Search Results (823)

Background/Objectives: Mitochondrial dysfunction, often reflected by a decline in mitochondrial DNA copy number (mtDNA-CN) in peripheral blood cells (PMBCs), is a key hallmark of biological aging and is linked to numerous adverse health outcomes, including frailty and cardiovascular disease. Furthermore, emerging evidence suggests that vitamin D may influence mitochondrial dysfunction. This cross-sectional study aims to investigate the associations of mtDNA-CN with muscular strength, self-rated health, and serum 25-hydroxyvitamin D₃ (25(OH)D₃) levels in a community-dwelling elderly population. Methods: A total of 149 elderly outpatients (≥65 years) from Soria, Spain, were included in this cross-sectional study. Muscular strength was assessed using the hand grip strength (HGS) test, and self-rated health-related quality of life (QoL) was measured using the EuroQoL five-dimension questionnaire (EQ-5D). Genomic DNA was extracted from peripheral blood, and mtDNA-CN was quantified using quantitative real-time PCR (qPCR). Serum 25(OH)D₃, intact parathyroid hormone (iPTH), phosphorus, calcium, albumin and other mineral metabolism markers were measured. Statistical analyses, including Spearman correlations and multivariate logistic regression, were performed to assess associations, with stratification by sex. Results: In the total population, a marginally significant positive correlation was observed between mtDNA copy number (mtDNA-CN) and serum 25(OH)D₃ levels (r = 0.210; p = 0.010), which did not remain significant after Bonferroni correction. Among women, lower mtDNA-CN was significantly linked to muscle weakness (p = 0.005), mobility problems (p = 0.009), and a trend toward self-care difficulties (p = 0.016). Multivariate analysis confirmed an independent association with increased mobility impairment risk (adjusted OR = 0.983; 95% CI: 0.97–1.00; p = 0.009). No significant associations were observed between mtDNA-CN and dynapenia or QoL components in the male group. Conclusions: This study identified a marginally significant positive correlation between serum 25(OH)D₃ levels and mtDNA-CN in the total population (r = 0.210; p = 0.010), which did not persist after Bonferroni correction, suggesting an exploratory link between vitamin D status and mitochondrial homeostasis in older adults. In addition, these results highlight sex-specific differences in mtDNA-CN as a potential biomarker of functional decline, particularly of mobility, in women. These findings support the idea that mtDNA-CN could serve as an integrated biomarker and that sex-specific nutrition could be used to promote healthy aging. Full article

Age-related chronic, low-grade inflammation, known as inflammaging, contributes to tissue damage and disease. In the lungs, inflammaging leads to abnormal tissue remodeling, reduced function, and decreased immunity. A key factor in inflammaging is declining acetylcholine signaling, which normally suppresses inflammation and promotes tissue repair. We tested whether increasing acetylcholine responsiveness could reverse age-related lung damage. Aged mice were treated with donepezil to increase acetylcholine availability. After six months, blood oxygen saturation and voluntary activity were significantly improved. Histologically, treated mice showed a reversal of alveolar enlargement (a hallmark of emphysema) and complete restoration of elastic fibers. Donepezil treatment also dramatically increased bronchus-associated lymphoid tissue (iBALT) formation. iBALT is the repository of tissue-resident memory lymphocytes, including memory cholinergic lymphocytes that produce acetylcholine to suppress inflammation during secondary infections. The age-related loss of iBALT contributes to the increased risks associated with respiratory infection in the elderly. This indicates that age-related lung function and respiratory immune deficits can be modulated by improving acetylcholine signaling. Repurposing an approved medication provides a direct pathway to clinical application for improving respiratory health and infection resistance during aging. Full article

Frontotemporal dementia (FTD) is a neurodegenerative disorder predominantly affecting individuals under 65 years of age, characterized by significant behavioral and language disabilities. Despite extensive research efforts, effective treatments for FTD remain elusive. Familial cases of FTD have been linked to genetic mutations in several key genes, among these, mutations in granulin (GRN) account for 5–20% of cases, leading to haploinsufficiency of progranulin (PGRN), a multifunctional glycoprotein. This study investigates the cellular pathology associated with GRN insufficiency by using fibroblasts derived from FTD patients carrying the c.709-1G>A GRN mutation (FTD-GRN). These fibroblasts exhibited pathological hallmarks of FTD, including lysosomes, autophagosomes, and lipofuscin accumulation, mirroring observations in affected patient tissues. Notably, we report mitochondrial abnormalities, characterized by mitochondrial swelling which is associated with decreased mitochondrial respiration, and lipid droplet accumulation, reflecting altered lipid metabolism. Experimental supplementation with recombinant human progranulin (rhPGRN) was associated with recovery of lysosomal acidification and attenuation of mitochondrial and lipid abnormalities in vitro. This study reveals that GRN haploinsufficiency induces mitochondrial and lipid dysfunctions, suggesting that these pathways may contribute to FTD-GRN pathogenesis and could be of interest for therapeutic development. Full article

Neurodegenerative diseases (NDs) are the most prevalent age-associated disorders, characterized by progressive neuronal loss and cognitive decline. Mitochondrial dysfunction is strictly associated with NDs and represent one of the hallmarks of these disorders, with neurological syndromes frequently representing the primary clinical manifestations of mitochondrial abnormalities. As central regulators of cellular bioenergetics, mitochondria play a pivotal role in both the physiological maintenance and pathogenesis of disease by different regulatory approaches. One of these, microRNAs (miRNAs), a class of small non-coding RNAs, are well-established regulators of gene expression across different biological pathways. These miRNAs were usually investigated within the cytoplasmic context, but recent discoveries have revealed the presence of these miRNAs in different parts of mitochondria, where they contribute to the regulation of gene expression and metabolic activity. These mitochondrial-localized miRNAs, termed mito-MiRNA, may originate from either nuclear or mitochondrial genomes and have been shown to modulate the translational machinery of the cells. Despite extensive research on cytoplasmic miRNAs, the functional roles of mito-MiRNA remain poorly understood, particularly in the context of neurodegenerative disorders. Based on these findings, this review aims to synthesize emerging evidence on the involvement of mito-MiRNA in in one of most prevalent neurodegenerative diseases—Parkinson’s disease (PD). Full article

The maintenance of bone homeostasis requires the coordinated activity of specialized cells (osteoblasts, osteoclasts and osteocytes), soluble factors and hormones with regulatory functions. Disruption of this tightly controlled balance contributes to several skeletal pathological conditions, among which osteoporosis is one of the most prevalent. Iron, an essential element for the basic cellular functions of both osteoblasts and osteoclasts, plays a pivotal role in preserving bone homeostasis and skeletal integrity. Both iron deficiency and iron overload impair bone remodeling through distinct but converging mechanisms. Iron deficiency compromises collagen synthesis, alters hypoxia-dependent signaling, and may affect vitamin D metabolism, collectively predisposing the individual to reduced bone mineral density and increased fracture risk. Conversely, excess iron enhances oxidative stress, promotes osteoclastogenesis, and suppresses osteoblast differentiation and function, thereby favoring bone loss, particularly in the aging population and postmenopausal individuals. Hepcidin, the master regulator of systemic iron availability, has emerged as a key modulator of bone turnover, whereas the bone-derived hormone fibroblast growth factor 23 (FGF23) links iron imbalance to phosphate homeostasis, vitamin D metabolism, and inflammation. Beyond metabolic bone diseases, dysregulated iron handling is increasingly recognized as a hallmark of osteosarcoma biology, influencing tumor growth, metabolic reprogramming, and an individual’s susceptibility to ferroptosis. The emerging, albeit only preclinical, evidence of the roles of iron and ferroptosis in osteosarcoma is therefore also covered. This review summarizes the current understanding of the interactions between iron metabolism and bone biology and addresses how an imbalance in iron metabolism may lead to major skeletal disorders. Overall, iron homeostasis could represent a potential target for preventing and treating osteoporosis and for improving therapeutic strategies for osteosarcoma. Full article

Background/Objectives. Ebstein’s anomaly (EA), which accounts for fewer than 1% of congenital heart diseases, and atrioventricular canal defect (AVCD), present in approximately 4–5% of cases, exceptionally coexist, with this combination observed in fewer than 0.5% of patients with AVCD. We aim to report the oldest documented case of a 45-year-old female with the exceptionally rare combination of complete AVCD, EA, and right ventricular hypoplasia and to provide a concise review of these anomalies. Case presentation. Diagnosed in early childhood with a complete AVCD, pulmonary stenosis, and right ventricular (RV) hypoplasia, the patient underwent palliative surgical intervention with a modified Blalock–Taussig shunt at the age of 10 but did not receive subsequent regular follow-up. Over the ensuing 35 years, she remained largely untreated until presentation at 45 years of age with progressive exertional dyspnea, central cyanosis, and palpitations, corresponding to NYHA class III. Comprehensive multimodal imaging, including transthoracic echocardiography and cardiac magnetic resonance, revealed a complete AVCD with moderate-to-severe mitral regurgitation secondary to an anterior mitral leaflet cleft, severe tricuspid regurgitation, RV hypoplasia, and hallmark features of EA. Given the complex cardiac anatomy and the elevated surgical risk, the patient was considered inoperable, and a strategy of conservative management with multidisciplinary follow-up was implemented. Conclusions. This case highlights the exceptional longevity of a patient with the rare coexistence of complete AVCD, EA, and RV hypoplasia, surviving 45 years from diagnosis despite limited early intervention. It underscores the importance of lifelong follow-up in complex congenital heart disease and illustrates the role of multimodal imaging in assessing anatomy and guiding management when surgical options are high-risk or not feasible. Full article

During open mitosis, reassembly of the nuclear envelope requires the coordinated recruitment of the ESCRT machinery, initiated by the chromatin-associated factor BAF1 and the nuclear-envelope-associated factor LEM2. Because telomeres are enriched at the reforming envelope, we investigated whether ESCRT factors contribute to telomere integrity. Reduction in the pivotal nuclear ESCRT factor CHMP7 caused DNA damage, heterochromatin disorganization, and telomere defects, including sister telomere associations and telomere free ends. Extending this analysis, we found that additional ESCRT components, including TSG101, VPS28, CHMP4B, and the ESCRT-associated factor AKTIP/Ft1, also contribute to telomere integrity, although with different strengths. Genetic interaction analyses suggest that CHMP7 converges in a common pathway with CHMP4B and AKTIP/Ft1, while it functions in parallel routes to TNKS1, a telomere-specific regulator of the shelterin TRF1. More genetic analyses indicated that BAF1 and LEM2 contribute to safeguarding of telomeres during nuclear envelope reassembly. Because defects in nuclear envelope dynamics and chromatin–membrane coupling are hallmarks of disorders associated with nuclear deformation and fragility, including aging and cancer, our findings contribute a new angle into these conditions and suggest potential targets for selectively modulating telomere maintenance pathways. Full article

Deregulated Nlrp3 (NOD-like receptor pyrin 3) inflammasome activation is strongly associated with age-related blinding diseases, including cataract. Previously, we demonstrated that loss of peroxiredoxin6 (Prdx6) promotes reactive oxygen species (ROS) amplification and aberrant activation of Klf9 and Nlrp3 inflammasome activity–driven pyroptosis. In this study, using aging mouse(m)/human(h) lenses and lens epithelial cells (LECs), we reveal a critical link between Nlrp3 and thioredoxin (TRX)-interacting protein (TXNIP), which increases during aging and oxidative stress conditions. We found that aging lenses exhibiting opacity showed elevated ROS levels, increased TXNIP expression, along with upregulation of Nlrp3 inflammasome components, including caspase-1, ASC, IL-1β, IL-18, and gasderminD (GSDMD), with significantly reduced TRX1. mLECs overexpressing TXNIP were more susceptible to hydrogen peroxide (H₂O₂), Lipopolysaccharide (LPS), ultraviolet B (UVB)-induced oxidative stress, displaying increased ROS accumulation, reduced cell viability, and enhanced activation of Nlrp3 inflammasome and its downstream inflammatory mediators, hallmarks of pyroptotic cell death. Conversely, TXNIP knockdown suppressed Nlrp3 inflammasome activation, decreased ROS production, and significantly improved cell survival, indicating a protective effect against oxidative injury. Ex vivo, TAT-HA-Prdx6 delivery inhibited H₂O₂-induced Nlrp3 activation and preserved lens transparency, demonstrating its potent antioxidant and anti-inflammatory effects. Collectively, these findings identify TXNIP as a key regulator of Nlrp3 inflammasome signaling and thereby highlight the therapeutic potential of TXNIP silencing (ShTXNIP) or TAT-HA-Prdx6 delivery to halt Nlrp3-mediated pyroptosis during aging or oxidative stress conditions. Full article

Plant-based extracts are rich sources of phenolic compounds, which may act as skin antiaging mediators. Herein, Cistus albidus L. (Ca), Cistus ladanifer L. subsp. ladanifer (Cl) and Cistus salviifolius L. (Cs) were selected to test whether their phytochemical profile and bioactive potential align to target human skin aging. Hydroethanolic extracts (HEs) were prepared and characterized using infrared vibrational spectroscopy (FTIR-ATR) and liquid chromatography–mass spectrometry (LC-MS). Non-toxic concentrations were screened, and cytoprotective and antioxidant effects were studied in tert-butyl hydroperoxide-stimulated normal human dermal fibroblasts (NHDFs). Lipopolysaccharide-stimulated RAW 264.7 macrophages were used to assess anti-inflammatory activity, the Organization for Economic Co-operation and Development (OECD) Test Guideline No. 439 was used to assess irritant effects, and the anti-senescence potential was assessed in etoposide-stimulated NHDFs. A series of enzymatic inhibition assays was performed. All extracts comprised ellagic acid derivatives, as well as myricetin and quercetin derivatives in Cs and Ca. The HE of Cs was also markedly composed of ligstroside. At non-toxic concentrations, cytoprotective effects were observed in NHDFs. However, only Cs and Cl exhibited significant antioxidant activity in these cells (p < 0.001 and p < 0.0001, respectively). In addition to that, Cl demonstrated highly significant anti-inflammatory (p < 0.0001) and anti-senescence (p < 0.0001) effects. Cs and Cl showed a remarkable potential to inhibit elastase; in addition, Cs also showed anti-hyaluronidase and anti-tyrosinase activities. Meaningfully, Cs and Cl extracts did not exhibit skin irritant effects. The unveiled potential of Cl in skin aging offset highlights the need to elucidate the detailed mechanisms of action, paving the way for the development of skin anti-aging formulations. Full article

Age-related thymic atrophy, a hallmark of immunosenescence linked to age-related diseases, involves gonadal and adrenal steroid hormones, but their distinct roles and mechanisms in this process remain unclear. Through biochemical, histological, and RNA-seq analyses, we comprehensively explored the mechanisms underpinning age-related thymic atrophy in response to ovariectomy (OVX) versus adrenalectomy (ADX) in female mice. Compared to the sham controls, OVX overtly ameliorated age-related thymic atrophy, as evidenced by increased thymus mass, a larger gross thymus area, and denser cortex cellularity. In contrast, ADX evidently accelerated age-related thymic atrophy, characterized by increased adipose infiltration and decreased cortex/medulla ratio, obscure cortico-medullary junctions, and sparser thymic cortical cells. Unexpectedly, combined OVX and ADX displayed a more pronounced effect than OVX alone in ameliorating age-related thymic atrophy. Mechanistically, OVX decreased while ADX increased the circulating 17β-estradiol levels in female mice, which drove these opposing outcomes potentially by promoting Pparg-mediated thymic fat deposition and blocking Cdk1-dependent thymocyte cell cycle progression. Although OVX eliminated gonadal 17β-estradiol production, it appeared to trigger a compensatory adrenal-dependent estrogen biosynthesis, whereas combined OVX and ADX nearly eliminated all estrogen sources, thus leading to a more pronounced effect than OVX alone in ameliorating age-related thymic atrophy in female mice. Notably, OVX increased while ADX decreased serum corticosterone levels, but these alterations exerted minimal impacts on age-related thymic atrophy, highlighting a pivotal role of estrogens over glucocorticoids in accelerating age-related thymic atrophy in females. Undesirably, although OVX ameliorated age-related thymic atrophy, it appeared to simultaneously increase autoimmune susceptibility by downregulating thymic Cd74 expression. Taken together, our results indicate that OVX ameliorates while ADX accelerates age-related thymic atrophy in females. Estrogens rather than glucocorticoids act as the predominant regulator of this process, potentially via promoting Pparg-dependent fat deposition and blocking Cdk1-dependent thymocyte cycle progression. However, OVX-induced estrogen depletion also elevated autoimmune risk, emphasizing the need to balance benefits and risks in regulating thymic aging. Full article

Parkinson’s disease is the second leading neurodegenerative disease of aging. For over five decades, oral levodopa has been used to manage the progressive motor deficits that are the hallmark of the disease. However, individual dose requirements are highly variable, and patients typically require increased levodopa dosage as the disease progresses, which can cause undesirable side effects. It has become increasingly apparent that the gut microbiome can have a major impact on the metabolism and efficacy of therapeutic drugs. In this Perspective, we examine recent studies highlighting the impact of metabolism by Enterococcus faecalis, a common commensal gut bacterium, on levodopa bioavailability. E. faecalis expresses a highly conserved tyrosine decarboxylase that promiscuously converts levodopa to dopamine in the gut, resulting in decreased neuronal uptake of levodopa and reduced dopamine formation in the brain. Mitochondria-targeted antioxidants conjugated to a triphenylphosphonium moiety have shown promise in transiently suppressing the growth of E. faecalis and decreasing microbial levodopa metabolism, providing an approach to modulating the microbiome that is less perturbing than conventional antibiotics. Thus, mitigating metabolism by the gut microbiota is an attractive therapeutic target to preserve and potentiate the efficacy of oral levodopa therapy in Parkinson’s disease. Full article

Most clinical cancer therapy trials do not specifically consider the effect of patient age on treatment outcomes, and many even exclude older individuals. This is despite the fact that solid cancers are age-associated diseases and that there are many shared hallmarks between biological ageing and cancer. Thus, there is an increasing awareness of the serious gaps remaining in our knowledge of how older adults respond to cancer treatments, particularly immunotherapies. Emerging evidence suggests that it is not only the physiological and immunological changes associated with chronological ageing that impacts cancer treatment, but also those heterogeneous differences that impact treatment outcomes, such as frailty, comorbidities, and more generally, biological ageing. Importantly, it remains unclear which of these factors are negative or positive contributors, as has been illuminated by recent evidence pertaining to the incidence and severity of immune-related adverse events and survival. Much of our information on older patients in this context is essentially anecdotal, mostly deriving from the treatment of older adults in real-world practice or clinical trials that happened to include some older patients. Given the lack of comprehensive articles on the heterogeneity of ageing as a core determinant of cancer treatment outcomes, we briefly consider the state of the art of cancer research and treatment in the older patient, with an emphasis on immunotherapy and geriatric oncology. Full article

Several animal models of Alzheimer’s disease have been developed and tested for diagnostic and treatment purposes. [¹¹C]PIB is the gold-standard radiotracer for the detection of Aβ plaque deposits, a hallmark of the disease. This study aimed to evaluate the in vivo detection of Aβ plaques using [¹¹C]PIB microPET imaging across different animal models of Alzheimer’s disease. The study included 3xTg-AD transgenic mice, TgF344-AD transgenic rats and Aβ injection-based rat model. The results showed an age-related increase in [¹¹C]PIB uptake in 3xTg-AD mice, particularly in the midbrain and thalamus. In TgF344-AD rats, differences were also observed compared to WT controls, with the highest values observed in the hippocampus and cortex. In the injection-based model, inoculated rats showed greater uptake in the injection site than SHAM animals. Across all microPET studies, [¹¹C]PIB uptake was consistently higher in females than in their male counterparts. These findings support the value of transgenic and Aβ injection-based models in preclinical research on Aβ plaque deposition and highlight the importance of considering species, model type, sex, and age in experimental design. Full article

Background: Ovarian cancer remains the deadliest gynecologic malignancy, with its progression closely tied to age-associated remodeling of the tumor immune microenvironment. The laying hen serves as a valuable spontaneous model for human ovarian cancer. Its single-cell analyses may provide valuable insights into the immune-related axis linking ovarian aging to carcinogenesis. Methods: This study applied single-cell RNA sequencing to profile ovaries from three laying hen groups, including 35-week-old normal ovaries (A35w), 110-week-old normal ovaries (B110w), and 110-week-old ovarian cancer tissues (C110w). Key analyses had UCell-based scoring of senescence-related pathways and cancer hallmarks, differential expression analysis for overlapping dysregulated genes, LASSO regression-based prognostic model construction, and assessment of chemotherapy sensitivity and immune infiltration. Results: A comprehensive cellular landscape of chicken ovaries was established, identifying major immune populations including B cells, CD4+ T cells, CD8+ T cells, macrophages, and plasma cells. Senescence-related pathways and cancer hallmarks showed progressive activation in immune cells from A35w to B110w to C110w. A total of 216 genes commonly dysregulated in aging and carcinogenesis, reveal core links between immune dysfunction and malignant transformation. The 20-gene prognostic model derived from these genes stratified human ovarian cancer patients into high-risk and low-risk groups with significant overall survival differences, exhibited robust predictive performance across TCGA, GSE32063, and GSE140082. The model also predicted the differential chemotherapy sensitivity in high-risk and low-risk patients and correlated with specific immune infiltration patterns in the tumor microenvironment. Conclusions: Notably, this is the first single-cell RNA sequencing study of chicken ovarian cancer, and we constructed the 20-gene prognostic model for human ovarian cancer using 216 genes that change significantly in immune cells during both ovarian aging and carcinogenesis. This work provides support to establish the hen as a potential preclinical animal model and a translational tool to guide personalized therapy. Full article

Parkinson’s disease (PD) is a neurodegenerative disorder characterized by age-dependent degeneration of dopaminergic neurons in the substantia nigra, a process mediated by α-synuclein aggregation, mitochondrial dysfunction, and impaired proteostasis. While BAP31—an endoplasmic reticulum protein critical for protein trafficking and degradation—has been implicated in neuronal processes, its role in PD pathogenesis remains poorly understood. To investigate the impact of BAP31 deficiency on PD progression, we generated dopamine neuron-specific BAP31 conditional knockout with DAT-Cre (cKO) mice (Slc6a3cre-BAP31^fl/fl) and subjected them to MPTP-lesioned Parkinsonian models. Compared to BAP31^fl/fl controls, Slc6a3cre-BAP31^fl/fl mice exhibited exacerbated motor deficits following MPTP treatment, including impaired rotarod performance, reduced balance beam traversal time, and diminished climbing and voluntary motor capacity abilities. BAP31 conditional deletion showed no baseline phenotype, with deficits emerging only after MPTP. Our results indicate that these behavioral impairments correlated with neuropathological hallmarks: decreased NeuN neuronal counts, elevated GFAP astrogliosis, reduced tyrosine hydroxylase levels in the substantia nigra, and aggravated dopaminergic neurodegeneration. Mechanistically, BAP31 deficiency disrupted mitochondrial homeostasis by suppressing the PINK1–Parkin mitophagy pathway. Further analysis revealed that BAP31 regulates PINK1 transcription via the transcription factor Engrailed Homeobox 1. Collectively, our findings identify BAP31 as a neuroprotective modulator that mitigates PD-associated motor dysfunction by preserving mitochondrial stability, underscoring its therapeutic potential as a target for neurodegenerative disorders. Full article