Next Article in Journal
Application of the RBBP9 Serine Hydrolase Inhibitor, ML114, Decouples Human Pluripotent Stem Cell Proliferation and Differentiation
Next Article in Special Issue
Fibrosis in Chronic Kidney Disease: Pathogenesis and Consequences
Previous Article in Journal
Design, Synthesis and Evaluation of New Bioactive Oxadiazole Derivatives as Anticancer Agents Targeting Bcl-2
Previous Article in Special Issue
New Aspects of the Kidney in the Regulation of Fibroblast Growth Factor 23 (FGF23) and Mineral Homeostasis
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
IJMS
Volume 21
Issue 23
10.3390/ijms21238992
ijms-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Review

Role of Metabolism in Bone Development and Homeostasis

by
Akiko Suzuki
1,2,
Mina Minamide
1,2,
Chihiro Iwaya
1,2,
Kenichi Ogata
1,2 and
Junichi Iwata
1,2,3,*
1
Department of Diagnostic & Biomedical Sciences, School of Dentistry, The University of Texas Health Science Center at Houston, Houston, TX 77054, USA
2
Center for Craniofacial Research, The University of Texas Health Science Center at Houston, Houston, TX 77054, USA
3
MD Anderson Cancer Center UTHealth Graduate School of Biomedical Sciences, Houston, TX 77030, USA
*
Author to whom correspondence should be addressed.
Int. J. Mol. Sci. 2020, 21(23), 8992; https://doi.org/10.3390/ijms21238992
Submission received: 16 October 2020 / Revised: 22 November 2020 / Accepted: 25 November 2020 / Published: 26 November 2020
(This article belongs to the Special Issue Regulation of Bone Mineral Homeostasis)
Browse Figures
Versions Notes

Abstract

:
Carbohydrates, fats, and proteins are the underlying energy sources for animals and are catabolized through specific biochemical cascades involving numerous enzymes. The catabolites and metabolites in these metabolic pathways are crucial for many cellular functions; therefore, an imbalance and/or dysregulation of these pathways causes cellular dysfunction, resulting in various metabolic diseases. Bone, a highly mineralized organ that serves as a skeleton of the body, undergoes continuous active turnover, which is required for the maintenance of healthy bony components through the deposition and resorption of bone matrix and minerals. This highly coordinated event is regulated throughout life by bone cells such as osteoblasts, osteoclasts, and osteocytes, and requires synchronized activities from different metabolic pathways. Here, we aim to provide a comprehensive review of the cellular metabolism involved in bone development and homeostasis, as revealed by mouse genetic studies.

1. Introduction

Bone (re)modeling is responsible for the growth and repair/regeneration of the tissue by maintaining a balance between bone matrix deposition and resorption during development and homeostasis [1]. Osteoblasts and osteoclasts are the cells responsible for bone deposition/mineralization and resorption, respectively [1]. The functions of bones include acting as a locomotorium coordinating with muscles, tendons, and joints, the support of posture, the protection of organs and brain, the storage of minerals, and hematopoiesis in the bone marrow. Bone has various metabolic networks and is well controlled to maintain homeostasis. The metabolic status of these cells affects bone formation and homeostasis via various biological reactions; in fact, compromised homeostasis and/or metabolic processes lead to various congenital skeletal disorders and bone diseases [1]. Metabolism as a whole comprises complex physical and biochemical processes that allow organisms to generate, maintain, and regenerate their structures and respond to environmental cues [2,3]. It involves numerous biochemical enzymatic reactions [2] necessary to sustain life, which are divided into three main metabolic pathways: (1) anabolism (the synthesis of complex macromolecules from the polymerization of simple molecules); (2) catabolism (the release of energy by the degradation of these molecules); and (3) degradation (the elimination of toxic substrates) [3]. A metabolic pathway is thus a series of enzymatic cascades that convert a molecule into another biochemical compound and are essential for homeostasis in organisms. Metabolic pathways can be categorized into anabolic and catabolic pathways. The anabolic pathway synthesizes complex molecules from simple or smaller molecules by consuming energy, whereas the catabolic pathway degrades complex molecules into simple or smaller molecules by releasing energy. Therefore, these pathways complement each other in terms of energy utilization, and the products and metabolites generated in one or more metabolic pathways may be used in other pathways as substrates or stored for future use. In addition to these two major pathways, the amphibolic pathway (e.g., citric acid cycle and Embden–Meyerhof pathway) is also involved in both the anabolic and catabolic metabolism [4].
An increasing number of studies show that type I and type II diabetes mellitus, obesity, and dyslipidemia are associated with risk of osteoporosis and a delay of bone healing [5,6,7,8,9]. For example, serum levels of high-density lipoprotein cholesterol (HDL-C) and triglycerides (TGs) are positively associated with bone mineral density (BMD) [10,11]. Individuals with hypercholesterolemia show decreased BMD [12]. In addition, patients with type II diabetes with hyperglycemia have a higher risk of failure of dental implants due to failure in osteointegration [13]. Moreover, the frequency of hip fractures is significantly associated with duration of type II diabetes [14]. Mice with type I diabetes induced by streptozotocin display impaired bone regeneration in the injured bones, and treatment with insulin, vitamin D, or both, can normalize it [15]. This line of evidence strongly suggests that abnormal energy catabolism influences bone formation and homeostasis. In this review, we will describe how catabolic pathways affect bone development and homeostasis (Table 1 and Table 2).

2. Cholesterol Metabolism

Cholesterol is crucial as a source of numerous biomolecules, including bile acids, steroid hormones, and oxysterols, and is a vital component of cellular membranes; therefore, dysregulation of cholesterol synthesis is associated with various disorders and diseases [16]. It is also known that cholesterol modification of Hedgehog ligands–Sonic Hedgehog (Shh), Indian Hedgehog (Ihh), and Desert Hedgehog (Dhh–and receptor Smoothened (SMO) is crucial for their biological functions [17,18,19]. Hedgehog ligands are morphogens that play crucial roles in embryonic development and skeletogenesis [20,21,22]. Absence of a cholesterol moiety in SHH (ShhN) leads to a shorter distribution and lower activation of SHH signaling in limb buds, while it shows no difference in its biological functions compared to the molecules modified with cholesterol [23,24]. Mice overexpressing ShhN (Sox2-Cre;Shh+/+;ShhN or Sox2-Cre;ShhF/F;ShhN) exhibit polydactyly, holoprosencephaly, and cleft palate due to the long-range spread and activation of Shh signaling [24,25]. Thus, cholesterol modification in Hedgehog ligands is crucial for the regulation of Hedgehog signaling for morphogenesis. Moreover, the plasma membrane contains a large amount of lipids, especially cholesterol, which is essential for structural integrity, membrane fluidity, and membrane stability [26,27]. Cholesterol-rich micro-domains, lipid rafts, and caveolae act as a signaling center by assembling a variety of receptors and channels [28,29]. Thus, it is important to precisely control cholesterol synthesis and transportation through the regulation of cell viability and functions under physiological and pathological conditions.
Cholesterol biosynthesis is regulated by a highly complex process that involves more than 30 reactions regulated by more than 15 enzymes [30]. De novo cholesterol biosynthesis (a.k.a. mevalonate pathway) begins with the generation of 3-hydroxy-3-methylglutaryl-coenzyme A (HMG-CoA) from acetyl-CoA. HMG-CoA reductase (HMGCR) then converts HMG-CoA into mevalonate at the ER membrane for the control of cholesterol synthesis through negative cholesterol feedback. Thus, the inhibition of HMGCR results in the suppression of cholesterol synthesis and a reduction in mature cholesterol levels. In zebrafish, inactivation of hmgcr by a genetic approach, or by treatment with a statin (an HMGCR inhibitor), results in shorter or lack of cartilage in the viscerocranium due to defects in condensation and the reduced survival of cranial neural crest cells during craniofacial development [31]. Statins stimulate bone formation in cultured osteoblasts [32,33,34,35] as well as in animal models [36,37,38]; more importantly, statins can rescue the skeletal dysplasia observed in mice with a gain-of-function mutation in the fibroblast growth factor receptor type III gene (Fgfr3) [39]. However, the clinical evidence of the effects of statins on bone is still controversial [40,41,42,43,44,45,46,47].
Farnesyl diphosphate synthase (FDPS, a.k.a. FPPS) converts isopentenyl pyrophosphate and dimethylallyl pyrophosphate into farnesyl pyrophosphate (FPP; a.k.a. FDP) and is known to be a target of nitrogen-containing bisphosphonates (N-BPs) [48,49]. FPP is further converted into squalene and geranylgeranyl diphosphate (GGPP) by farnesyl-diphosphate farnesyltransferase (FDFT1; a.k.a. SQS) and geranylgeranyl pyrophosphate synthase (GGPPS1), respectively. GGPP plays an important role in the activation of osteoclasts in bone formation and resorption [50,51]. A recent study shows that the inhibition of the mevalonate pathway with statins and N-BPs suppresses osteoclastogenesis and bone resorption via reduced binding of estrogen-related receptor alpha (ERRα), a nuclear receptor, to the promoter regions of its target genes [52]. In fact, long-term treatment with bisphosphonates causes bisphosphonate-related osteonecrosis of the jaw, a known side effect of these drugs [53,54]. Protein isoprenylation (farnesylation or geranylgeranylation) is one of the post-translational modifications and required for the activation of molecules. Farnesyltransferase catalyzes the conversion from farnesyl pyrophosphate to farnesyl proteins in farnesylation; geranylgeranyl transferase catalyzes the conversion from geranylgeranyl diphosphate to geranylgeranyl proteins in geranylgeranylation. The inhibition of farnesylation suppresses osteogenic differentiation and mineralization in human mesenchymal stem cells, while inhibition of geranylgeranylation accelerates osteogenic differentiation and mineralization [55]. In addition, inhibition of geranylgeranylation suppresses osteoclast differentiation, induces apoptosis in osteoclasts, and suppresses bone resorption [56]. Thus, protein prenylation plays an important role in the regulation of both osteoblastogenesis and osteoclastogenesis.
In the cholesterol metabolic pathway, mice deficient for Fdft1, cytochrome P450, family 51 (Cyp51), and transmembrane 7 superfamily member 2 (Tm7sf2; a.k.a. Dhcr14), NAD(P) dependent steroid dehydrogenase-like (Nsdhl), hydroxysteroid (17-beta) dehydrogenase 7 (Hsd17b7), methylsterol monooxygenase 1 (Sc4mol), sterol-C5-desaturase (Sc5d), 7-dehydrocholesterol reductase (Dhcr7), 24-dehydrocholesterol reductase (Dhcr24), and insulin-induced gene 1 and 2 (Insig1/2) display defects in bone formation and/or homeostasis, as described below (Figure 1).
Squalene synthase FDFT1 catalyzes the dimerization of FPP into squalene in the mevalonate pathway. Interestingly, treatment with zaragozic acid, an FDFT1 inhibitor, or excessive FPP in osteoblasts inhibits osteoblast differentiation and mineralization [57]. The homozygous Fdft1 null mutation is embryonic lethal at embryonic day (E) 12.5, causing growth retardation and neurodevelopmental deficit [58]. Patients with squalene synthase deficiency, which is caused by autosomal recessive FDFT1 mutations, exhibit facial dysmorphism, micrognathia, syndactyly, brain developmental defects, and developmental delay [59].
Additionally, lanosterol 14-α demethylase (CYP51A1 in humans and CYP51 in mice), a member of the cytochrome P450 superfamily, catalyzes the demethylation of lanosterol and 24,25-dihydrolanosterol in the cholesterol synthesis pathway via cytochrome P450 oxidoreductase (POR). Cyp51 null mice (Cyp51−/− mice) exhibit a variety of skeletal defects, including cleft palate, micrognathia, brachycephaly, microglossia/aglossia, polydactyly/syndactyly, and malformation of long bones, as well as cardiac developmental defects, through altered sonic hedgehog and retinoic acid signaling [60].
TM7SF2 (a.k.a. DHCR14), a sterol delta (14)-D reductase, catalyzes the reduction of C14-unsaturated bond of lanosterol in a NADP-dependent manner during cholesterol biosynthesis. Mutations in TM7SF2 cause Greenberg skeletal dysplasia (a.k.a. hydrops-ectopic calcification-moth-eaten or HEM skeletal dysplasia), an autosomal recessive chondrodystrophy characterized by fetal hydrops, short limbs, and abnormal chondro-osseous ossification. The bony defects in this syndrome include severe short-limbed dwarfism, postaxial polydactyly, and platyspondyly [61]. The Lamin B receptor (LBR), a paralog of TM7SF2, act bi-functionally as a lamin B receptor and delta14-reductase; TM7SF1 and LBR is functionally redundant for the delta14-reductase activity. Although mice with a deletion of Tm7sf2 (Tm7sf24-7/∆4-7) are almost comparable to wild-type mice, Lbr+/−; Tm7sf24-7/∆4-7 mice exhibit shorter growth plates, less trabecular bones, growth retardation, cleft palate, and ataxia [62]. On the other hand, Lbr−/− mice exhibit disorganized hypertrophic chondrocytes (but normal growth plate length), immature trabecular bone, growth retardation, and ichthyosis [62,63].
NSDHL is a 3β-hydroxysterol dehydrogenase involved in the removal of two C4 methyl groups from 4,4-dimethylcholesta-8,24-dien-3β-ol, a sterol intermediate derived from lanosterol. Mutations in NSDHL cause X-linked dominant Congenital Hemidysplasia with Ichthyosiform nevus and Limb Defects (CHILD) syndrome, which is characterized by peculiar ichthyosiform nevus, hyperkeratotic plaques, and limb defects ranging from digital hypoplasia to complete amelia [64]. Heterozygous Nsdhl mutant female mice (bare patches [Bpa] mice) exhibit hyperkeratotic eruption and skeletal dysplasia with chondrodysplasia punctata [65].
SC5D converts lathosterol into 7-dehydrocholesterol, and SC5D mutations cause lathosterolosis, which is characterized by growth and mental retardation, short limbs, polydactyly/syndactyly, and craniofacial malformations, including cleft palate, micrognathia, midfacial hypoplasia, and calvarial defects [66]. Similarly, as seen in humans, mice with a deficiency for Sc5d (Sc5d−/− mice) exhibit cleft palate, micrognathia, agenesis of lower incisors, calvaria hypomineralization, malformation of long bones, and syndactyly/polydactyly [66,67].
The DHCR7 enzyme catalyzes the conversion of both 7-dehydrocholesterol (7-DHC) to cholesterol and 7-dehydrodesmosterol to desmosterol [68]. Mutations in DHCR7 cause Smith-Lemli-Opitz syndrome (SLOS), which is characterized by cleft palate, postaxial polydactyly, 2-3 toe syndactyly, microcephaly, micrognathia, and mental retardation [69,70]. Mice deficient for Dhcr7 (Dhcr7−/− mice) exhibit accelerated calvarial bone formation, cleft palate (in 9% of the mice), brain developmental defects, and immature lung development [71,72]. Dhcr7 null osteoblasts show ciliogenesis defects (shorter and fewer primary cilia), leading to the upregulation of WNT/β-catenin signaling, which accelerates osteoblast differentiation and mineralization [72]. 7-DHC is also a precursor of vitamin D, a known regulator of calcium homeostasis, and is activated under ultraviolet B radiation (sunlight) in the skin.
DHCR24 catalyzes the reduction of the delta-24 double bond of sterol intermediates in cholesterol biosynthesis [73]. Autosomal recessive mutations in DHCR24 cause desmosterolosis, which is characterized by cleft palate or high-arched palate, short limbs with osteosclerosis, contractures in the hands, and developmental brain defects [74,75,76]. Dhcr24−/− mice die before birth and present growth retardation and a wrinkleless taut skin, with no apparent defects in other parts of the body [77].
As described above, there are differences in the clinical features of the syndromes (e.g., lathostelosis, SLOS, and desmosterolosis) as well as in the phenotypes of Sc5d−/−, Dhcr7−/−, and Dhcr24−/− mice, suggesting that the accumulation of different cholesterol intermediates contributes to the pathogenesis of these diseases, rather than the absence of mature cholesterol [78].
Finally, INSIG1 and INSIG2 are ER-retention proteins that regulate cholesterol synthesis by modifying the activity of HMGCR and sterol regulatory element-binding protein (SREBP) cleavage-activating protein (SREBP cleavage activating protein; SCAP) in the ER membranes via a negative feedback mechanism triggered by high cholesterol status [79,80,81,82]. INSIG1/2 binds to HMGCR and promotes its degradation by the proteasome, resulting in decreased HMGCR enzymatic activity. On the other hand, INSIG1/2 binds to a complex of SCAP and SREBP, interrupting the translocation of the complex to the Golgi apparatus. At lower cholesterol levels, INSIG1/2 separate from the SCAP/SREBP complex, and this free complex is transported to the Golgi by coat protein complex II (COPII)-coated vesicles. SREBP is then cleaved at the Golgi membrane and translocated into the nucleus, thus inducing expression of its target genes [83]. Insig1/2 double-null knockout (Insig1−/−;Insig2−/−) mice exhibit midline cleft face or cleft palate, micrognathia, exencephaly, and atelectatic lungs [84]. Moreover, mice with an Insig1/2 deficiency in cranial neural crest cells (Wnt1-Cre; Insig1F/F;Insig2−/− mice), which form the majority of craniofacial structures, exhibit thin calvarial bone with low mineralization, resembling osteogenesis imperfecta [72]. Interestingly, Insig1/2 mutant osteoblasts show abnormal multiple centrioles, supernumerary and longer primary cilia, resulting in compromised WNT/β-catenin signaling that leads to suppression of osteoblast differentiation and mineralization [72].
During chondrocyte differentiation, expressions of genes associated with cholesterol synthesis (e.g., Hmgcr, Hmgcs1, Ldlr, Scap, Insig1, Srbp) is downregulated [85]. The deletion of Insig1/2 in either mesodermal cells or chondrocytes (Prrx1-Cre; Insig1F/F; Insig2−/− and Col2a1-Cre; Insig1F/F; Insig2−/− mice) results in a disorganized growth plate and chondrogenesis defects during endochondral ossification, which is manifested by short limbs and dwarfism [85]. Prrx1-Cre; Insig1F/F; Insig2−/− mice also exhibit a midline cleft, as seen in Insig1−/−; Insig2−/− mice. In addition, mice with a specific deletion of Scap in mesodermal cells or chondrocytes (Prrx1-Cre; ScapF/F and Col2a1-Cre; ScapF/F mice) show similar defects in growth plate organization and chondrogenesis, with short limbs and dwarfism [85]. The mesenchymal cells in Prrx1-Cre; ScapF/F mice show disorganized cellular condensation and suppressed proliferation and differentiation into chondrocytes. The suppression of cholesterol synthesis by a DHCR7 inhibitor AY9944 in 4 weeks-old rats suppresses Hedgehog signaling, leading to a reduction of chondrocyte proliferation and growth palate length [86]. Consistent with that observation, chondrocytes from Col2a1-Cre; ScapF/F and Col2a1-Cre; Insig1F/F; Insig2−/− mice show downregulated and upregulated Hedgehog signaling, respectively [85]. Interestingly, normalization of upregulated intracellular cholesterol synthesis in Col2a1-CreERT2;Idh1R132Q/R132Q mice by loss of Scap (Col2a1-CreERT2;Idh1R132Q/R132Q;ScapF/F mice), or by treatment with lovastatin, suppresses chondrogenic tumor growth [87]. These studies suggest that either the upregulation or downregulation of intracellular cholesterol synthesis compromises osteogenesis and chondrogenesis. In addition, there is a positive feedback loop for expression of genes regulating the sterol metabolic pathway (e.g., Cyp11a1, Cyp39a1, Cyp51, Lss, Dhcr7) regulated by Runx2. For instance, during osteogenic differentiation, Cyp11a1, which catalyzes the conversion from cholesterol to pregnolone, is a direct target of RUNX2 and suppresses cell proliferation in MC3T3-E1 osteoblast cells [88]. These results suggest that cholesterol synthesis is directly linked to osteogenic differentiation.

3. Fatty Acid Metabolism

Fatty acid metabolism involves an enzymatic cascade that degrades fatty acids into bioactive substrates and synthesizes straight-chain fatty acids to be stored as triglycerides in adipose tissues. The catabolic pathway starts with the release of free fatty acids from glycerol, consumed in the diet or derived from triglycerides in adipose tissue through lipolysis, followed by transport to peripheral cells and the entire body, according to its needs. In the cytosol, long-chain fatty acids are catalyzed with ATP to acyl-CoA and further broken down to acetyl-CoA by β-oxidation to enter the tricarboxylic acid cycle (TCA) cycle in the mitochondrial matrix. On the other hand, acetyl-CoA is a substrate for straight-chain fatty acid synthesis. Triglycerides, phospholipids, precursors of eicosanoid hormones and second messengers, and ketone bodies are all produced in both the catabolic and synthetic pathways. A recent study suggests that single nucleotide polymorphisms (SNPs) in genes associated with fatty acid synthesis (MCAT, PPT1, ACSL5, HSD17B12, and ACADL) are associated with non-syndromic cleft lip with/without palate in humans [89]. A proteomic analysis demonstrated that expression of inflammation-related proteins and HSD17B12 is significantly elevated in chondrocytes isolated from articular cartilage of osteoarthritis patients [90]. These results suggest that fatty acid synthesis is closely associated with skeletal disorders. Indeed, mice with a deficiency of malonyl-CoA-acyl carrier protein transacylase (Mcat; inducible Mcat−/− mice) [91], palmitoyl-protein thioesterase 1 (Ppt1; Ppt1−/− mice) [92]), acyl-CoA synthetase bubblegum family member 2 (Acsbg2; Acsbg2−/− mice), and carnitine palmitoyltransferase 2 (Cpt2; Cpt+/− mice) display various defects in bone formation and/or homeostasis (Figure 2).
MCAT is a crucial enzyme in fatty acid biosynthesis and is responsible for transferring the malonyl moieties from malonyl-CoA to mitochondrial acyl carrier proteins. Mice with a deficiency in Mcat in almost all tissues, due to tamoxifen-inducible Cre expression starting at 4−6 weeks of age (McatF/F;Esr1-CreER mice), exhibit kyphosis at 10 months without any unusual morphologic changes in bone [91].
PPT1 hydrolyzes long-chain fatty acyl-CoA during fatty acid synthesis, in addition to hydrolyzing fatty acids from modified cysteine residues of proteins that undergo lysosomal degradation. Ppt1−/− mice exhibit thick calvaria and neurological abnormalities [92] through either dysregulated fatty acid metabolism or disrupted lysosomal protein degradation. In humans, autosomal recessive mutations in PPT1 cause infantile neuronal ceroid lipofuscinosis 1 with accumulation of fatty acyl cysteine thioesters in neural cells, which leads to neuronal cell death [93,94].
ACSBG2, a long-chain fatty acid-CoA ligase isozyme, converts free long-chain fatty acids to fatty acyl-CoA esters, and Acsbg2−/− mice exhibit low bone mineral density (reported by the International Mouse Phenotyping Consortium [IMPC] at https://www.mousephenotype.org).
CPT2 oxidizes long-chain fatty acids by adding CoA at the mitochondrial inner membrane. The deletion of this enzyme in the fatty acid β-oxidation pathway in Cpt2−/− mice results in abnormal vertebrae morphology (reported by the IMPC); however, it remains unclear how these enzymes affect bone formation and homeostasis.
HSD17B12 (estradiol 17-β-dehydrogenase 12) is an enzyme that catalyzes the conversion of 3-ketoacyl-CoA to 3-hydroxyacyl-CoA in an NADP-dependent manner in fatty acid elongation. ACSL5 (acyl-CoA synthetase long chain family member 5) catalyzes the conversion of long-chain fatty acids to active fatty acyl-CoA esters, whereas ACADL (acyl-CoA dehydrogenase, long chain) catalyzes β-oxidation in the mitochondria to break down fatty acids into acetyl-CoA. However, mice with mutations in these genes have not yet been analyzed in detail.
The uptake of long-chain fatty acids is made through fatty acid translocase CD36 [cluster of differentiation 36; a.k.a. fatty acid translocase (FAT)] [95]. Cd36 null mice (Cd36−/−) show no defect at the initial stages of bone development; however, they show lower bone mass as adults due to the suppression of osteoblast differentiation [96]. Long-chain fatty acids mediate signaling through their binding to G-protein-coupled receptors, GPR40 and GPR120, in bone cells [97,98,99,100,101]. GPR120 is expressed at higher levels in mature osteoblasts and osteoclasts compared to precursor cells. The activation of the GPR120-mediated signaling pathway suppresses bone resorption through the inhibition of osteoclast differentiation induced by the RANKL‒NFκB‒NFATc1 pathway [100] and promotes osteogenesis via the Ras‒ERK1/2 signaling pathway [99]. Activation of the free fatty acid receptor G-coupled protein receptor 40 (GPR40)-mediated signaling pathway stimulates osteoblastogenesis, but inhibits mineralization [97], and suppresses osteoclastogenesis through the inhibition of the RANKL‒NFκB‒NFATc1 pathway [101]. Gpr40 knockout (Gpr40−/−) mice exhibit an osteoporotic bone phenotype (e.g., low bone mass, low bone mineral density, low trabecular thickness/number) [101]. Treatment of ovariectomized mice with a GPR40 agonist protect from bone loss by normalizing osteoclast activity [101]. In addition, essential fatty acids (alpha-linolenic acid and linoleic acid) have been suggested to regulate calcification and bone resorption [102,103,104,105]. For instance, β-oxidation of fatty acids is required for bone formation and maintenance. Female mice with a deficiency for carnitine palmitoyltransferase-2 (Cpt2), which catabolizes compounds through β-oxidation, in osteoblasts (Oc-Cre; Cpt2F/F) exhibit decreased bone acquisition due to the suppression of osteoblast differentiation [106]. In addition, short-chain fatty acids are up-taken through GPR41 or GPR43 (a.k.a. FFAR2) and inhibit osteoclastogenesis and bone resorption under physiological and pathological (e.g., ovariectomized osteoporotic) conditions [107]. These results suggest that free fatty acids and their synthesis are associated with bone formation and bone loss in physiological and pathological conditions.

4. Glycolysis and Gluconeogenesis

Glycogen, a long, branched polymer of glucose residues, is a readily mobilized storage form of glucose that is mainly present in the liver and skeletal muscles; when the body needs energy, glycogen is broken down into glucose. In the liver, glycogen synthesis and degradation are regulated for the maintenance of blood glucose levels as required by the organism, but in muscles and other tissues these processes are regulated based on their specific needs. It is well known that patients with hyperglycemia or diabetes show decreased bone remodeling. Excessive glucose addition inhibits cell proliferation and osteogenic differentiation in a dose-dependent manner in human bone marrow mesenchymal stem cells and osteoblast cell lines MG63 and MC3T3-E1 [108,109,110]. Glucose is up-taken through glucose transporters SLC2A1-4 (solute carrier family 2, member 1-4; a.k.a. GLUT1-4). Among them, SLC2A1 is expressed in osteoclasts, and its expression is upregulated over time during osteoclast differentiation and maturation. In the growth plate, SLC2A1 is expressed only in upper hypertrophic chondrocytes [111,112]. Female mice with a deletion of Slc2a1 in monocyte-derived osteoclasts (Lys2-Cre;Slc2a1F/F) show defects in osteoclastogenesis, but not males, leading to increased trabecular bone mass [113]. In addition, the expression of Slc2a1 is upregulated over time during osteoblast differentiation and suppressed by tumor suppressor gene p53 [114] and induced by Runx2 [115]. Mice with a deletion of Slc2a1 in mesoderm-derived cells (Dermo1-Cre; Slc2a1F/F), pre-osteoblasts (Osx-Cre; Slc2a1F/F and Osx-CreERT2; Slc2a1F/F), and osteoblasts (Bglap-Cre; Slc2a1F/F) also exhibit severe bone mineralization defects with reduced trabecular bone mass in both endochondral and intramembranous ossification [115,116]. Mice with a mesenchymal cell-specific deletion of Slc2a1 in the limb bud and craniofacial region (Prx1-Cre; Slc2a1F/F) exhibit short long bones with a disorganized columnar structure in the proliferation and hypertrophic zones of the growth plate, the suppression of cartilage matrix synthesis, and modestly delayed ossification [111]. Slc2a1 is also involved in stabilization of RUNX2 to promote osteoblast differentiation [115]. Thus, glucose uptake and consequent aerobic glycolysis play crucial roles in bone formation and remodeling.
Glycolysis is a biochemical cascade that is conserved in almost all organisms and that catalyzes glucose to pyruvic acid (a.k.a. pyruvate), nicotinamide adenine dinucleotide (NADH), ATP, and other intermediates, in the cytosol. In osteoblasts, 80% of the ATP is produced by aerobic glycolysis [117]. For instance, NAD+-dependent mitochondrial malic enzyme ME2, which catalyzes the conversion of malate to pyruvate in the mitochondria, is upregulated during osteoblast differentiation. The knockdown of Me2 in osteoblasts suppresses glucose consumption and cell proliferation and differentiation [117]. In addition, a recent study showed that aerobic glycolysis is required for osteoclastogenesis and bone resorption [113]. In the glycolysis and gluconeogenesis pathway, mice with a deficiency in the glucose-6-phosphatase catalytic subunits (G6pc), i.e., 6-phosphogluconate dehydrogenase (Pgd), aldolase B (Aldob), display defects in bone formation and/or homeostasis (Figure 2).
Glucose-6-phosphatase (G6Pase), a multi-subunit integral membrane protein of the endoplasmic reticulum (ER), is a crucial enzyme in gluconeogenesis and catalyzes the hydrolysis of D-glucose-6-phosphate (glucose-6P, G6P) to D-glucose and orthophosphate, thus generating a phosphate group and free glucose. G6Pase comprises a catalytic subunit and transporters for glucose-6P, phosphate (Pi), and glucose and is mainly expressed in the liver and kidneys for glucose homeostasis. Mutations in G6PC, one of the three genes encoding the G6Pase catalytic subunits in humans (G6PC1, G6PC2, and G6PC3), cause glycogen storage disease type Ia (GSD-Ia), which is characterized by neuropathy, hepatic adenocarcinoma, and osteopenia [118,119,120]. Mice with a loss of G6pc (G6pc−/−) exhibit cartilage dysplasia [121], delayed ossification in the growth plate of bones, decreased bone dimensions, and decreased levels of growth hormone (GH) and insulin-like GH, and hepatic GH signaling [122]. Insulin-like growth factor 1 (IGF1) is a peptide hormone; its production is stimulated by GH in the liver [123]. IGF1 signaling is mediated by binding to the IGF1 receptor type I (IGF1R). The GH‒IGF1 axis is a well-known regulator for bone growth and remodeling through the stimulation of cell proliferation, osteoblastogenesis and osteoblast activity, osteoblast-to-osteocyte transition, osteoclast activity, and chondrocyte differentiation at the growth plates [124,125,126,127]. Igf1 null (Igf1−/−) mice exhibit decreased cell proliferation in the growth plate, delayed bone development, and growth retardation [128,129]. Mice with a deficiency for IGF1 receptor type I in pre-osteoblasts and pre-hypertrophic chondrocytes (Osx-GFP: Cre; Igf1rF/F) exhibit shorter hypertrophic zone in the growth plates and suppressed chondrocyte differentiation/maturation, resulting in the retardation of postnatal bone growth [130]. Mice with a deficiency for Igf1r in osteoblasts (Col1a1-Cre; Igf1rF/F) exhibit decreased post-fracture bone formation due to suppressed osteoblastogenesis [131]. Mice with a tamoxifen-induced deficiency of Igf1r in bone marrow mesenchymal cells (Nestin-CreER; Igf1rF/F, tamoxifen induction at 3 weeks of age) exhibit decreased trabecular bone mass due to suppression of osteoblast differentiation [132]. These results suggest that the reductions in serum GH and IGF1 are responsible for the impaired bone growth phenotype seen in G6pc−/− mice. SLC37A4 (G6P translocase; a.k.a. G6PT), working together with G6Pase, transports D-glucose 6-phosphate (glucose-6P) from the cytoplasm to the ER and is known to be a causative gene of GSD-Ib, which is characterized by osteopenia, also seen in patients with GSD-Ia caused by mutations in G6Pase [120]. Mice with a Slc37a4 deficiency (Slc37a4−/− mice; a.k.a. G6PT−/− mice) exhibit seizures, suppressed hematopoiesis, and delayed bone development at 3 weeks of age but they catch up by 6 weeks of age [133]. These findings indicate that appropriate glycogen storage and degradation are essential for bone homeostasis.
In the cytosol, G6P is converted to fructose-6 phosphate (F6P) by phosphogluconate dehydrogenase (6PGD; a.k.a. 6PGDH), which is further converted to pyruvate by aldolase B (a.k.a. fructose-bisphosphate B). Pyruvate is a key metabolite connecting glycolysis, the TCA cycle, cholesterol synthesis, lipid catabolism, and amino acid metabolism through acetyl-CoA. The pyruvate dehydrogenase complex (PDC), which includes three catalytic domains, catalyzes the conversion from pyruvate and NAD+ to acetyl-CoA, CO2, and NADH in the mitochondria. Mice with a deficiency of either Pgd (Pgd+/− mice) or Aldob (Aldob−/− mice) exhibit low bone mineral content and density (reported by the IMPC). Patients with autosomal dominant PGD mutations are asymptomatic, whereas those with autosomal recessive ALDOB mutations show hereditary fructose intolerance, but no bone abnormalities. Future studies may identify the contribution of these genes in bone diseases. Pyruvate dehydrogenase complex activity is inactivated by pyruvate dehydrogenase kinase 1-4 (PDK1-4). While Pdk4−/− mice normally develop and maintain bone homeostasis, Pdk4−/− mice show reduced bone mass due to enhanced osteoclastogenesis and bone resorption under unloading conditions [134]. Bone marrow mesenchymal cells isolated from Pdk4−/− mice show suppression of osteoclastogenesis but no defect in osteoclast fusion. In recombination assays, osteoblasts isolated from Pdk4−/− mice failed to induce osteoclastogenesis of monocytes isolated from wild-type mice due to decreased Rankl expression [134]. Ovariectomy, a procedure that induces estrogen-dependent osteoporosis, of Pdk2 null (Pdk2−/−) mice show reduced osteoclast number, suppressed osteoclastogenesis, and suppressed bone resorption through the RANKL‒CREB‒c-Fos‒NFATc1 pathway [135]. Thus, the suppression of transformation to acetyl-CoA causes bone loss.

5. Glycogenolysis and Glycogenesis

Dietary carbohydrates are digested into glucose by amylase and dissolved into the bloodstream. At each organ, glucose is up-taken into the cytosol through glucose transporters and is synthesized to glycogen. Glycogen is a multi-branched polysaccharide containing multi-units of glucose and stored as an energy source, mainly in the liver and skeletal muscles [136]. Glycogenolysis initiates with the breakdown of glycogen into glucose 1-phosphate (G1P) by AGL and glycogen phosphorylase. G1P is further broken down into G6P by phosphoglucomutase. In the growth plate in young rats, glycogen is abundant in the resting, pre-hypertrophic, and hypertrophic chondrocytes but is less abundant in the proliferative and late-hypertrophic chondrocytes [137]. Inversely, glycogen degradation enzymes (glycogen phosphorylase and G6Pase) are highly active in the proliferative, pre-hypertrophic, and hypertrophic chondrocytes and are suppressed in the resting and late-hypertrophic chondrocytes [112,137]. G6Pase is expressed at higher levels in osteoblasts than in osteocytes and osteoclasts in the metaphyses of young rats [138]. On the other hand, glycogen synthesis (glycogenesis) starts with the conversion of glucose to G6P by glucokinase in the liver, or hexokinase 1 and -2 in other organs. G6P is then converted to G1P by phosphoglucomutase. UDP-glucose pyrophosphorylase 2 (UGP2) then catalyzes the transformation of G1P and UTP to UDP-glucose and pyrophosphate (PPi). Finally, UDP-glucose and glycogenin are converted to glycogen by UDP-glucose-glycogen glucosyltransferase (a.k.a. glycogen synthase) and branching enzymes.
Amylo-alpha-1, 6-glucosidase, 4-alpha-glucanotransferase (AGL), which is expressed in the liver and skeletal muscles, plays a role in glycogen degradation. AGL has two enzymatic activities—glucosyltransferase and glucosidase—and breaks down (debranches) glycogen into G1P, together with glycogen phosphorylase [139]. In humans, mutations in AGL are associated with glycogen storage disease type III (GSD-III), an autosomal recessive metabolic disorder caused by the accumulation of glycogen in the liver and skeletal muscles, resulting in organ dysfunction. GSD-III is further characterized into two subtypes: (1) GSD-IIIa, which affects only the liver; and (2) GSD-IIIb, which involves both the liver and skeletal muscles. Unlike patients with GSD-IIIa, patients with GSD-IIIb exhibit low bone mineral density [119,140,141,142]. In addition, Agl knockout mice (Agl−/− mice) exhibit kyphosis [143]. However, the exact mechanism of the skeletal dysplasia in Agl−/− mice and the contribution of glycogen metabolism to bone homeostasis will be further examined in mice with a specific deletion of Agl in bone cells.
In addition, enzyme ectonucleotide pyrophosphatase/phosphodiesterase 1 (ENPP1) plays a role in the regulation of pyrophosphate levels by generating inorganic pyrophosphate (PPi) from adenosine triphosphate (ATP), acting as a suppressor of calcification under various pathological conditions [144,145]. In glycogen degradation and glycogenesis, ENPP1 catalyzes the dephosphorylation of uridine diphosphate glucose (UDP-glucose) into G1P and PPi, which is an anti-mineralization factor under physiological conditions [146]. In humans, autosomal recessive ENPP1 deficiency causes hypophosphatemic rickets type 2, which is characterized by low bone mass and osteopenia [147,148]. The loss of Enpp1 results in abnormal bone mineralization in twy mutant mice, which have a spontaneous nonsense mutation in Enpp1 (p.Gly568Ter), as well as in mice with a spontaneous Enpp1 deletion, in mice with a chemically induced (by the mutagen N-ethyl-N-nitrosourea [ENU]) single point mutation (c.T737A), and Enpp1−/− null mice [148,149,150,151,152,153,154]. In addition, all of these Enpp1 mutant mice exhibit excessive calcification of the articular cartilages/joints, ankylosis/joint fusion, exostosis, and calcification in blood vessels [148,150,155,156,157]. The accelerated calcification in Enpp1-deficient osteoblasts is caused by decreased extracellular PPi levels and downregulated osteopontin expression [152]. However, because ATP, a complex organic chemical that participates in many biological processes, is one of the primary substrates for ENPP1 [158], the contribution of ENPP1 to glycogen degradation and glycogenesis needs to be evaluated in mice with a specific deletion of Enpp1 in bone cells (Figure 3).

6. TCA Cycle

The TCA cycle (a.k.a. the citric acid cycle or the Krebs cycle) is an essential metabolic cycle present in the mitochondria of all aerobic organisms. Through glycolysis, pyruvic acid and fatty acyl-CoA are converted into acetyl-CoA, with subsequent synthesis of guanosine triphosphate (GTP)/ATP, NADH, and amino acids. Studies in mice have shown that a deficiency of Idh1 (isocitrate dehydrogenase 1, cytosolic) and Sdhc (succinate dehydrogenase complex subunit C) in the TCA cycle pathway induces defects in bone formation and/or homeostasis (Figure 2).
Isocitrate dehydrogenase 1 (IDH1) is an enzyme that catalyzes the oxidative decarboxylation of isocitrate and NADP+, producing α-ketoglutarate (a.k.a. 2-oxoglutarate) and NADPH. Mutations in IDH1 cause several cancers such as solitary or multiple enchondromas, acute myeloid leukemia, and glioma [159]. Mutations in IDH1 also accelerate the conversion of α-ketoglutarate to D-2-hydroxyglutarate and the accumulation of D-2-hydroxyglutarate, which is known as an oncometabolite competing with α-ketoglutarate in binding to histone and DNA demethylases, leading to chromatin hypermethylation [160,161]. The exogenous supplementation of D-2-hydroxyglutarate inhibits osteoblast differentiation from mesenchymal stem cells [162]. Zebrafish embryos treated with 2-hydroxyglutarate exhibit a failure of bone formation without affecting cartilage development [162]. In addition, an accumulating number of genetic studies suggests that IDH1 plays crucial roles in bone and cartilage formation. For example, mice with a knock-in mutation in the Idh1 gene causing human enchondroma (Col2a1-Cre; Idh1R132Q/+ mice) exhibit growth plate disorganization and cartilaginous dysplasia [163]. Moreover, mice with the inducible mutation (Col2a1-CreERT2; Idh1R132Q/+) develop enchondroma-like cartilage around the growth plate [163]. Known oncogenic mutations in the IDH1 gene in humans (such as R132C, R132Q, and R132H) upregulate enzymatic activity for the conversion of α-ketoglutarate to D-2-hydrozyglutarate, an inhibitor of histone demethylase [163,164,165]. In mice, the expression of hypertrophic chondrocyte markers Runx2 and Col10a1 and cell proliferation are upregulated at the proliferating zone of the growth plate in mice with oncogenic Idh1 mutations, indicating that a proper amount of intermediates from the TCA cycle is vital for the development and homeostasis of cartilage and bone.
Succinate dehydrogenase (SDH) participates in both the TCA cycle and the electron transport chain as the mitochondria respiratory chain complex II at the mitochondria’s inner membrane, which catalyzes the oxidation of succinate converting it to fumarate. Succinate dehydrogenase subunit C (SDHC) is one of the four subunits of SDH [166]. Mice heterozygous for the Sdhc null mutation (Sdhc+/− mice) exhibit decreased bone mineral content in females, but increased content in males without any tumorigenesis (reported by the IMPC). In humans, patients with autosomal dominant mutations in the SDHC gene show benign hereditary pheochromocytomas/paragangliomas type III without any bone abnormality. Future studies may identify the contribution of SDHC in bone diseases.

7. Phospholipid Metabolism

Phospholipids are synthesized in the ER and include a hydrophobic fatty acid tail and a hydrophilic head that form the lipid bilayer in the eukaryotic plasma membrane. The lipid bilayer comprises, in addition to phospholipids, several other molecules such as proteins, cholesterols, and glycoproteins that contribute to the membrane’s function and fluidity. The metabolites of phospholipids also serve as second messengers in signal transduction [e.g., phosphatidic acid (PA), phosphatidylinositol-(4,5)-bisphosphate (PIP2), diacylglycerol (DAG), and prostaglandins]. Phosphatidylserine receptors such as TIM4, BAI1, and STAB2 are expressed in mature osteoclasts. Blocking these receptors or reducing extracellular phosphatidylserine inhibits fusion of pre-osteoclasts without affecting ostoclastogenesis [167,168]. Interestingly, extracellular phosphatidylserine induces apoptosis in mature osteoclasts through TIM4 and BAI1 receptors [167]. Bone filling with hydroxyapatite containing phosphatidylserine-liposomes accelerates osteoblast differentiation and bone regeneration at injured sites of rat calvaria compared to hydroxyapatite alone [169]. Lysophosphatidic acid (LPA) is a phospholipid-derivative growth factor, which is converted from lysophosphatidylcholine that acts through G-protein-coupled receptors LPAR1-6. Treatment with lysophosphatidic acids enhances osteoblast differentiation, mineralization, and expression of CTGF (connective tissue growth factor; a.k.a. CCN2) through LPAR1 and LPAR3 in MC3T3-E1 pre-osteoblast cells [170,171]. Lpar1 null (Lpar1−/−) mice exhibit dwarfism, short limbs, rib cage deformity, short snout, osteoporotic bones, and low bone mineral density due to decreased osteoblatogenesis and osteoblast differentiation [172]. These results suggest that phospholipids and their receptors positively regulate bone formation [173,174].
In the phospholipid metabolic pathway, mice with a deficiency of either choline O-acetyltransferase (Chat), choline kinase beta (Chkb), phosphoethanolamine/phosphocholine phosphatase (Phospho1), phospholipase A2 group VI (Pla2g6), membrane-bound O-acyltransferase domain containing 7 (Mboat7), 1-acylglycerol-3-phosphate O-acyltransferase 3 (Agpat3), or 1-acylglycerol-3-phosphate O-acyltransferase 4 (Agpat4) exhibit defects in bone formation and/or homeostasis (Figure 4).
ChAT catalyzes the synthesis of acetylcholine from acetyl-CoA and choline. Acetylcholine plays a crucial role in synaptic transmission, particularly at neuromuscular junctions, in the regulation of skeletal muscle activity. Chat−/− mice display kyphosis at birth due to impaired skeletal muscle development and dysfunctional neurotransmission within muscles [175,176,177].
Choline kinase [a.k.a. ethanolamine kinase (EK)] includes two isozymes, CHKA and CHKB, and catalyzes the first step of the biosynthesis of phosphatidylcholine and phosphatidylethanolamine. Mice with a 1.6-kb intragenic deletion within the choline kinase beta (Chkb) gene (Chkbrmd/rmd mice) exhibit severe dystrophy in hindlimb skeletal muscles and bone deformity in the forelimbs due to chondrocyte differentiation arrest and suppression of cartilage matrix degradation in the growth plates [178,179]. Moreover, mice with an A-to-T transversion at the start codon of the Chkb gene (Chkbflp/flp mice) exhibit deformity in the forelimbs and low bone mass via increased osteoclast number, accelerated bone matrix resorption by osteoclasts, and reduced mineralization activity in osteoblasts [180].
In the next step of the phospholipid metabolic pathway, PHOSPHO1, a membrane-bounded matrix vesicle phosphatase, catalyzes the dephosphorylation of both phosphoethanolamine and phosphocholine, thus producing Pi, and also plays a role in the initiation of the calcification process, particularly in skeletal tissues [181,182]. Phospho1−/− mice display growth plate abnormalities, low bone mineral density, fragile bones, osteomalacia, and thoracic scoliosis due to decreased mineralization during endochondral ossification [183,184], and also exhibit hypomineralized dentin and enamel in the teeth [185,186].
Another enzyme that participates in phospholipid metabolism is PLA2G6, which breaks down phosphatidylcholine to produce arachidonic acid and lysophospholipid [187]. The absence of Pla2g6 in mice results in neurodegeneration and kyphosis due to motor dysfunction, without any bone defect, as seen in patients with mutations in this gene [188].
MBOAT7, a member of the acyltransferase family, catalyzes the conversion of lysophosphatidylinositol (LPI) into phosphatidylinositol; Mboat7-deficient mice (Mboat7−/− mice) display domed-shaped calvaria [189]. Since LPI bound to G-protein coupled receptor 55 (GPR55) and dysregulated LPI‒GPR55 signaling results in metabolic diseases [190], treatment of monocytes and pre-osteoclasts with either LPI or a GPR55 agonist, O-1602, induces osteoclastogenesis through osteoclast differentiation/polarization and bone resorption activity in vitro [191]. Moreover, Gpr55−/− mice show an osteopetrosis-like phenotype, a reduced number of osteoclasts, and increased bone mass, without effects on osteoblastogenesis and bone matrix formation [191].
AGPAT3 and its paralog AGPAT4 are other members of the acyltransferase family of proteins; they convert lysophosphatidic acid (LPA) to phosphatidic acid during phospholipid biosynthesis. An increasing number of studies indicate that LPA differentially affects various bone cells via LPA receptors. For example, LPA accelerates osteogenic differentiation of bone marrow mesenchymal stromal cells, stimulates osteoblast proliferation and maturation, and promotes bone resorption by osteoclasts [192]. Accordingly, Agpat3+/− and Agpat4−/− mice show decreased bone mineral content, although the amount of LPA may be increased (reported by the IMPC).

8. Conclusions

There are a variety of metabolic pathways that may affect bone development and homeostasis. In recent years, it has been reported that imbalance of cellular and systemic metabolism is associated with various bone diseases and developmental defects [193,194,195,196]. Several of these metabolic pathways have been extensively examined with great interest in clinical cohort studies and mouse genetic studies. While there is significant evidence showing a possible link between bone diseases and metabolic disorders, the specific players and molecular interactions in these metabolic networks remain to be determined. In this review, we focused on recent discoveries concerning metabolic pathways potentially associated with bone diseases. As indicated by several reports, the nutritional and pharmacological manipulation of these pathways may prevent or improve bone diseases caused by metabolic dysfunction.

Author Contributions

J.I. designed conception, M.M. and A.S. prepared the first draft, and C.I. and K.O. assisted with the revisions of the manuscript. A.S. and J.I. critically revised the manuscript. All authors have read and agreed to the published version of the manuscript.

Funding

This study was supported, in part, by grants from the National Institute of Dental and Craniofacial Research/National Institutes of Health (DE026767 and DE029818) to J.I., as well as by UTHealth School of Dentistry faculty funds to J.I.

Conflicts of Interest

The authors declare no conflicts interest.

Abbreviations

6PGD, 6-phosphogluconate dehydrogenase; 7-DHC, 7-dehydrocholesterol; Acadl1, acyl-CoA dehydrogenase, long chain; Acsl4, acyl-CoA synthetase long-chain family member 4; Acsl5, acyl-CoA synthetase long-chain family member 5; Acsbg2, acyl-CoA synthetase bubblegum family member 2; Agl, amylo-alpha-1, 6-glucosidase, 4-alpha-glucanotransferase; Agpat3, 1-acylglycerol-3-phosphate O-acyltransferase 3; Agpat4, 1-acylglycerol-3-phosphate O-acyltransferase 4; Aldob, aldolase, fructose-bisphosphate B; ATP, adenosine triphosphate; Bai1, brain-specific angiogenesis inhibitor 1; BMD, bone mineral density; CD36, CD 36 molecule; c-FOS, FBJ osteosarcoma oncogene; Chat, choline O-acetyltransferase; CHILD, Ichthyosiform nevus and Limb Defects; Chka, choline kinase alpha; Chkb, choline kinase beta; Col10a1, collagen type X alpha 1 chain; COPII, coat protein complex II; Cpt2, carnitine palmitoyltransferase 2; CREB, cAMP response element-binding protein; Ctgf, connective tissue growth factor; Cyp51, cytochrome P450, family 51; D-2HG, D-2-hydroxyglutarate; DAG, diacylglycerol; Dhh, desert hedgehog; Dhcr7, 7-dehydrocholesterol reductase; Dhcr24, 24-dehydrocholesterol reductase; Ennp1, ectonucleotide pyrophosphatase/phosphodiesterase 1; ENU, N-ethyl-N-nitrosourea; ER, endoplasmic reticulum; ERK1 (MAPK3), mitogen-activated protein kinase 3; ERK2 (MAPK1), mitogen-activated protein kinase 1; ERRα, estrogen related receptor alpha; F6P, fructose-6-phosphate; FAT, fatty acid translocase; Fdft1, farnesyl-diphosphate farnesyltransferase 1; FDPS, farnesyl diphosphate synthase; Fgfr3, fibroblast growth factor receptor type III; FPP, farnesyl pyrophosphate; G1P, glucose 1-phosphate; G6P, D-glucose-6-phosphate; G6pase, glucose 6-phosphatase; G6pc, glucose-6-phosphatase catalytic subunit; Gad1, glutamate decarboxylase 1; Gfpt1, glutamine fructose-6-phosphate transaminase 1; Gfpt2, glutamine fructose-6-phosphate transaminase 2; GGPP, geranylgeranyl diphosphate; GLUT1, glucose transporter 1; Gpr40, G protein-coupled receptor 40; Gpr41, G protein-coupled receptor 41; Gpr43, G protein-coupled receptor 43; Gpr55, G protein-coupled receptor 55; Gpr120, G protein-coupled receptor 120; GGPPS1, geranylgeranyl diphosphate synthase; GH, growth hormone; Gpt1, glutamic pyruvic transaminase 1; GSD-Ia, glycogen storage disease type Ia; GSD-Ib, glycogen storage disease type Ib; GSD-III, glycogen storage disease type III; GTP, guanosine triphosphate; HDL-C, high-density lipoprotein cholesterol; HMG-CoA, 3-hydroxy-3-methylglutaryl-coenzyme A; HMGCR, HMG-CoA reductase; Hsd17b7, hydroxysteroid (17-beta) dehydrogenase 7; Hsd17b12, hydroxysteroid (17-beta) dehydrogenase 12; Idh1, isocitrate dehydrogenase 1, cytosolic; IGF1, insulin-like growth factor 1; IGF1R, insulin-like growth factor 1 receptor; Ihh, Indian hedgehog; Insig1, insulin-induced gene; Insig2, insulin-induced gene 2; LPA, lysophosphatidic acid; Lpar1, lysophosphatidic acid receptor 1; Lpar3, lysophosphatidic acid receptor 3; LPI, lysophosphatidylinositol; LRB, lamin B receptor; Mboat7, membrane bound O-acyltransferase domain containing 7; Mcat, malonyl-CoA-acyl carrier protein transacylase; Me2, NAD-dependent malic enzyme, mitochondria; NADH, nicotinamide adenine dinucleotide; NADP/NADPH, nicotinamide adenine dinucleotide phosphate; N-BP, nitrogen containing bisphosphonate; NFATc1, nuclear factor of activated T cells 1; NFκB, nuclear factor kappa-light-chain-enhancer of activated B cell; Nsdhl, NAD(P) dependent steroid dehydrogenase-like; PA, phosphatidic acid; Pi, phosphate; PDC, pyruvate dehydrogenase complex; Pdk2, pyruvate dehydrogenase lipoamide kinase isozyme 2; Pdk4, pyruvate dehydrogenase kinase 4; Pgd, phosphogluconate dehydrogenase; Phospho1, phosphoethanolamine/phosphocholine phosphatase; PIP2, phosphatidylinositol-(4,5)-bisphosphate; Pla2g6, phospholipase A2 group VI; POR, cytochrome P450 oxidoreductase; PPi, pyrophosphate; Ppt1, palmitoyl-protein thioesterase 1; RANKL (TNFS11), receptor activator of nuclear factor kappa-B ligand (tumor necrosis factor (ligand) superfamily, member 11); Runx2, runt related transcription factor 2; Sc4mol, methylsterol monooxygenase 1; Sc5d, sterol-C5-desaturase; Scap, sterol regulatory element-binding protein cleavage-activating protein; SDH, succinate dehydrogenase; Sdhc, succinate dehydrogenase complex subunit C; Shh, sonic hedgehog; Slc2a1, solute carrier family 2 member 1; SLOS, Smith-Lemli-Opitz syndrome; Slc37a4, solute carrier family 37 member 4; SMO, smoothened; SNP, single nucleotide polymorphism; Srebp, sterol regulatory element-binding protein; Stab2, stabilin-2; TCA cycle, tricarboxylic acid cycle, aka citric acid cycle or Krebs cycle; TG, triglyceride; Tim4 (Timd4), T-cell membrane protein 4 (T-cell immunoglobulin and mucin domain containing 4); Tm7sf2, transmembrane 7 superfamily member 2; UDP, uridine diphosphate; UGP2, UDP-glucose pyrophosphorylase 2; UTP, uridine triphosphate.

References

  1. Raggatt, L.J.; Partridge, N.C. Cellular and molecular mechanisms of bone remodeling. J. Biol. Chem. 2010, 285, 25103–25108. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  2. Schilling, C.H.; Letscher, D.; Palsson, B.O. Theory for the systemic definition of metabolic pathways and their use in interpreting metabolic function from a pathway-oriented perspective. J. Theor. Biol. 2000, 203, 229–248. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  3. De Berardinis, R.J.; Thompson, C.B. Cellular metabolism and disease: What do metabolic outliers teach us? Cell 2012, 148, 1132–1144. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  4. Shen, L.C.; Fall, L.; Walton, G.M.; Atkinson, D.E. Interaction between energy charge and metabolite modulation in the regulation of enzymes of amphibolic sequences. Phosphofructokinase and pyruvate dehydrogenase. Biochemistry 1968, 7, 4041–4045. [Google Scholar] [CrossRef] [PubMed]
  5. Alekos, N.S.; Moorer, M.C.; Riddle, R.C. Dual Effects of Lipid Metabolism on Osteoblast Function. Front. Endocrinol. 2020, 11, 578194. [Google Scholar] [CrossRef]
  6. Shah, V.N.; Harrall, K.K.; Shah, C.S.; Gallo, T.L.; Joshee, P.; Snell-Bergeon, J.K.; Kohrt, W.M. Bone mineral density at femoral neck and lumbar spine in adults with type 1 diabetes: A meta-analysis and review of the literature. Osteoporos. Int. 2017, 28, 2601–2610. [Google Scholar] [CrossRef]
  7. Vestergaard, P. Discrepancies in bone mineral density and fracture risk in patients with type 1 and type 2 diabetes--a meta-analysis. Osteoporos. Int. 2007, 18, 427–444. [Google Scholar] [CrossRef]
  8. Chin, K.-Y.; Chan, C.Y.; Subramaniam, S.; Muhammad, N.; Fairus, A.; Ng, P.Y.; Jamil, N.A.; Aziz, N.A.; Ima-Nirwana, S.; Mohamed, N. Positive association between metabolic syndrome and bone mineral density among Malaysians. Int. J. Med. Sci. 2020, 17, 2585–2593. [Google Scholar] [CrossRef]
  9. Hunt, H.B.; Miller, N.A.; Hemmerling, K.J.; Koga, M.; Lopez, K.A.; Taylor, E.A.; Sellmeyer, D.E.; Moseley, K.F.; Donnelly, E. Bone Tissue Composition in Postmenopausal Women Varies With Glycemic Control From Normal Glucose Tolerance to Type 2 Diabetes Mellitus. J. Bone Miner. Res. 2020. [Google Scholar] [CrossRef]
  10. Panahi, N.; Soltani, A.; Ghasem-Zadeh, A.; Shafiee, G.; Heshmat, R.; Razi, F.; Mehrdad, N.; Nabipour, I.; Larijani, B.; Ostovar, A. Associations between the lipid profile and the lumbar spine bone mineral density and trabecular bone score in elderly Iranian individuals participating in the Bushehr Elderly Health Program: A population-based study. Arch. Osteoporos. 2019, 14, 52. [Google Scholar] [CrossRef]
  11. Saoji, R.; Das, R.S.; Desai, M.; Pasi, A.; Sachdeva, G.; Das, T.K.; Khatkhatay, M.I. Association of high-density lipoprotein, triglycerides, and homocysteine with bone mineral density in young Indian tribal women. Arch. Osteoporos. 2018, 13, 108. [Google Scholar] [CrossRef] [PubMed]
  12. Zhou, Y.; Deng, T.; Zhang, H.; Guan, Q.; Zhao, H.; Yu, C.; Shao, S.; Zhao, M.; Xu, J. Hypercholesterolaemia increases the risk of high‑turnover osteoporosis in men. Mol. Med. Rep. 2019, 19, 4603–4612. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  13. Tang, D.; Wang, E.; Xu, Y.; Liang, C.; Liu, C.; Lin, X.; Li, J. Is hyperglycemia the only risk factor for implant in type 2 diabetics during the healing period? Oral. Dis. 2020. [Google Scholar] [CrossRef] [PubMed]
  14. Park, H.Y.; Han, K.; Kim, Y.; Kim, Y.H.; Sur, Y.J. The risk of hip fractures in individuals over 50 years old with prediabetes and type 2 diabetes—A longitudinal nationwide population-based study. Bone 2020, 142, 115691. [Google Scholar] [CrossRef]
  15. Cignachi, N.P.; Ribeiro, A.; Machado, G.D.; Cignachi, A.P.; Kist, L.W.; Bogo, M.R.; Silva, R.B.; Campos, M.M. Bone regeneration in a mouse model of type 1 diabetes: Influence of sex, vitamin D3, and insulin. Life Sci. 2020, 263, 118593. [Google Scholar] [CrossRef]
  16. Porter, F.D.; Herman, G.E. Malformation syndromes caused by disorders of cholesterol synthesis. J. Lipid. Res. 2011, 52, 6–34. [Google Scholar] [CrossRef] [Green Version]
  17. Hentschel, A.; Zahedi, R.P.; Ahrends, R. Protein lipid modifications--More than just a greasy ballast. Proteomics 2016, 16, 759–782. [Google Scholar] [CrossRef]
  18. Xiao, X.; Tang, J.-J.; Peng, C.; Wang, Y.; Fu, L.; Qiu, Z.-P.; Xiong, Y.; Yang, L.-F.; Cui, H.-W.; He, X.-L.; et al. Cholesterol Modification of Smoothened Is Required for Hedgehog Signaling. Mol. Cell 2017, 66, 154–162.e10. [Google Scholar] [CrossRef] [Green Version]
  19. Porter, J.A.; Young, K.E.; Beachy, P.A. Cholesterol modification of hedgehog signaling proteins in animal development. Science 1996, 274, 255–259. [Google Scholar] [CrossRef]
  20. Ohba, S. Hedgehog Signaling in Skeletal Development: Roles of Indian Hedgehog and the Mode of Its Action. Int. J. Mol. Sci. 2020, 21, 6665. [Google Scholar] [CrossRef]
  21. Alman, B.A. The role of hedgehog signalling in skeletal health and disease. Nat. Rev. Rheumatol. 2015, 11, 552–560. [Google Scholar] [CrossRef] [PubMed]
  22. Perrimon, N.; Pitsouli, C.; Shilo, B.Z. Signaling mechanisms controlling cell fate and embryonic patterning. Cold Spring Harb. Perspect. Biol. 2012, 4, a005975. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  23. Lewis, P.M.; Dunn, M.P.; McMahon, J.A.; Logan, M.; Martin, J.F.; St-Jacques, B.; McMahon, A.P. Cholesterol Modification of Sonic Hedgehog Is Required for Long-Range Signaling Activity and Effective Modulation of Signaling by Ptc1. Cell 2001, 105, 599–612. [Google Scholar] [CrossRef] [Green Version]
  24. Li, Y.; Zhang, H.; Litingtung, Y.; Chiang, C. Cholesterol modification restricts the spread of Shh gradient in the limb bud. Proc. Natl. Acad. Sci. USA 2006, 103, 6548–6553. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  25. Huang, X.; Litingtung, Y.; Chiang, C. Ectopic sonic hedgehog signaling impairs telencephalic dorsal midline development: Implication for human holoprosencephaly. Hum. Mol. Genet. 2007, 16, 1454–1468. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  26. Zhang, Y.; Li, Q.; Dong, M.; Han, X. Effect of cholesterol on the fluidity of supported lipid bilayers. Colloids Surf. B Biointerfaces 2020, 196, 111353. [Google Scholar] [CrossRef]
  27. Maxfield, F.R.; Van Meer, G. Cholesterol, the central lipid of mammalian cells. Curr. Opin. Cell Biol. 2010, 22, 422–429. [Google Scholar] [CrossRef] [Green Version]
  28. Zakany, F.; Kovacs, T.; Panyi, G.; Varga, Z. Direct and indirect cholesterol effects on membrane proteins with special focus on potassium channels. Biochim. Biophys. Acta Mol. Cell Biol. Lipids 2020, 1865, 158706. [Google Scholar] [CrossRef]
  29. Ouweneel, A.B.; Thomas, M.J.; Sorci-Thomas, M.G. The ins and outs of lipid rafts: Functions in intracellular cholesterol homeostasis, microparticles, and cell membranes. J. Lipid Res. 2020, 61, 676–686. [Google Scholar] [CrossRef] [Green Version]
  30. Dietschy, J.M.; Turley, S.D.; Spady, D.K. Role of liver in the maintenance of cholesterol and low density lipoprotein homeostasis in different animal species, including humans. J. Lipid Res. 1993, 34, 1637–1659. [Google Scholar]
  31. Signore, I.A.; Jerez, C.; Figueroa, D.; Suazo, J.; Marcelain, K.; Cerda, O.; Flores, A.C. Inhibition of the 3-hydroxy-3-methyl-glutaryl-CoA reductase induces orofacial defects in zebrafish. Birth Defects Res. Part A Clin. Mol. Teratol. 2016, 106, 814–830. [Google Scholar] [CrossRef] [PubMed]
  32. Mundy, G.R.; Garrett, R.; Harris, S.; Chan, J.; Chen, D.; Rossini, G.; Boyce, B.; Zhao, M.; Gutierrez, G. Stimulation of Bone Formation in Vitro and in Rodents by Statins. Science 1999, 286, 1946–1949. [Google Scholar] [CrossRef] [PubMed]
  33. Maeda, T.; Matsunuma, A.; Kawane, T.; Horiuchi, N. Simvastatin promotes osteoblast differentiation and mineralization in MC3T3-E1 cells. Biochem. Biophys. Res. Commun. 2001, 280, 874–877. [Google Scholar] [CrossRef] [PubMed]
  34. Viereck, V.; Gründker, C.; Blaschke, S.; Frosch, K.-H.; Schoppet, M.; Emons, G.; Hofbauer, L.C. Atorvastatin stimulates the production of osteoprotegerin by human osteoblasts. J. Cell. Biochem. 2005, 96, 1244–1253. [Google Scholar] [CrossRef] [PubMed]
  35. Ghosh-Choudhury, N.; Mandal, C.C.; Choudhury, G.G. Statin-induced Ras activation integrates the phosphatidylinositol 3-kinase signal to Akt and MAPK for bone morphogenetic protein-2 expression in osteoblast differentiation. J. Biol. Chem. 2007, 282, 4983–4993. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  36. Calixto, J.C.; Lima, C.E.; Frederico, L.; Lima, R.P.; Anbinder, A.L. The influence of local administration of simvastatin in calvarial bone healing in rats. J. Craniomaxillofac. Surg. 2011, 39, 215–220. [Google Scholar] [CrossRef]
  37. Van Hong, T.D.; Chiang, C.-P.; Liu, Y.-F.; Kuo, M.Y.-P.; Lin, S.; Lai, J.-Y.; Lee, B.-S. Highly efficient release of lovastatin from poly(lactic-co-glycolic acid) nanoparticles enhances bone repair in rats. J. Orthop. Res. 2011, 29, 1504–1510. [Google Scholar] [CrossRef]
  38. Killeen, A.C.; Rakes, P.A.; Schmid, M.J.; Zhang, Y.; Narayana, N.; Marx, D.B.; Payne, J.B.; Wang, N.; Reinhardt, R.A. Impact of Local and Systemic Alendronate on Simvastatin-Induced New Bone Around Periodontal Defects. J. Periodontol. 2012, 83, 1463–1471. [Google Scholar] [CrossRef]
  39. Yamashita, A.; Morioka, M.; Kishi, H.; Kimura, T.; Yahara, Y.; Okada, M.; Fujita, K.; Sawai, H.; Ikegawa, S.; Tsumaki, N. Statin treatment rescues FGFR3 skeletal dysplasia phenotypes. Nature 2014, 513, 507–511. [Google Scholar] [CrossRef]
  40. Funkhouser, H.L.; Adera, T.; Adler, R.A. Effect of HMG-CoA reductase inhibitors (statins) on bone mineral density. J. Clin. Densitom. 2002, 5, 151–158. [Google Scholar] [CrossRef]
  41. Hernandez, J.L.; Olmos, J.M.; Romaña, G.; Martinez, J.; Castillo, J.; Yezerska, I.; Pinedo, G.; González-Macías, J. Bone mineral density in statin users: A population-based analysis from a Spanish cohort. J. Bone Miner. Metab. 2013, 32, 184–191. [Google Scholar] [CrossRef] [PubMed]
  42. Liu, J.; Zhu, L.P.; Yang, X.L.; Huang, H.L.; Ye, D.Q. HMG-CoA reductase inhibitors (statins) and bone mineral density: A meta-analysis. Bone 2013, 54, 151–156. [Google Scholar] [CrossRef] [PubMed]
  43. Safaei, H.; Janghorbani, M.; Aminorroaya, A.; Amini, M. Lovastatin effects on bone mineral density in postmenopausal women with type 2 diabetes mellitus. Acta Diabetol. 2007, 44, 76–82. [Google Scholar] [CrossRef] [PubMed]
  44. Bone, H.G.; Kiel, D.P.; Lindsay, R.S.; Lewiecki, E.M.; Bolognese, M.A.; Leary, E.T.; Lowe, W.; McClung, M.R. Effects of Atorvastatin on Bone in Postmenopausal Women with Dyslipidemia: A Double-Blind, Placebo-Controlled, Dose-Ranging Trial. J. Clin. Endocrinol. Metab. 2007, 92, 4671–4677. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  45. Uysal, A.R.; Delibasi, T.; Erdogan, M.F.; Kamel, N.; Başkal, N.; Tonyukuk, V.; Çorapçıoğlu, D.; Gullu, S.; Erdoğan, G. Effect of Simvastatin use on Bone Mineral Density in Women with Type 2 Diabetes. Endocr. Pract. 2007, 13, 114–116. [Google Scholar] [CrossRef] [PubMed]
  46. Tang, Q.O.; Tran, G.T.; Gamie, Z.; Graham, S.; Tsialogiannis, E.; Tsiridis, E.; Linder, T.; Tsiridis, E. Statins: Under investigation for increasing bone mineral density and augmenting fracture healing. Expert Opin. Investig. Drugs 2008, 17, 1435–1463. [Google Scholar] [CrossRef]
  47. Fajardo, M.E.; Rocha, M.L.; Sanchez-Marin, F.J.; Espinosa-Chavez, E.J. Effect of atorvastatin on chronic periodontitis: A randomized pilot study. J. Clin. Periodontol. 2010, 37, 1016–1022. [Google Scholar] [CrossRef]
  48. Rodriguez, J.B.; Falcone, B.N.; Szajnman, S.H. Approaches for Designing new Potent Inhibitors of Farnesyl Pyrophosphate Synthase. Expert Opin. Drug Discov. 2016, 11, 307–320. [Google Scholar] [CrossRef]
  49. Fernandez, D.; Ortega-Castro, J.; Frau, J. Human farnesyl pyrophosphate synthase inhibition by nitrogen bisphosphonates: A 3D-QSAR study. J. Comput. Aided. Mol. Des. 2013, 27, 739–754. [Google Scholar] [CrossRef]
  50. Reszka, A.A.; Rodan, G.A. Mechanism of action of bisphosphonates. Curr. Osteoporos. Rep. 2003, 1, 45–52. [Google Scholar] [CrossRef]
  51. Huang, X.; Huang, L.; Cheng, Y.; Li, F.; Zhou, Q.; Wu, C.; Shi, Q.; Guan, Z.; Liao, J.; Hong, W. Zoledronic acid inhibits osteoclast differentiation and function through the regulation of NF-κB and JNK signalling pathways. Int. J. Mol. Med. 2019, 44, 582–592. [Google Scholar] [CrossRef] [PubMed]
  52. Wei, W.; Schwaid, A.G.; Wang, X.; Wang, X.; Chen, S.; Chu, Q.; Saghatelian, A.; Wan, Y. Ligand Activation of ERRalpha by Cholesterol Mediates Statin and Bisphosphonate Effects. Cell Metab. 2016, 23, 479–491. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  53. Zhu, W.; Xu, R.; Du, J.; Fu, Y.; Li, S.; Zhang, P.; Liu, L.; Jiang, H. Zoledronic acid promotes TLR-4-mediated M1 macrophage polarization in bisphosphonate-related osteonecrosis of the jaw. FASEB J. 2019, 33, 5208–5219. [Google Scholar] [CrossRef] [PubMed]
  54. Kim, H.-J.; Kim, H.J.; Choi, Y.; Bae, M.-K.; Hwang, D.-S.; Shin, S.-H.; Lee, J.-Y. Zoledronate Enhances Osteocyte-Mediated Osteoclast Differentiation by IL-6/RANKL Axis. Int. J. Mol. Sci. 2019, 20, 1467. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  55. Duque, G.; Vidal, C.; Rivas, D. Protein isoprenylation regulates osteogenic differentiation of mesenchymal stem cells: Effect of alendronate, and farnesyl and geranylgeranyl transferase inhibitors. Br. J. Pharmacol. 2011, 162, 1109–1118. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  56. Coxon, F.P.; Helfrich, M.H.; Hof, R.V.; Sebti, S.; Ralston, S.H.; Hamilton, A.; Rogers, M.J. Protein Geranylgeranylation Is Required for Osteoclast Formation, Function, and Survival: Inhibition by Bisphosphonates and GGTI-298. J. Bone Miner. Res. 2000, 15, 1467–1476. [Google Scholar] [CrossRef]
  57. Weivoda, M.M.; Hohl, R.J. Effects of farnesyl pyrophosphate accumulation on calvarial osteoblast differentiation. Endocrinology 2011, 152, 3113–3122. [Google Scholar] [CrossRef] [Green Version]
  58. Tozawa, R.-I.; Ishibashi, S.; Osuga, J.-I.; Yagyu, H.; Oka, T.; Chen, Z.; Ohashi, K.; Perrey, S.; Shionoiri, F.; Yahagi, N.; et al. Embryonic Lethality and Defective Neural Tube Closure in Mice Lacking Squalene Synthase. J. Biol. Chem. 1999, 274, 30843–30848. [Google Scholar] [CrossRef] [Green Version]
  59. Coman, D.; Vissers, L.E.; Riley, L.G.; Kwint, M.P.; Hauck, R.; Koster, J.; Geuer, S.; Hopkins, S.; Hallinan, B.; Sweetman, L.; et al. Squalene Synthase Deficiency: Clinical, Biochemical, and Molecular Characterization of a Defect in Cholesterol Biosynthesis. Am. J. Hum. Genet. 2018, 103, 125–130. [Google Scholar] [CrossRef] [Green Version]
  60. Keber, R.; Motaln, H.; Wagner, K.D.; Debeljak, N.; Rassoulzadegan, M.; Ačimovič, J.; Rozman, D.; Horvat, S. Mouse Knockout of the Cholesterogenic Cytochrome P450 Lanosterol 14α-Demethylase (Cyp51) Resembles Antley-Bixler Syndrome. J. Biol. Chem. 2011, 286, 29086–29097. [Google Scholar] [CrossRef] [Green Version]
  61. Waterham, H.R.; Koster, J.; Mooyer, P.; Noort Gv, G.V.; Kelley, R.I.; Wilcox, W.R.; Wanders, R.J.A.; Hennekam, R.C.M.; Oosterwijk, J. Autosomal recessive HEM/Greenberg skeletal dysplasia is caused by 3 beta-hydroxysterol delta 14-reductase deficiency due to mutations in the lamin B receptor gene. Am. J. Hum. Genet. 2003, 72, 1013–1017. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  62. Wassif, C.A.; Brownson, K.E.; Sterner, A.L.; Forlino, A.; Zerfas, P.M.; Wilson, W.K.; Starost, M.F.; Porter, F.D. HEM dysplasia and ichthyosis are likely laminopathies and not due to 3β-hydroxysterol Δ14-reductase deficiency. Hum. Mol. Genet. 2007, 16, 1176–1187. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  63. Shultz, L.D.; Lyons, B.L.; Burzenski, L.M.; Gott, B.; Samuels, R.; Schweitzer, P.A.; Dreger, C.; Herrmann, H.; Kalscheuer, V.; Olins, A.L.; et al. Mutations at the mouse ichthyosis locus are within the lamin B receptor gene: A single gene model for human Pelger-Huet anomaly. Hum. Mol. Genet. 2003, 12, 61–69. [Google Scholar] [CrossRef] [PubMed]
  64. Bornholdt, D.; König, A.; Happle, R.; Leveleki, L.; Bittar, M.; Danarti, R.; Vahlquist, A.; Tilgen, W.; Reinhold, U.; Baptista, A.P.; et al. Mutational spectrum of NSDHL in CHILD syndrome. J. Med. Genet. 2005, 42, e17. [Google Scholar] [CrossRef] [PubMed]
  65. Liu, X.Y.; Kelley, R.I.; Zhao, W.; Denny, P.; Botcherby, M.; Cattanach, B.; Peters, J.; Hunsicker, P.R.; Mallon, A.M.; Strivens, M.A.; et al. The gene mutated in bare patches and striated mice encodes a novel 3beta-hydroxysteroid dehydrogenase. Nat. Genet. 1999, 22, 182–187. [Google Scholar] [CrossRef]
  66. Krakowiak, P.A.; Wassif, C.A.; Kratz, L.; Cozma, D.; Kovářová, M.; Harris, G.; Grinberg, A.; Yang, Y.; Hunter, A.G.; Tsokos, M.; et al. Lathosterolosis: An inborn error of human and murine cholesterol synthesis due to lathosterol 5-desaturase deficiency. Hum. Mol. Genet. 2003, 12, 1631–1641. [Google Scholar] [CrossRef] [Green Version]
  67. Gondre-Lewis, M.C.; Kruchten, A.E.; McNiven, M.A. Abnormal sterols in cholesterol-deficiency diseases cause secretory granule malformation and decreased membrane curvature. J. Cell Sci. 2006, 119, 1876–1885. [Google Scholar] [CrossRef] [Green Version]
  68. Prabhu, A.V.; Luu, W.; Li, D.; Sharpe, L.J.; Brown, A.J. DHCR7: A vital enzyme switch between cholesterol and vitamin D production. Prog. Lipid Res. 2016, 64, 138–151. [Google Scholar] [CrossRef]
  69. Porter, F.D. Smith-Lemli-Opitz syndrome: Pathogenesis, diagnosis and management. Eur. J. Hum. Genet. 2008, 16, 535–541. [Google Scholar] [CrossRef] [Green Version]
  70. Fitzky, B.U.; Witsch-Baumgartner, M.; Erdel, M.; Lee, J.N.; Paik, Y.-K.; Glossmann, H.; Utermann, G.; Moebius, F.F. Mutations in the 7-sterol reductase gene in patients with the Smith-Lemli-Opitz syndrome. Proc. Natl. Acad. Sci. USA 1998, 95, 8181–8186. [Google Scholar] [CrossRef] [Green Version]
  71. Fitzky, B.U.; Moebius, F.F.; Asaoka, H.; Waage-Baudet, H.; Xu, L.; Xu, G.; Maeda, N.; Kluckman, K.; Hiller, S.; Yu, H.; et al. 7-Dehydrocholesterol-dependent proteolysis of HMG-CoA reductase suppresses sterol biosynthesis in a mouse model of Smith-Lemli-Opitz/RSH syndrome. J. Clin. Investig. 2001, 108, 905–915. [Google Scholar] [CrossRef] [PubMed]
  72. Suzuki, A.; Ogata, K.; Yoshioka, H.; Shim, J.; Wassif, C.A.; Porter, F.D.; Iwata, J. Disruption of Dhcr7 and Insig1/2 in cholesterol metabolism causes defects in bone formation and homeostasis through primary cilium formation. Bone Res. 2020, 8, 1–14. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  73. Zerenturk, E.J.; Sharpe, L.J.; Ikonen, E.; Brown, A.J. Desmosterol and DHCR24: Unexpected new directions for a terminal step in cholesterol synthesis. Prog. Lipid Res. 2013, 52, 666–680. [Google Scholar] [CrossRef] [PubMed]
  74. Zolotushko, J.; Flusser, H.; Markus, B.; Shelef, I.; Langer, Y.; Heverin, M.; Björkhem, I.; Sivan, S.; Birk, O.S. The desmosterolosis phenotype: Spasticity, microcephaly and micrognathia with agenesis of corpus callosum and loss of white matter. Eur. J. Hum. Genet. 2011, 19, 942–946. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  75. Andersson, H.C.; Kratz, L.; Kelley, R. Desmosterolosis presenting with multiple congenital anomalies and profound developmental delay. Am. J. Med. Genet. 2002, 113, 315–319. [Google Scholar] [CrossRef] [PubMed]
  76. Rohanizadegan, M.; Sacharow, S. Desmosterolosis presenting with multiple congenital anomalies. Eur. J. Med. Genet. 2018, 61, 152–156. [Google Scholar] [CrossRef] [Green Version]
  77. Mirza, R.; Hayasaka, S.; Takagishi, Y.; Kambe, F.; Ohmori, S.; Maki, K.; Yamamoto, M.; Murakami, K.; Kaji, T.; Zadworny, D.; et al. DHCR24 Gene Knockout Mice Demonstrate Lethal Dermopathy with Differentiation and Maturation Defects in the Epidermis. J. Investig. Dermatol. 2006, 126, 638–647. [Google Scholar] [CrossRef] [Green Version]
  78. Jiang, X.S.; Backlund, P.S.; Wassif, C.A.; Yergey, A.L.; Porter, F.D. Quantitative proteomics analysis of inborn errors of cholesterol synthesis: Identification of altered metabolic pathways in DHCR7 and SC5D deficiency. Mol. Cell Proteom. 2010, 9, 1461–1475. [Google Scholar] [CrossRef] [Green Version]
  79. Dong, X.Y.; Tang, S.Q.; Chen, J.D. Dual functions of Insig proteins in cholesterol homeostasis. Lipids Health Dis. 2012, 11, 173. [Google Scholar] [CrossRef] [Green Version]
  80. Edwards, P.A.; Tabor, D.; Kast, H.R.; Venkateswaran, A. Regulation of gene expression by SREBP and SCAP. Biochim. Biophys. Acta 2000, 1529, 103–113. [Google Scholar] [CrossRef]
  81. Shimano, H. Sterol regulatory element-binding proteins (SREBPs): Transcriptional regulators of lipid synthetic genes. Prog. Lipid Res. 2001, 40, 439–452. [Google Scholar] [CrossRef]
  82. Jo, Y.; Debose-Boyd, R.A. Control of cholesterol synthesis through regulated ER-associated degradation of HMG CoA reductase. Crit. Rev. Biochem. Mol. Biol. 2010, 45, 185–198. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  83. Rawson, R.B. The SREBP pathway—insights from Insigs and insects. Nat. Rev. Mol. Cell Biol. 2003, 4, 631–640. [Google Scholar] [CrossRef] [PubMed]
  84. Engelking, L.J.; Evers, B.M.; Richardson, J.A.; Goldstein, J.L.; Brown, M.S.; Liang, G. Severe facial clefting in Insig-deficient mouse embryos caused by sterol accumulation and reversed by lovastatin. J. Clin. Investig. 2006, 116, 2356–2365. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  85. Tsushima, H.; Tang, Y.J.; Puviindran, V.; Hsu, S.-H.C.; Nadesan, P.; Yu, C.; Zhang, H.; Mirando, A.J.; Hilton, M.J.; Alman, B.A. Intracellular biosynthesis of lipids and cholesterol by Scap and Insig in mesenchymal cells regulates long bone growth and chondrocyte homeostasis. Development 2018, 145, dev162396. [Google Scholar] [CrossRef] [Green Version]
  86. Wu, S.; De Luca, F. Role of cholesterol in the regulation of growth plate chondrogenesis and longitudinal bone growth. J. Biol. Chem. 2004, 279, 4642–4647. [Google Scholar] [CrossRef] [Green Version]
  87. Zhang, H.; Wei, Q.; Tsushima, H.; Puviindran, V.; Tang, Y.J.; Pathmanapan, S.; Poon, R.; Ramu, E.; Al-Jazrawe, M.; Wunder, J.S.; et al. Intracellular cholesterol biosynthesis in enchondroma and chondrosarcoma. JCI Insight 2019, 5, 5. [Google Scholar] [CrossRef]
  88. Teplyuk, N.M.; Zhang, Y.; Lou, Y.; Hawse, J.R.; Hassan, M.Q.; Teplyuk, V.I.; Pratap, J.; Galindo, M.; Stein, J.L.; Stein, G.S.; et al. The Osteogenic Transcription Factor Runx2 Controls Genes Involved in Sterol/Steroid Metabolism, Including Cyp11a1 in Osteoblasts. Mol. Endocrinol. 2009, 23, 849–861. [Google Scholar] [CrossRef] [Green Version]
  89. Yang, J.; Yu, X.; Zhu, G.; Wang, R.; Lou, S.; Zhu, W.; Fu, C.; Liu, J.; Fan, L.; Li, D.; et al. Integrating GWAS and eQTL to predict genes and pathways for non-syndromic cleft lip with or without palate. Oral Dis. 2020. [Google Scholar] [CrossRef]
  90. Tsolis, K.C.; Bei, E.S.; Papathanasiou, I.; Kostopoulou, F.; Gkretsi, V.; Kalantzaki, K.; Malizos, K.; Zervakis, M.; Tsezou, A.; Economou, A. Comparative proteomic analysis of hypertrophic chondrocytes in osteoarthritis. Clin. Proteom. 2015, 12, 1–16. [Google Scholar] [CrossRef] [Green Version]
  91. Smith, S.; Witkowski, A.; Moghul, A.; Yoshinaga, Y.; Nefedov, M.; De Jong, P.; Feng, D.; Fong, L.; Tu, Y.; Hu, Y.; et al. Compromised Mitochondrial Fatty Acid Synthesis in Transgenic Mice Results in Defective Protein Lipoylation and Energy Disequilibrium. PLoS ONE 2012, 7, e47196. [Google Scholar] [CrossRef] [PubMed]
  92. Gupta, P.; Soyombo, A.A.; Atashband, A.; Wisniewski, K.E.; Shelton, J.M.; Richardson, J.A.; Hammer, R.E.; Hofmann, S.L. Disruption of PPT1 or PPT2 causes neuronal ceroid lipofuscinosis in knockout mice. Proc. Natl. Acad. Sci. USA 2001, 98, 13566–13571. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  93. Hofmann, S.L.; Das, A.K.; Lu, J.Y.; Soyombo, A.A. Positional candidate gene cloning of CLN1. Adv. Genet. 2001, 45, 69–92. [Google Scholar] [PubMed]
  94. Carcel-Trullols, J.; Kovacs, A.D.; Pearce, D.A. Cell biology of the NCL proteins: What they do and don’t do. Biochim. Biophys. Acta 2015, 1852, 2242–2255. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  95. Glatz, J.F.; Luiken, J.J.; Bonen, A. Membrane fatty acid transporters as regulators of lipid metabolism: Implications for metabolic disease. Physiol. Rev. 2010, 90, 367–417. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  96. Kevorkova, O.; Martineau, C.; Martin-Falstrault, L.; Sanchez-Dardon, J.; Brissette, L.; Moreau, R.A. Low-Bone-Mass Phenotype of Deficient Mice for the Cluster of Differentiation 36 (CD36). PLoS ONE 2013, 8, e77701. [Google Scholar] [CrossRef] [Green Version]
  97. Philippe, C.; Wauquier, F.; Lyan, B.; Coxam, V.; Wittrant, Y. GPR40, a free fatty acid receptor, differentially impacts osteoblast behavior depending on differentiation stage and environment. Mol. Cell. Biochem. 2015, 412, 197–208. [Google Scholar] [CrossRef]
  98. Ahn, S.H.; Park, S.-Y.; Kim, B.-J.; Koh, J.; Baek, J.-E.; Lee, S.-K.; Baek, W.-Y.; Lee, Y.-S.; Yoo, H.J.; Kim, H.; et al. Free Fatty Acid Receptor 4 (GPR120) Stimulates Bone Formation and Suppresses Bone Resorption in the Presence of Elevated n-3 Fatty Acid Levels. Endocrinology 2016, 157, 2621–2635. [Google Scholar] [CrossRef] [Green Version]
  99. Gao, B.; Huang, Q.; Jie, Q.; Lu, W.-G.; Wang, L.; Li, X.-J.; Sun, Z.; Hu, Y.-Q.; Chen, L.; Liu, B.-H.; et al. GPR120: A bi-potential mediator to modulate the osteogenic and adipogenic differentiation of BMMSCs. Sci. Rep. 2015, 5, 14080. [Google Scholar] [CrossRef] [Green Version]
  100. Kim, H.-J.; Yoon, H.-J.; Kim, B.K.; Kang, W.Y.; Seong, S.J.; Lim, M.-S.; Kim, S.-Y.; Yoon, Y.-R. G Protein-Coupled Receptor 120 Signaling Negatively Regulates Osteoclast Differentiation, Survival, and Function. J. Cell. Physiol. 2015, 231, 844–851. [Google Scholar] [CrossRef]
  101. Wauquier, F.; Philippe, C.; Léotoing, L.; Mercier, S.; Davicco, M.-J.; Lebecque, P.; Guicheux, J.; Pilet, P.; Miot-Noirault, E.; Poitout, V.; et al. The Free Fatty Acid Receptor G Protein-coupled Receptor 40 (GPR40) Protects from Bone Loss through Inhibition of Osteoclast Differentiation. J. Biol. Chem. 2013, 288, 6542–6551. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  102. Bellissimo, M.P.; Ziegler, T.R.; Jones, D.P.; Liu, K.H.; Fernandes, J.; Roberts, J.L.; Weitzmann, M.N.; Pacifici, R.; Alvarez, J.A. Plasma high-resolution metabolomics identifies linoleic acid and linked metabolic pathways associated with bone mineral density. Clin. Nutr. 2020, in press. [Google Scholar] [CrossRef] [PubMed]
  103. Ozaki, Y.; Morozumi, T.; Watanabe, K.; Toyama, T.; Sasaki, H.; Sato, T.; Yamamoto, Y.; To, M.; Inaba, K.; Tsukinoki, K.; et al. Inhibitory effect of omega-3 fatty acids on alveolar bone resorption and osteoclast differentiation. J. Oral Sci. 2020, 62, 298–302. [Google Scholar] [CrossRef] [PubMed]
  104. Sharma, T.; Mandal, C.C. Omega-3 fatty acids in pathological calcification and bone health. J. Food Biochem. 2020, 44, e13333. [Google Scholar] [CrossRef]
  105. Koren, N.; Simsa-Maziel, S.; Shahar, R.; Schwartz, B.; Monsonego-Ornan, E. Exposure to omega-3 fatty acids at early age accelerate bone growth and improve bone quality. J. Nutr. Biochem. 2014, 25, 623–633. [Google Scholar] [CrossRef] [PubMed]
  106. Kim, S.P.; Li, Z.; Zoch, M.L.; Frey, J.L.; Bowman, C.E.; Kushwaha, P.; Ryan, K.A.; Goh, B.C.; Scafidi, S.; Pickett, J.E.; et al. Fatty acid oxidation by the osteoblast is required for normal bone acquisition in a sex- and diet-dependent manner. JCI Insight 2017, 2, 2. [Google Scholar] [CrossRef]
  107. Lucas, S.; Omata, Y.; Hofmann, J.; Böttcher, M.; Iljazovic, A.; Sarter, K.; Albrecht, O.; Schulz, O.; Krishnacoumar, B.; Krönke, G.; et al. Short-chain fatty acids regulate systemic bone mass and protect from pathological bone loss. Nat. Commun. 2018, 9, 1–10. [Google Scholar] [CrossRef] [Green Version]
  108. Aswamenakul, K.; Klabklai, P.; Pannengpetch, S.; Tawonsawatruk, T.; Isarankura-Na-Ayudhya, C.; Roytrakul, S.; Nantasenamat, C.; Supokawej, A. Proteomic study of in vitro osteogenic differentiation of mesenchymal stem cells in high glucose condition. Mol. Biol. Rep. 2020, 47, 7505–7516. [Google Scholar] [CrossRef]
  109. Shao, X.; Cao, X.; Song, G.; Zhao, Y.; Shi, B. Metformin rescues the MG63 osteoblasts against the effect of high glucose on proliferation. J. Diabetes Res. 2014, 2014, 453940. [Google Scholar] [CrossRef]
  110. Bartolome, A.; López-Herradón, A.; Portal-Núñez, S.; García-Aguilar, A.; Esbrit, P.; Benito, M.; Guillen, C. Autophagy impairment aggravates the inhibitory effects of high glucose on osteoblast viability and function. Biochem. J. 2013, 455, 329–337. [Google Scholar] [CrossRef] [Green Version]
  111. Lee, S.Y.; Abel, E.D.; Long, F. Glucose metabolism induced by Bmp signaling is essential for murine skeletal development. Nat. Commun. 2018, 9, 4831. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  112. Hollander, J.M.; Zeng, L. The Emerging Role of Glucose Metabolism in Cartilage Development. Curr. Osteoporos Rep. 2019, 17, 59–69. [Google Scholar] [CrossRef] [PubMed]
  113. Li, B.; Lee, W.; Song, C.; Ye, L.; Abel, E.D.; Long, F. Both aerobic glycolysis and mitochondrial respiration are required for osteoclast differentiation. FASEB J. 2020, 34, 11058–11067. [Google Scholar] [CrossRef] [PubMed]
  114. Ohnishi, T.; Kusuyama, J.; Bandow, K.; Matsuguchi, T. Glut1 expression is increased by p53 reduction to switch metabolism to glycolysis during osteoblast differentiation. Biochem. J. 2020, 477, 1795–1811. [Google Scholar] [CrossRef] [Green Version]
  115. Wei, J.; Shimazu, J.; Makinistoglu, M.P.; Maurizi, A.; Kajimura, D.; Zong, H.; Takarada, T.; Iezaki, T.; Pessin, J.E.; Hinoi, E.; et al. Glucose Uptake and Runx2 Synergize to Orchestrate Osteoblast Differentiation and Bone Formation. Cell 2015, 161, 1576–1591. [Google Scholar] [CrossRef] [Green Version]
  116. Chen, H.; Ji, X.; Lee, W.-C.; Shi, Y.; Li, B.; Abel, E.D.; Jiang, D.; Huang, W.; Long, F. Increased glycolysis mediates Wnt7b-induced bone formation. FASEB J. 2019, 33, 7810–7821. [Google Scholar] [CrossRef]
  117. Lee, W.C.; Ji, X.; Nissim, I.; Long, F. Malic Enzyme Couples Mitochondria with Aerobic Glycolysis in Osteoblasts. Cell Rep. 2020, 32, 108108. [Google Scholar] [CrossRef]
  118. Wolfsdorf, J.I.; Holm, I.A.; Weinstein, D.A. Glycogen storage diseases. Phenotypic, genetic, and biochemical characteristics, and therapy. Endocrinol. Metab. Clin. N. Am. 1999, 28, 801–823. [Google Scholar] [CrossRef]
  119. Cabrera-Abreu, J.; Crabtree, N.J.; Elias, E.; Fraser, W.; Cramb, R.; Alger, S. Bone mineral density and markers of bone turnover in patients with glycogen storage disease types I, III and IX. J. Inherit. Metab. Dis. 2004, 27, 1–9. [Google Scholar] [CrossRef]
  120. Melis, D.; Pivonello, R.; Cozzolino, M.; Della Casa, R.; Balivo, F.; Del Puente, A.; Dionisi-Vici, C.; Cotugno, G.; Zuppaldi, C.; Rigoldi, M.; et al. Impaired Bone Metabolism in Glycogen Storage Disease Type 1 Is Associated with Poor Metabolic Control in Type 1a and with Granulocyte Colony-Stimulating Factor Therapy in Type 1b. Horm. Res. Paediatr. 2014, 81, 55–62. [Google Scholar] [CrossRef]
  121. Lei, K.J.; Chen, H.; Pan, C.J.; Ward, J.M.; Mosinger, B., Jr.; Lee, E.J.; Westphal, H.; Mansfield, B.C.; Chou, J.Y. Glucose-6-phosphatase dependent substrate transport in the glycogen storage disease type-1a mouse. Nat. Genet. 1996, 13, 203–209. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  122. Brooks, E.D.E.D.; Little, D.; Arumugam, R.; Sun, B.; Curtis, S.; DeMaster, A.; Maranzano, M.; Jackson, M.W.; Kishnani, P.; Freemark, M.S.; et al. Pathogenesis of growth failure and partial reversal with gene therapy in murine and canine Glycogen Storage Disease type Ia. Mol. Genet. Metab. 2013, 109, 161–170. [Google Scholar] [CrossRef] [PubMed]
  123. Mathews, L.S.; Norstedt, G.; Palmiter, R.D. Regulation of insulin-like growth factor I gene expression by growth hormone. Proc. Natl. Acad. Sci. USA 1986, 83, 9343–9347. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  124. Dixit, M.; Poudel, S.B.; Yakar, S. Effects of GH/IGF axis on bone and cartilage. Mol. Cell Endocrinol. 2020, 519, 111052. [Google Scholar] [CrossRef]
  125. Yakar, S.; Werner, H.; Rosen, C.J. Insulin-like growth factors: Actions on the skeleton. J. Mol. Endocrinol. 2018, 61, T115–T137. [Google Scholar] [CrossRef]
  126. Qiu, T.; Crane, J.L.; Xie, L.; Xian, L.; Xie, H.; Cao, X. IGF-I induced phosphorylation of PTH receptor enhances osteoblast to osteocyte transition. Bone Res. 2018, 6, 5. [Google Scholar] [CrossRef]
  127. Xian, L.; Wu, X.; Pang, L.; Lou, M.; Rosen, C.J.; Qiu, T.; Crane, J.; Frassica, F.J.; Zhang, L.; Rodriguez, J.P.; et al. Matrix IGF-1 maintains bone mass by activation of mTOR in mesenchymal stem cells. Nat. Med. 2012, 18, 1095–1101. [Google Scholar] [CrossRef] [Green Version]
  128. Baker, J.; Liu, J.P.; Robertson, E.J.; Efstratiadis, A. Role of insulin-like growth factors in embryonic and postnatal growth. Cell 1993, 75, 73–82. [Google Scholar] [CrossRef]
  129. Stratikopoulos, E.; Szabolcs, M.; Dragatsis, I.; Klinakis, A.; Efstratiadis, A. The hormonal action of IGF1 in postnatal mouse growth. Proc. Natl. Acad. Sci. USA 2008, 105, 19378–19383. [Google Scholar] [CrossRef] [Green Version]
  130. Wang, Y.; Menendez, A.; Fong, C.; Elalieh, H.Z.; Kubota, T.; Long, R.; Bikle, D.D. IGF-I Signaling in Osterix-Expressing Cells Regulates Secondary Ossification Center Formation, Growth Plate Maturation, and Metaphyseal Formation During Postnatal Bone Development. J. Bone Miner. Res. 2015, 30, 2239–2248. [Google Scholar] [CrossRef]
  131. Wang, T.; Wang, Y.; Menendez, A.; Fong, C.; Babey, M.; Tahimic, C.G.T.; Cheng, Z.; Li, A.; Chang, W.; Bikle, D.D. Osteoblast-Specific Loss of IGF1R Signaling Results in Impaired Endochondral Bone Formation During Fracture Healing. J. Bone Miner. Res. 2015, 30, 1572–1584. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  132. Crane, J.L.; Zhao, L.; Frye, J.S.; Xian, L.; Qiu, T.; Cao, X. IGF-1 Signaling is Essential for Differentiation of Mesenchymal Stem Cells for Peak Bone Mass. Bone Res. 2013, 1, 186–194. [Google Scholar] [CrossRef] [PubMed]
  133. Chen, L.-Y.; Shieh, J.-J.; Lin, B.; Pan, C.-J.; Gao, J.-L.; Murphy, P.M.; Roe, T.F.; Moses, S.; Ward, J.M.; Lee, E.J.; et al. Impaired glucose homeostasis, neutrophil trafficking and function in mice lacking the glucose-6-phosphate transporter. Hum. Mol. Genet. 2003, 12, 2547–2558. [Google Scholar] [CrossRef] [PubMed]
  134. Wang, Y.; Liu, W.; Masuyama, R.; Fukuyama, R.; Ito, M.; Zhang, Q.; Komori, H.; Murakami, T.; Moriishi, T.; Miyazaki, T.; et al. Pyruvate dehydrogenase kinase 4 induces bone loss at unloading by promoting osteoclastogenesis. Bone 2012, 50, 409–419. [Google Scholar] [CrossRef] [PubMed]
  135. Lee, J.; Kim, M.; Lee, S.J.; Kim, B.; Choi, J.; Lee, S.M.; Ham, H.J.; Koh, J.; Jeon, J.; Lee, I. PDK2 deficiency prevents ovariectomy-induced bone loss in mice by regulating the RANKL-NFATc1 pathway during osteoclastogenesis. J. Bone Miner. Res. 2020. [Google Scholar] [CrossRef]
  136. Adeva-Andany, M.M.; Gonzalez-Lucan, M.; Donapetry-Garcia, C.; Fernandez-Fernandez, C.; Ameneiros-Rodriguez, E. Glycogen metabolism in humans. BBA Clin. 2016, 5, 85–100. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  137. Tokunaga, H.; Watanabe, J.; Kanai, K.; Sakaida, M.; Kanamura, S. Glucose 6-phosphatase and glycogen phosphorylase activities in chondrocytes in epiphyseal cartilage of growing rats. Anat. Rec. 1987, 219, 356–362. [Google Scholar] [CrossRef]
  138. Tokunaga, H.; Kanamura, S.; Watanabe, J.; Kanai, K.; Sakaida, M. High glucose-6-phosphatase activity in osteoblasts in the metaphysis of femur of growing rats. Anat. Rec. 1988, 220, 252–257. [Google Scholar] [CrossRef]
  139. Zhai, L.; Feng, L.; Xia, L.; Yin, H.; Xiang, S. Crystal structure of glycogen debranching enzyme and insights into its catalysis and disease-causing mutations. Nat. Commun. 2016, 7, 11229. [Google Scholar] [CrossRef]
  140. Shin, Y.S. Glycogen storage disease: Clinical, biochemical, and molecular heterogeneity. Semin. Pediatr. Neurol. 2006, 13, 115–120. [Google Scholar] [CrossRef]
  141. Melis, D.; Rossi, A.; Pivonello, R.; Del Puente, A.; Pivonello, C.; Cangemi, G.; Negri, M.; Colao, A.; Andria, G.; Parenti, G. Reduced bone mineral density in glycogen storage disease type III: Evidence for a possible connection between metabolic imbalance and bone homeostasis. Bone 2016, 86, 79–85. [Google Scholar] [CrossRef] [PubMed]
  142. Mundy, H.R.; Williams, J.E.; Lee, P.J.; Fewtrell, M.S. Reduction in bone mineral density in glycogenosis type III may be due to a mixed muscle and bone deficit. J. Inherit. Metab. Dis. 2008, 31, 418–423. [Google Scholar] [CrossRef] [PubMed]
  143. Pagliarani, S.; Lucchiari, S.; Bresolin, N.; Comi, G.P.; Ulzi, G.; Violano, R.; Ripolone, M.; Bordoni, A.; Nizzardo, M.; Gatti, S.; et al. Glycogen storage disease type III: A novel Agl knockout mouse model. Biochim. Biophys. Acta 2014, 1842, 2318–2328. [Google Scholar] [CrossRef] [Green Version]
  144. Roberts, F.; Zhu, D.; Farquharson, C.; Macrae, V.E. ENPP1 in the Regulation of Mineralization and Beyond. Trends Biochem. Sci. 2019, 44, 616–628. [Google Scholar] [CrossRef] [PubMed]
  145. Mackenzie, N.C.; Huesa, C.; Rutsch, F.; MacRae, V.E. New insights into NPP1 function: Lessons from clinical and animal studies. Bone 2012, 51, 961–968. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  146. O’Neill, W.C.; Sigrist, M.K.; McIntyre, C.W. Plasma pyrophosphate and vascular calcification in chronic kidney disease. Nephrol. Dial. Transplant. 2010, 25, 187–191. [Google Scholar] [CrossRef] [Green Version]
  147. Oheim, R.; Zimmerman, K.; Maulding, N.D.; Stürznickel, J.; Von Kroge, S.; Kavanagh, D.; Stabach, P.R.; Kornak, U.; Tommasini, S.M.; Horowitz, M.C.; et al. Human Heterozygous ENPP1 Deficiency Is Associated With Early Onset Osteoporosis, a Phenotype Recapitulated in a Mouse Model of Enpp1 Deficiency. J. Bone Miner. Res. 2019, 35, 528–539. [Google Scholar] [CrossRef] [Green Version]
  148. Babij, P.; Roudier, M.; Graves, T.; Han, C.-Y.E.; Chhoa, M.; Li, C.-M.; Juan, T.; Morony, S.; Grisanti, M.; Li, X.; et al. New Variants in the Enpp1 and Ptpn6 Genes Cause Low BMD, Crystal-Related Arthropathy, and Vascular Calcification. J. Bone Miner. Res. 2009, 24, 1552–1564. [Google Scholar] [CrossRef]
  149. Okawa, A.; Nakamura, I.; Goto, S.; Moriya, H.; Nakamura, Y.; Ikegawa, S. Mutation in Npps in a mouse model of ossification of the posterior longitudinal ligament of the spine. Nat. Genet. 1998, 19, 271–273. [Google Scholar] [CrossRef]
  150. Li, Q.; Pratt, C.H.; Dionne, L.A.; Fairfield, H.; Karst, S.Y.; Sundberg, J.P.; Uitto, J. Spontaneous asj-2J Mutant Mouse as a Model for Generalized Arterial Calcification of Infancy: A Large Deletion/Insertion Mutation in the Enpp1 Gene. PLoS ONE 2014, 9, e113542. [Google Scholar] [CrossRef]
  151. Li, Q.; Guo, H.; Chou, D.W.; Berndt, A.; Sundberg, J.P.; Uitto, J. Mutant Enpp1asj mice as a model for generalized arterial calcification of infancy. Dis. Model. Mech. 2013, 6, 1227–1235. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  152. Johnson, K.A.; Goding, J.; Van Etten, D.; Sali, A.; Hu, S.-I.; Farley, D.; Krug, H.; Hessle, L.; Millán, J.L.; Terkeltaub, R. Linked Deficiencies in Extracellular PPi and Osteopontin Mediate Pathologic Calcification Associated With Defective PC-1 and ANK Expression. J. Bone Miner. Res. 2003, 18, 994–1004. [Google Scholar] [CrossRef] [PubMed]
  153. Johnson, K.; Polewski, M.; van Etten, D.; Terkeltaub, R. Chondrogenesis mediated by PPi depletion promotes spontaneous aortic calcification in NPP1-/- mice. Arterioscler. Thromb. Vasc. Biol. 2005, 25, 686–691. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  154. Yamada, T.; Kawano, H.; Koshizuka, Y.; Fukuda, T.; Yoshimura, K.; Kamekura, S.; Saito, T.; Ikeda, T.; Kawasaki, Y.; Azuma, Y.; et al. Carminerin contributes to chondrocyte calcification during endochondral ossification. Nat. Med. 2006, 12, 665–670. [Google Scholar] [CrossRef] [PubMed]
  155. Harmey, D.; Hessle, L.; Narisawa, S.; Johnson, K.A.; Terkeltaub, R.; Millán, J.L. Concerted regulation of inorganic pyrophosphate and osteopontin by akp2, enpp1, and ank: An integrated model of the pathogenesis of mineralization disorders. Am. J. Pathol. 2004, 164, 1199–1209. [Google Scholar] [CrossRef]
  156. Takabayashi, S.; Seto, S.; Katoh, H. A New Enpp1 allele, Enpp1ttw-Ham, Identified in an ICR Closed Colony. Exp. Anim. 2014, 63, 193–204. [Google Scholar] [CrossRef] [Green Version]
  157. Sakamoto, M.; Hosoda, Y.; Kojimahara, K.; Yamazaki, T.; Yoshimura, Y. Arthritis and ankylosis in twy mice with hereditary multiple osteochondral lesions: With special reference to calcium deposition. Pathol. Int. 1994, 44, 420–427. [Google Scholar] [CrossRef]
  158. Kato, K.; Nishimasu, H.; Okudaira, S.; Mihara, E.; Ishitani, R.; Takagi, J.; Aoki, J.; Nureki, O. Crystal structure of Enpp1, an extracellular glycoprotein involved in bone mineralization and insulin signaling. Proc. Natl. Acad. Sci. USA 2012, 109, 16876–16881. [Google Scholar] [CrossRef] [Green Version]
  159. Liu, S.; Cadoux-Hudson, T.; Schofield, C.J. Isocitrate dehydrogenase variants in cancer—Cellular consequences and therapeutic opportunities. Curr. Opin. Chem. Biol. 2020, 57, 122–134. [Google Scholar] [CrossRef]
  160. Chang, S.; Yim, S.; Park, H. The cancer driver genes IDH1/2, JARID1C/ KDM5C, and UTX/ KDM6A: Crosstalk between histone demethylation and hypoxic reprogramming in cancer metabolism. Exp. Mol. Med. 2019, 51, 1–17. [Google Scholar] [CrossRef] [Green Version]
  161. Ye, D.; Guan, K.L.; Xiong, Y. Metabolism, Activity, and Targeting of D- and L-2-Hydroxyglutarates. Trends Cancer 2018, 4, 151–165. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  162. Suijker, J.; Baelde, H.J.; Roelofs, H.; Cleton-Jansen, A.M.; Bovee, J.V. The oncometabolite D-2-hydroxyglutarate induced by mutant IDH1 or -2 blocks osteoblast differentiation in vitro and in vivo. Oncotarget 2015, 6, 14832–14842. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  163. Hirata, M.; Sasaki, M.; Cairns, R.A.; Inoue, S.; Puviindran, V.; Li, W.Y.; Snow, B.E.; Jones, L.D.; Wei, Q.; Sato, S.; et al. Mutant IDH is sufficient to initiate enchondromatosis in mice. Proc. Natl. Acad. Sci. USA 2015, 112, 2829–2834. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  164. Dang, L.; White, D.W.; Gross, S.; Bennett, B.D.; Bittinger, M.A.; Driggers, E.M.; Fantin, V.R.; Jang, H.G.; Jin, S.; Keenan, M.C.; et al. Cancer-associated IDH1 mutations produce 2-hydroxyglutarate. Nature 2010, 465, 966. [Google Scholar] [CrossRef]
  165. Xu, W.; Yang, H.; Liu, Y.; Yang, Y.; Wang, P.; Kim, S.-H.; Ito, S.; Yang, C.; Wang, P.; Xiao, M.-T.; et al. Oncometabolite 2-Hydroxyglutarate Is a Competitive Inhibitor of α-Ketoglutarate-Dependent Dioxygenases. Cancer Cell 2011, 19, 17–30. [Google Scholar] [CrossRef] [Green Version]
  166. Bezawork-Geleta, A.; Rohlena, J.; Dong, L.; Pacak, K.; Neuzil, J. Mitochondrial Complex II: At the Crossroads. Trends Biochem. Sci. 2017, 42, 312–325. [Google Scholar] [CrossRef]
  167. Kang, J.-H.; Ko, H.-M.; Han, G.-D.; Lee, S.-Y.; Moon, J.-S.; Kim, M.-S.; Koh, J.-T.; Kim, S.-H. Dual role of phosphatidylserine and its receptors in osteoclastogenesis. Cell Death Dis. 2020, 11, 1–11. [Google Scholar] [CrossRef]
  168. Verma, S.K.; Leikina, E.; Melikov, K.; Gebert, C.; Kram, V.; Young, M.F.; Uygur, B.; Chernomordik, L.V. Cell-surface phosphatidylserine regulates osteoclast precursor fusion. J. Biol. Chem. 2017, 293, 254–270. [Google Scholar] [CrossRef] [Green Version]
  169. Hatakeyama, J.; Anan, H.; Hatakeyama, Y.; Matsumoto, N.; Takayama, F.; Wu, Z.; Matsuzaki, E.; Minakami, M.; Izumi, T.; Nakanishi, H. Induction of bone repair in rat calvarial defects using a combination of hydroxyapatite with phosphatidylserine liposomes. J. Oral Sci. 2019, 61, 111–118. [Google Scholar] [CrossRef] [Green Version]
  170. Chen, X.; Song, Z.; Chen, R.; Tan, S.; Huang, C.; Liu, Y.; Cheng, B.; Fu, Q. Lysophosphatidic acid enhanced the osteogenic and angiogenic capability of osteoblasts via LPA1/3 receptor. Connect. Tissue Res. 2018, 60, 85–94. [Google Scholar] [CrossRef]
  171. Yu, Z.-L.; Li, D.-Q.; Huang, X.-Y.; Xing, X.; Yu, R.-Q.; Li, Z.; Li, Z. Lysophosphatidic acid upregulates connective tissue growth factor expression in osteoblasts through the GPCR/PKC and PKA pathways. Int. J. Mol. Med. 2016, 37, 468–474. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  172. Gennero, I.; Laurencin-Dalicieux, S.; Conte-Auriol, F.; Briand-Mésange, F.; Laurencin, D.; Rue, J.; Beton, N.; Malet, N.; Mus, M.; Tokumura, A.; et al. Absence of the lysophosphatidic acid receptor LPA1 results in abnormal bone development and decreased bone mass. Bone 2011, 49, 395–403. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  173. Sims, S.M.; Panupinthu, N.; Lapierre, D.M.; Pereverzev, A.; Dixon, S.J. Lysophosphatidic acid: A potential mediator of osteoblast-osteoclast signaling in bone. Biochim. Biophys. Acta 2013, 1831, 109–116. [Google Scholar] [CrossRef] [PubMed]
  174. Blackburn, J.; Mansell, J.P. The emerging role of lysophosphatidic acid (LPA) in skeletal biology. Bone 2012, 50, 756–762. [Google Scholar] [CrossRef] [PubMed]
  175. Misgeld, T.; Burgess, R.W.; Lewis, R.M.; Cunningham, J.M.; Lichtman, J.W.; Sanes, J.R. Roles of neurotransmitter in synapse formation: Development of neuromuscular junctions lacking choline acetyltransferase. Neuron 2002, 36, 635–648. [Google Scholar] [CrossRef] [Green Version]
  176. Brandon, E.P.; Lin, W.; D’Amour, K.A.; Pizzo, D.P.; Dominguez, B.; Sugiura, Y.; Thode, S.; Ko, C.-P.; Thal, L.J.; Gage, F.H.; et al. Aberrant Patterning of Neuromuscular Synapses in Choline Acetyltransferase-Deficient Mice. J. Neurosci. 2003, 23, 539–549. [Google Scholar] [CrossRef] [Green Version]
  177. LeComte, M.-J.; Bertolus, C.; Santamaria, J.; Bauchet, A.-L.; Herbin, M.; Saurini, F.; Misawa, H.; Maisonobe, T.; Pradat, P.-F.; Nosten-Bertrand, M.; et al. Selective disruption of acetylcholine synthesis in subsets of motor neurons: A new model of late-onset motor neuron disease. Neurobiol. Dis. 2014, 65, 102–111. [Google Scholar] [CrossRef]
  178. Sher, R.B.; Aoyama, C.; Huebsch, K.A.; Ji, S.; Kerner, J.; Yang, Y.; Frankel, W.N.; Hoppel, C.L.; Wood, P.A.; Vance, D.E.; et al. A Rostrocaudal Muscular Dystrophy Caused by a Defect in Choline Kinase Beta, the First Enzyme in Phosphatidylcholine Biosynthesis. J. Biol. Chem. 2005, 281, 4938–4948. [Google Scholar] [CrossRef] [Green Version]
  179. Li, Z.; Wu, G.; Sher, R.B.; Khavandgar, Z.; Hermansson, M.; Cox, G.A.; Doschak, M.R.; Murshed, M.; Beier, F.; Vance, D.E. Choline kinase beta is required for normal endochondral bone formation. Biochim. Biophys. Acta 2014, 1840, 2112–2122. [Google Scholar] [CrossRef] [Green Version]
  180. Kular, J.; Tickner, J.C.; Pavlos, N.J.; Viola, H.M.; Abel, T.; Lim, B.S.; Yang, X.; Chen, H.; Cook, R.; Hool, L.C.; et al. Choline kinase beta mutant mice exhibit reduced phosphocholine, elevated osteoclast activity, and low bone mass. J. Biol. Chem. 2015, 290, 1729–1742. [Google Scholar] [CrossRef] [Green Version]
  181. Houston, B.; Stewart, A.J.; Farquharson, C. PHOSPHO1-A novel phosphatase specifically expressed at sites of mineralisation in bone and cartilage. Bone 2004, 34, 629–637. [Google Scholar] [CrossRef] [PubMed]
  182. Stewart, A.J.; Roberts, S.J.; Seawright, E.; Davey, M.G.; Fleming, R.H.; Farquharson, C. The presence of PHOSPHO1 in matrix vesicles and its developmental expression prior to skeletal mineralization. Bone 2006, 39, 1000–1007. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  183. Yadav, M.C.; Simão, A.M.S.; Narisawa, S.; Huesa, C.; McKee, M.D.; Farquharson, C.; Millán, J.L. Loss of skeletal mineralization by the simultaneous ablation of PHOSPHO1 and alkaline phosphatase function: A unified model of the mechanisms of initiation of skeletal calcification. J. Bone Miner. Res. 2011, 26, 286–297. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  184. Huesa, C.; Yadav, M.C.; Finnilä, M.A.; Goodyear, S.R.; Robins, S.P.; Tanner, K.E.; Aspden, R.M.; Millán, J.L.; Farquharson, C. PHOSPHO1 is essential for mechanically competent mineralization and the avoidance of spontaneous fractures. Bone 2011, 48, 1066–1074. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  185. Gao, X.J.; Olsen, N.J.; Pincus, T.; Stastny, P. HLA-DR alleles with naturally occurring amino acid substitutions and risk for development of rheumatoid arthritis. Arthritis Rheum. 1990, 33, 939–946. [Google Scholar] [CrossRef] [PubMed]
  186. Pandya, M.; Rosene, L.; Farquharson, C.; Millan, J.L.; Diekwisch, T.G.H. Intravesicular Phosphatase PHOSPHO1 Function in Enamel Mineralization and Prism Formation. Front. Physiol. 2017, 8, 805. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  187. Akiba, S.; Sato, T. Cellular function of calcium-independent phospholipase A2. Biol. Pharm. Bull. 2004, 27, 1174–1178. [Google Scholar] [CrossRef] [Green Version]
  188. Shinzawa, K.; Sumi, H.; Ikawa, M.; Matsuoka, Y.; Okabe, M.; Sakoda, S.; Tsujimoto, Y. Neuroaxonal Dystrophy Caused by Group VIA Phospholipase A2 Deficiency in Mice: A Model of Human Neurodegenerative Disease. J. Neurosci. 2008, 28, 2212–2220. [Google Scholar] [CrossRef] [Green Version]
  189. Anderson, K.E.; Kielkowska, A.; Durrant, T.N.; Juvin, V.; Clark, J.; Stephens, L.; Hawkins, P.T. Lysophosphatidylinositol-Acyltransferase-1 (LPIAT1) Is Required to Maintain Physiological Levels of PtdIns and PtdInsP2 in the Mouse. PLoS ONE 2013, 8, e58425. [Google Scholar] [CrossRef]
  190. Arifin, S.A.; Falasca, M. Lysophosphatidylinositol Signalling and Metabolic Diseases. Metabolites 2016, 6, 6. [Google Scholar] [CrossRef] [Green Version]
  191. Whyte, L.S.; Ryberg, E.; Sims, N.A.; Ridge, S.A.; Mackie, K.; Greasley, P.J.; Ross, R.A.; Rogers, M.J. The putative cannabinoid receptor GPR55 affects osteoclast function in vitro and bone mass in vivo. Proc. Natl. Acad. Sci. USA 2009, 106, 16511–16516. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  192. Wu, X.; Ma, Y.; Su, N.; Shen, J.; Zhang, H.; Wang, H. Lysophosphatidic acid: Its role in bone cell biology and potential for use in bone regeneration. Prostaglandins Other Lipid Mediat. 2019, 143, 106335. [Google Scholar] [CrossRef] [PubMed]
  193. Sidhu, K.; Ali, B.; Burt, L.A.; Boyd, S.K.; Khan, A. Spectrum of microarchitectural bone disease in inborn errors of metabolism: A cross-sectional, observational study. Orphanet J. Rare Dis. 2020, 15, 251. [Google Scholar] [CrossRef] [PubMed]
  194. Yang, J.; Ueharu, H.; Mishina, Y. Energy metabolism: A newly emerging target of BMP signaling in bone homeostasis. Bone 2020, 138, 115467. [Google Scholar] [CrossRef] [PubMed]
  195. Shi, Y.; Saben, J.L.; He, G.; Moley, K.H.; Long, F. Diet-Induced Metabolic Dysregulation in Female Mice Causes Osteopenia in Adult Offspring. J. Endocr. Soc. 2020, 4, bvaa028. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  196. Frommer, K.W.; Hasseli, R.; Schäffler, A.; Lange, U.; Rehart, S.; Steinmeyer, J.; Rickert, M.; Sarter, K.; Zaiss, M.M.; Culmsee, C.; et al. Free Fatty Acids in Bone Pathophysiology of Rheumatic Diseases. Front. Immunol. 2019, 10, 2757. [Google Scholar] [CrossRef] [Green Version]
Ijms 21 08992 g001 550
Figure 1. Cholesterol metabolism. This figure was drawn based on steroid biosynthesis pathway maps from the KEGG website. ACAT2, acetyl-CoA acetyltransferase 2; CYP51, cytochrome P450 family 51 subfamily; DHCR7, 7-dehydrocholesterol reductase; DHCR24, 24-dehydrocholesterol reductase; FDFT1, farnesyl-diphosphate farnesyltransferase 1; GGPP, geranylgeranyl pyrophosphate; HMGCR, HMG-CoA reductase; HMGCS1, 3-hydroxy-3-methylglutaryl-CoA synthase 1; HSD17B7, hydroxysteroid 17-beta dehydrogenase 7; LSS, lanosterol synthase; NSDHL, NAD(P)-dependent steroid dehydrogenase-like; SC4MOL (MSMO1), methylsterol monooxygenase 1; SC5D, sterol-C5-desaturase; SQLE, squalene epoxidase; TM7SF2, transmembrane 7 superfamily member 2.
Figure 1. Cholesterol metabolism. This figure was drawn based on steroid biosynthesis pathway maps from the KEGG website. ACAT2, acetyl-CoA acetyltransferase 2; CYP51, cytochrome P450 family 51 subfamily; DHCR7, 7-dehydrocholesterol reductase; DHCR24, 24-dehydrocholesterol reductase; FDFT1, farnesyl-diphosphate farnesyltransferase 1; GGPP, geranylgeranyl pyrophosphate; HMGCR, HMG-CoA reductase; HMGCS1, 3-hydroxy-3-methylglutaryl-CoA synthase 1; HSD17B7, hydroxysteroid 17-beta dehydrogenase 7; LSS, lanosterol synthase; NSDHL, NAD(P)-dependent steroid dehydrogenase-like; SC4MOL (MSMO1), methylsterol monooxygenase 1; SC5D, sterol-C5-desaturase; SQLE, squalene epoxidase; TM7SF2, transmembrane 7 superfamily member 2.
Ijms 21 08992 g001
Ijms 21 08992 g002 550
Figure 2. Fatty acid metabolism, glycolysis, and tricarboxylic acid cycle (TCA) cycle. Fatty acid biosynthesis, fatty acid elongation, glycolysis pathway, and TCA cycle were drawn based on maps from the KEGG website; 6PGD, 6-phosphogluconate dehydrogenase, decarboxylating; ACSBG2, acyl-CoA synthetase bubblegum family member 2; ALDOB, aldolase, fructose-bisphosphate B; CPT2, carnitine palmitoyltransferase 2; FPP, farnesyl pyrophosphate; G6Pase, glucose 6-phosphatase; IDH1, isocitrate dehydrogenase (NADP(+)) 1; MCAT, malonyl-CoA-acyl carrier protein transacylase; ME2, malic enzyme 2; PDC, pyruvate dehydrogenase complex; PDK1, pyruvate dehydrogenase kinase 1; PPT1, palmitoyl-protein thioesterase 1; SDHC, succinate dehydrogenase complex subunit C; SLC24A1, solute carrier family 24 member 1; SLC37A4, solute carrier family 37 member 4.
Figure 2. Fatty acid metabolism, glycolysis, and tricarboxylic acid cycle (TCA) cycle. Fatty acid biosynthesis, fatty acid elongation, glycolysis pathway, and TCA cycle were drawn based on maps from the KEGG website; 6PGD, 6-phosphogluconate dehydrogenase, decarboxylating; ACSBG2, acyl-CoA synthetase bubblegum family member 2; ALDOB, aldolase, fructose-bisphosphate B; CPT2, carnitine palmitoyltransferase 2; FPP, farnesyl pyrophosphate; G6Pase, glucose 6-phosphatase; IDH1, isocitrate dehydrogenase (NADP(+)) 1; MCAT, malonyl-CoA-acyl carrier protein transacylase; ME2, malic enzyme 2; PDC, pyruvate dehydrogenase complex; PDK1, pyruvate dehydrogenase kinase 1; PPT1, palmitoyl-protein thioesterase 1; SDHC, succinate dehydrogenase complex subunit C; SLC24A1, solute carrier family 24 member 1; SLC37A4, solute carrier family 37 member 4.
Ijms 21 08992 g002
Ijms 21 08992 g003 550
Figure 3. Glycogen degradation and glycogenesis. This figure was drawn based on the glycogen metabolism pathway map from the KEGG website. AGL, amylo-alpha-1,6-glucosidase 4-alpha-glucanotransferase; ENPP1, ectonucleotide pyrophosphatase/phosphodiesterase 1; G6Pase, glucose 6-phosphatase; PPi, pyrophosphate; Pi, phosphate; UDP, uridine diphosphate; UGP2, UDP-glucose pyrophosphorylase 2; UTP, uridine triphosphate.
Figure 3. Glycogen degradation and glycogenesis. This figure was drawn based on the glycogen metabolism pathway map from the KEGG website. AGL, amylo-alpha-1,6-glucosidase 4-alpha-glucanotransferase; ENPP1, ectonucleotide pyrophosphatase/phosphodiesterase 1; G6Pase, glucose 6-phosphatase; PPi, pyrophosphate; Pi, phosphate; UDP, uridine diphosphate; UGP2, UDP-glucose pyrophosphorylase 2; UTP, uridine triphosphate.
Ijms 21 08992 g003
Ijms 21 08992 g004 550
Figure 4. Phospholipid metabolism. This figure was drawn based on the ethanolamine and choline metabolism pathway map from the KEGG website. AGPAT3, 1-Acylglycerol-3-phosphate O-acyltransferase 3; AGPAT4, 1-Acylglycerol-3-phosphate O-acyltransferase 4; CHAT, choline O-acetyltransferase; CHKA, choline kinase alpha; CHKB, choline kinase beta; GPR55, G protein-coupled receptor 55; MBOAT7, membrane bound O-acyltransferase domain containing 7; PHOSPHO1, phosphoethanolamine/phosphocholine phosphatase 1; PLA2G6, phospholipase A2 group VI.
Figure 4. Phospholipid metabolism. This figure was drawn based on the ethanolamine and choline metabolism pathway map from the KEGG website. AGPAT3, 1-Acylglycerol-3-phosphate O-acyltransferase 3; AGPAT4, 1-Acylglycerol-3-phosphate O-acyltransferase 4; CHAT, choline O-acetyltransferase; CHKA, choline kinase alpha; CHKB, choline kinase beta; GPR55, G protein-coupled receptor 55; MBOAT7, membrane bound O-acyltransferase domain containing 7; PHOSPHO1, phosphoethanolamine/phosphocholine phosphatase 1; PLA2G6, phospholipase A2 group VI.
Ijms 21 08992 g004
Table
Table 1. Role of the metabolic pathways in bone cells.
Table 1. Role of the metabolic pathways in bone cells.
Metabolic PathwayBone CellsCascade/Enzyme/MoleculeFunction
Cholesterol synthesisOsteoblastsFarnesylationTo induce osteoblast differentiation and mineralization
Geranylgeranylation To suppress osteoblast differentiation and mineralization
Deficiency for the farnesyl-diphosphate farnesyltransferase (FDFT1) gene
Farnesyl pyrophosphate (FPP)		To suppress osteoblast differentiation and mineralization
Deficiency for the 7-dehydrocholesterol reductase (DHCR7) geneTo accelerate osteoblast differentiation and mineralization via ciliogenesis
and accelerate bone formation
Deficiency for the insulin-induced gene 1 and 2 (INSIG1 and INSIG2) genesTo suppress osteoblast differentiation and mineralization via ciliogenesis
and suppress bone formation
OsteoclastsGeranylgeranylation To induce osteoclast differentiation
ChondrocytesDeficiency for INSIG1 and INSIG2
Deficiency for the sterol regulatory element-binding protein cleavage-activating protein (SCAP) gene		To suppress chondrocyte differentiation
DHCR7 deficiencyTo suppress chondrocyte proliferation
Deficiency for the transmembrane 7 superfamily member 2 (TM7FS2) gene
Lamin B deficiency		To disorganize the growth plate
Mesenchymal stem cellsFarnesylationTo induce osteoblast differentiation and mineralization
Geranylgeranylation To suppress osteoblast differentiation and mineralization
Fatty acid metabolismOsteoblastsLong-chain fatty acids
Essential fatty acids		To induce osteoblast differentiation
Deficiency for the carnitine palmitoyltransferase 2 (CPT2)To suppress osteoblast differentiation
OsteoclastsLong-chain fatty acids
Short-chain fatty acids		To suppress osteoclast differentiation
Glycolysis & GluconeogenesisOsteoblastsGlucoseTo maintain ossification and osteoblast differentiation
Deficiency for the NAD-dependent malic enzyme, mitochondria (ME2) geneTo suppress proliferation and osteoblast differentiation
Deficiency for the glucose 6-phosphatase (G6Pase) geneTo suppress ossification
Deficiency for the pyruvate dehydrogenase kinase 4 (PDK4) gene [activation of pyruvate dehydrogenase complex (PDC)]To fail to induce osteoclastogenesis
OsteoclastsGlucoseTo maintain osteoclastogenesis
PDK4 deficiency (activation of PDC)To enhance osteoclastogenesis
and bone resorption
Deficiency for the pyruvate dehydrogenase kinase 2 (PDK2) gene (activation of PDC)To suppress osteoclastogenesis
and bone resorption
ChondrocytesGlucoseTo maintain growth plate development
Bone marrow mesenchymal stem cellsPDK4 deficiency (activation of PDC)To suppress osteoclastogenesis
Glycogenolysis & GlycogenesisOsteoblastsDeficiency for the ectonucleotide pyrophosphatase/phosphodiesterase 1 (ENPP1) geneTo accelerate mineralization
TCA cycleOsteoblastsD-2-hydroxyglutarateTo suppress bone formation
ChondrocytesOncogenic point mutations in the isocitrate dehydrogenase 1, cytosolic (IDH1)To enhance chondrocyte proliferation and differentiation
Mesenchymal stem cellsD-2-hydroxyglutarateTo suppress osteoblast differentiation
Phospholipid metabolismOsteoblastsPhosphatidylserineTo enhance osteoblast differentiation
Lysophosphatidic acidTo enhance osteoblast differentiation and mineralization
OsteoclastsPhosphatidylserineTo maintain osteoclast fusion and apoptosis
lysophosphatidylinositol (LPI) and
G protein-coupled receptor 55 (GPR55) agonists		To enhance osteoclastogenesis, osteoclast maturation, and bone resorption
Table
Table 2. Skeletal phenotype in mice with metabolic aberrations.
Table 2. Skeletal phenotype in mice with metabolic aberrations.
Metabolic PathwayMutant MiceSkeletal Phenotype
Cholesterol synthesisCyp51−/−cleft palate, micrognathia, brachycephaly, microglossia/aglossia, polydactyly/syndactyly, and malformation of long bones
Dhcr7−/−cleft palate, postaxial polydactyly, 2-3 toe syndactyly, microcephaly, and micrognathia
Insig1−/−;Insig2−/−midline cleft face or cleft palate, and micrognathia
Wnt1-Cre;Insig1F/F;Insig2−/−osteogenesis imperfecta-like calvaria
Prrx1-Cre;Insig1F/F;Insig2−/−disorganized growth plate, short limbs, and dwarfism
Col2a1-Cre;Insig1F/F;Insig2−/−disorganized growth plate, short limbs, midline cleft, and dwarfism
Lbr−/−disorganized hypertrophic chondrocytes, immature trabecular bone, and growth retardation
Lbrβ+/−; Tm7sf2∆4-7/∆4-7short growth plates, less trabecular bones, growth retardation, and cleft palate
Nsdhl+/− femaleskeletal dysplasia and chondrodysplasia punctata
Sc5d−/−cleft palate, micrognathia, tooth agenesis of lower incisors, calvaria hypomineralization, malformation of long bones, and syndactyly/polydactyly
Prrx1-Cre;ScapF/F
Col2a1-Cre;ScapF/F		disorganized growth plate, short limbs, and dwarfism
Fatty acid metabolismAcsbg2−/−low bone mineral density
Cd36−/−osteoblast differentiation defect and lower bone mass in adults
Gpr40−/−osteoporosis
Cpt2−/−abnormal vertebrae morphology
Oc-Cre;Cpt2F/F (osteocalcin-Cre)decreased bone acquisition
Ppt1−/−thick calvaria
Glycolysis & GluconeogenesisAldob−/−low bone mineral content and density
G6pc−/−cartilage dysplasia
Pgd+/−low bone mineral content and density
Dermo1-Cre;Slc2a1F/Fbone mineralization defects in endochondral and intramembranous ossification
Lys2-Cre;Slc2a1F/F femaleosteoclastogenesis defects and increased trabecular bone mass
Prx1-Cre;Slc2a1F/Fdisorganized growth plate, suppression of cartilage matrix synthesis, and short long bones
Slc37a4−/−delayed bone development
Glycogenolysis & GlycogenesisEnpp1−/−twy (spontaneous)
Enpp1 c.T737A 		bone mineralization defects
TCA cycleCol2a1-Cre;Idh1R132Q/+growth plate disorganization and cartilaginous dysplasia
Sdhc+/− femalelow bone mineral contents
Phospholipid metabolismAgpat3+/−
Agpat4−/−		low bone mineral contents
Chkbrmd/rmdchondrocyte differentiation arrest, suppression of cartilage matrix degradation, and bone deformity in the forelimbs
Chkbflp/flpdeformity in the forelimbs and low bone mass
Gpr55−/−osteopetrosis-like bone
Lpar1-/dwarfism, short limbs, rib cage deformity, short snout, osteoporotic bones, and low bone mineral density
Mboat7−/−domed shape calvaria
Phospho1−/−growth plate differentiation defects, low bone mineral density, fragile bones, osteomalacia, and hypomineralized amelogenesis imperfecta
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Suzuki, A.; Minamide, M.; Iwaya, C.; Ogata, K.; Iwata, J. Role of Metabolism in Bone Development and Homeostasis. Int. J. Mol. Sci. 2020, 21, 8992. https://doi.org/10.3390/ijms21238992

AMA Style

Suzuki A, Minamide M, Iwaya C, Ogata K, Iwata J. Role of Metabolism in Bone Development and Homeostasis. International Journal of Molecular Sciences. 2020; 21(23):8992. https://doi.org/10.3390/ijms21238992

Chicago/Turabian Style

Suzuki, Akiko, Mina Minamide, Chihiro Iwaya, Kenichi Ogata, and Junichi Iwata. 2020. "Role of Metabolism in Bone Development and Homeostasis" International Journal of Molecular Sciences 21, no. 23: 8992. https://doi.org/10.3390/ijms21238992

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop