Search Results (285)

Mitochondria play a central role in energy metabolism, redox homeostasis, and signal transduction in the thyroid cells. Increasing evidence indicates that mitochondrial DNA (mtDNA) mutations, copy number variations, and haplogroup-specific polymorphisms are closely associated with metabolic reprogramming and malignant progression of thyroid cancer. This review summarizes recent advances in the understanding of the impact of mitochondrial genome instability and metabolic plasticity on thyroid tumorigenesis. We discuss how mtDNA alterations disrupt oxidative phosphorylation (OXPHOS), trigger adaptive metabolic rewiring, and interact with key oncogenic pathways, such as HIF-1α, BRAFV600E mutations, and TSHR signaling in thyroid cancer. We also highlight the emerging diagnostic and therapeutic potential of mtDNA in thyroid cancer and outline current challenges and future research directions. Gaining deeper insights into the mitochondria–metabolism axis may provide novel biomarkers and metabolic intervention strategies for precision medicine in thyroid oncology. Full article

Cognitive impairments, particularly in the context of neurodegenerative diseases, are associated with disruptions in mitochondrial function and key metabolic pathways. This study investigates the impact of short-term scopolamine exposure on mitochondrial DNA (mtDNA) stability and the kynurenine pathway (KP) in the hippocampus, a brain region central to learning and memory. We analyzed the mitochondrial D-loop region for mutations and heteroplasmy levels in hippocampal tissue from rats exposed to scopolamine (1 mg/kg/0.4 mL/cc i.p. x 14 days). Additionally, the expression of the KP enzymes kynurenine aminotransferase (KAT I, KAT II) and kynurenine 3-monooxygenase (KMO) and receptors aryl hydrocarbon receptor (Ahr) and G protein-coupled receptor 35 (GPR35) was evaluated using quantitative PCR. Neither significant mutation nor heteroplasmy changes were observed in the mtDNA D-loop region between the scopolamine-treated and control groups. Similarly, the hippocampal expression levels of the kat I, kat II, kmo and ahr and gpr35 genes remained unchanged, indicating no activation of this metabolic pathway under short-term scopolamine exposure. These findings suggest that the mitochondrial genome in the hippocampus remains stable under acute pharmacological stress induced by scopolamine, with no significant activation of the KP. These results underline the distinction between transient, reversible cognitive deficits and chronic neurodegenerative processes, providing insights for therapeutic approaches targeting specific stages of cognitive change. Full article

Cardiovascular diseases hinge on a vicious, self-amplifying cycle in which mitochondrial deoxyribonucleic acid (mtDNA) dysfunction undermines cardiac bioenergetics and unleashes sterile inflammation. The heart’s reliance on oxidative phosphorylation (OXPHOS) makes it exquisitely sensitive to mtDNA insults—mutations, oxidative lesions, copy-number shifts, or aberrant methylation—that impair ATP production, elevate reactive oxygen species (ROS), and further damage the mitochondrial genome. Damaged mtDNA fragments then escape into the cytosol, where they aberrantly engage cGAS–STING, TLR9, and NLRP3 pathways, driving cytokine storms, pyroptosis, and tissue injury. We propose that this cycle represents an almost unifying pathogenic mechanism in a spectrum of mtDNA-driven cardiovascular disorders. In this review, we aim to synthesize the pathophysiological roles of mtDNA in this cycle and its implications for cardiovascular diseases. Furthermore, we seek to evaluate preclinical and clinical strategies aimed at interrupting this cycle—bolstering mtDNA repair and copy-number maintenance, reversing pathogenic methylation, and blocking mtDNA-triggered innate immune activation—and discuss critical gaps that must be bridged to translate these approaches into precision mitochondrial genome medicine for cardiovascular disease. Full article

Background: The TWNK gene encodes a protein that colocalizes with mitochondrial DNA (mtDNA) in mitochondrial nucleoids. It acts as mtDNA helicase during replication, thus playing a pivotal role in the replication and maintenance of mtDNA stability. TWNK mutations are associated with a wide spectrum of clinical phenotypes and a marked heterogeneity. However, heterozygous nonsense variants in the gene have never been described in association with disease. Methods: We analyzed a next-generation sequencing (NGS) targeted gene panel in a cohort including 40 patients with high clinical suspicion of mitochondrial disorders. Selected patients underwent a complete neurological examination, electrophysiology tests, and muscle biopsy. Segregation analysis was performed in available family members. The 3D structure of twinkle was visualized and analyzed using Swiss Model and Pymol version 3.1.6.1. Results: We found four TWNK-mutated subjects from two unrelated families. They exhibited a variable clinical spectrum, ranging from asymptomatic individuals to subjects with psychiatric disorder, chronic progressive external ophthalmoplegia (CPEO), and CPEO-plus. All the subjects shared the heterozygous TWNK p.Glu665Ter variant. Discussion and Conclusions: We describe the clinical phenotype and muscle biopsy findings associated with the first reported heterozygous nonsense TWNK variant, thus expanding the current knowledge of Twinkle-related disorders. Our findings are in line with the high intrafamilial clinical variability associated with TWNK mutations. Although PEO and skeletal muscle involvement remain hallmarks of the disease, extra-muscular features should be carefully assessed. Full article

Mitochondria perform critical roles in cellular functions, particularly in metabolism and cell death regulation. Mutations in nuclear and mitochondrial genes can cause mitochondrial dysfunction, leading to classical mitochondrial diseases. Emerging evidence suggests that mitochondrial adaptations in cancer support the high energy demands of proliferating cells and contribute to tumor progression through anti-apoptotic mechanisms, dysregulated mitochondrial quality control (mtQC), and altered mitochondrial DNA (mtDNA) copy numbers. Interestingly, several mitochondrial pathways involved in cancer progression resemble those implicated in mitochondrial diseases. From this perspective, although cancer is not a classical mitochondrial disease, its progression involves mitochondria-associated pathways similar to those in mitochondrial disorders, suggesting that cancer may be considered a mitochondria-related disease in a broader sense. Understanding these shared mechanisms could provide new insights into precision treatment strategies. Furthermore, mitochondrial dysfunction is increasingly recognized in precancerous conditions, suggesting its potential as a target for early intervention. Oral potentially malignant disorders (OPMDs) serve as a valuable model for studying these mitochondria-associated mechanisms, offering a promising avenue for both therapeutic advancements and preventive approaches. Full article

Alterations in the mitochondrial genome (mtDNA) have been shown to be key in cancer development and could be useful as biomarkers for diagnosis, prognosis, and treatment. To identify mtDNA variants associated with breast cancer, we analyzed the whole mtDNA sequence from paired tissues (tumor–peripheral blood) of women with this malignancy and from peripheral blood samples of healthy women. The mtDNA mutational landscape, heteroplasmy levels of the variants, and mitochondrial ancestry were established. Comparative analysis between cases and controls revealed significant differences in the number and location of variants, as well as in the heteroplasmy levels. Cases showed higher mutation number in MT-ND5, tRNAs, and rRNAs genes; increased proportion of missense variants; and elevated mtDNA content, than controls. Notably, a high blood mtDNA mutational burden (OR = 3.83, CI: 1.89–7.95, p = 5.3 × 10⁻⁵) and five mtDNA variants showed association with the risk of breast cancer. Furthermore, a low tumor mutational burden (HR = 7.82, CI: 1.0–63.6, p = 0.05) and the haplogroup L (HR = 12.16, CI: 2.0–72.8, p = 0.0062) were associated with decreased overall and disease-free survival, respectively. Our study adds evidence of the potential usefulness of mtDNA variants as risk and prognosis biomarkers for breast cancer. Full article

Mitochondrial aging plays a central role in the functional decline of the central nervous system (CNS), with profound consequences for neurological health. As the brain is one of the most energy-demanding organs, neurons are particularly susceptible to mitochondrial dysfunction that arises with aging. Key features of mitochondrial aging include impaired mitochondrial dynamics, reduced mitophagy, increased production of reactive oxygen species (ROS), and accumulation of mitochondrial DNA (mtDNA) mutations. These alterations dramatically compromise neuronal bioenergetics, disrupt synaptic integrity, and promote oxidative stress and neuroinflammation, paving the path for the development of neurodegenerative diseases. This review also examines the complex mechanisms driving mitochondrial aging in the central nervous system (CNS), including the disruption of mitochondrial-organelle communication, and explores how mitochondrial dysfunction contributes to neurodegenerative diseases, such as Alzheimer’s, Parkinson’s, Huntington’s, and amyotrophic lateral sclerosis. By synthesizing current evidence and identifying key knowledge gaps, we emphasize the urgent need for targeted strategies to restore mitochondrial function, maintain cognitive health, and delay or prevent age-related neurodegeneration. Full article

Background: Leber’s hereditary optic neuropathy (LHON) is the most common mitochondrial disorder and an inherited optic neuropathy. Recently, two different LHON inheritance types have been discovered: mitochondrially inherited LHON (mtLHON) and autosomal recessive LHON (arLHON). Our case report is the first diagnosed case of arLHON in a patient of Lithuanian descent and confirms the DnaJ Heat Shock Protein Family (Hsp40) Member C30 (DNAJC30) c.152A>G p.(Tyr51Cys) founder variant. Case Presentation: A 34-year-old Lithuanian man complained of headache and sudden, painless loss of central vision in his right eye. On examination, the visual acuity of the right and left eyes was 0.1 and 1.0, respectively. Visual-field examination revealed a central scotoma in the right eye, and visual evoked potentials (VEPs) showed prolonged latency in both eyes. Optical coherence tomography showed thickening of the retinal nerve fiber layer in the upper quadrant of the optic disk in the left eye. Magnetic resonance imaging of the head showed evidence of optic nerve inflammation in the right eye. Blood tests were within normal range and showed no signs of inflammation. Retrobulbar neuritis of the right eye was suspected, and the patient was treated with steroids, which did not improve visual acuity. He later developed visual loss in the left eye as well. A genetic origin of the optic neuropathy was suspected, and a complete mitochondrial DNA analysis was performed, but it did not reveal any pathologic mutations. Over time, the visual acuity of both eyes slowly deteriorated, and the retinal nerve fiber layer (RNFL) thinning of the optic disks progressed. A multidisciplinary team of specialists concluded that vasculitis or infectious disease was unlikely to be the cause of the vision loss, and a genetic cause for the disease was still suspected, although a first-stage genetic test did not yield the diagnosis. Thirty-three months after disease onset, whole-exome sequencing revealed a pathogenic variant in the DNAJC30 gene, leading to the diagnosis of arLHON. Treatment with Idebenone was started 35 months after the onset of the disease, resulting in no significant worsening of the patient’s condition. Conclusion: This case highlights the importance of considering arLHON as a possible diagnosis for patients with optic neuropathy, because the phenotype of arLHON appears to be identical to that of mtLHON and cannot be distinguished by clinicians. Full article

Human mitochondrial DNA (mtDNA) is a relevant marker in evolutionary and population genetics, including ancient DNA (aDNA) research, due to inherent characteristics. However, aDNA is prone to damage and sequencing artefacts, potentially confounding evolutionary interpretations. To assess evolutionary patterns in ancient and modern mtDNA, we built a phylogeny comprising 63,965 modern and 3757 ancient public mitogenomes, classified mutations by genomic region and functional effect, and analysed distribution, frequency, and predicted pathogenicity of private and pre-terminal mutations, investigating purifying selection. We compared mutation class ratios (non-synonymous, rRNA, tRNA, nonsense vs. synonymous) across ancient and modern terminal branches and pre-terminal nodes. The predicted pathogenicity of non-synonymous mutations was evaluated across major European haplogroups using three tools. Ancient variants exhibited higher ratios of potentially deleterious mutations and significantly elevated pathogenicity scores compared to modern and pre-terminal branches, highlighting a mutation load likely inflated by damage-related artefacts. Remarkably, nonsense mutations—largely incompatible with life—were over 70 times more frequent in aDNA. The correlation between mutation ratios and predicted deleteriousness across haplogroups suggests a pattern incompatible with biological persistence or relaxed selection alone. These findings highlight the importance of rigorous quality control for ancient data in evolutionary inference, molecular clock calibration, and pathogenic variant identification. Full article

Renal oncocytoma (RO) is a benign renal neoplasm characterized by dense accumulation of dysfunctional mitochondria possibly resulting from increased mitochondrial biogenesis and decreased mitophagy; however, the mechanisms controlling these mitochondrial changes are unclear. ROs harbor recurrent inactivating mutations in mitochondrial genes encoding the Electron Transport Chain (ETC) Complex I, and we hypothesize that Complex I loss in ROs directly impairs mitophagy. Our analysis of ROs and normal kidney (NK) tissues shows that a significant portion (8 out of 17) of ROs have mtDNA Complex I loss-of-function mutations with high variant allele frequency (>50%). ROs indeed exhibit reduced Complex I expression and activity. Analysis of the various steps of mitophagy pathway demonstrates that AMPK activation in ROs leads to induction of mitochondrial biogenesis, autophagy, and formation of autophagosomes. However, the subsequent steps involving lysosome biogenesis and function are defective, resulting in an overall inhibition of mitophagy. Inhibiting Complex I in a normal kidney cell line recapitulated the observed lysosomal and mitophagy defects. Our data suggest Complex I loss in RO results in defective mitophagy due to lysosomal loss and dysfunction. Full article

Chemotherapy remains a cornerstone in the treatment of esophageal cancer (EC), yet chemoresistance remains a critical challenge, leading to poor outcomes and limited therapeutic success. Mitochondrial DNA (mtDNA) has emerged as a pivotal player in mediating these responses, influencing cellular metabolism, oxidative stress regulation, and apoptotic pathways. This review provides a comprehensive overview of the mechanisms by which mtDNA alterations, including mutations and copy number variations, drive chemoresistance in EC. Specific focus is given to the role of mtDNA in metabolic reprogramming, including its contribution to the Warburg effect and lipid metabolism, as well as its impact on epithelial–mesenchymal transition (EMT) and mitochondrial bioenergetics. Recent advances in targeting mitochondrial pathways through novel therapeutic agents, such as metformin and mitoquinone, and innovative approaches like CRISPR/Cas9 gene editing, are also discussed. These interventions highlight the potential for overcoming chemoresistance and improving patient outcomes. By integrating mitochondrial diagnostics with personalized treatment strategies, we propose a roadmap for future research that bridges basic mitochondrial biology with translational applications in oncology. The insights offered in this review emphasize the critical need for continued exploration of mtDNA-targeted therapies to address the unmet needs in EC management and other diseases associated with mitochondria. Full article

Background/Objectives: The gene pool of the Apennine wolf is affected by admixture with domestic variants due to anthropogenic hybridisation with dogs. Genetic monitoring at the population level involves assessing the extent of admixture in single individuals, ranging from pure wolves to recent hybrids or wolf backcrosses, through the analysis of nuclear and mitochondrial DNA (mtDNA) markers. Although individually non-diagnostic, mtDNA is nevertheless essential for completing the final diagnosis of genetic admixture. Typically, the identification of wolf mtDNA haplotypes is carried out via sequencing of coding genes and non-coding DNA stretches. Our objective was to develop a fast real-time PCR assay to detect the mtDNA haplotypes that occur exclusively in the Apennine wolf population, as a valuable alternative to the demanding sequence-based typing. Methods: We validated a qualitative duplex real-time PCR that exploits the combined presence of diagnostic point mutations in two mtDNA segments, the NDH-4 gene and the control region, and is performed in a single-tube step through TaqMan-MGB chemistry. The aim was to detect mtDNA multi-fragment haplotypes that are exclusive to the Apennine wolf, bypassing sequencing. Results: Basic validation of 149 field samples, consisting of pure Apennine wolves, dogs, wolf × dog hybrids, and Dinaric wolves, showed that the assay is highly specific and sensitive, with genomic DNA amounts as low as 10⁻⁵ ng still producing positive results. It also proved high repeatability and reproducibility, thereby enabling reliable high-throughput testing. Conclusions: The results indicate that the assay presented here provides a valuable alternative method to the time- and cost-consuming sequencing procedure to reliably diagnose the maternal lineage of the still-threatened Apennine wolf, and it covers a wide range of applications, from scientific research to conservation, diagnostics, and forensics. Full article

The aim of this paper is to present our experience with the diagnosis and management of nine patients diagnosed with Leber’s hereditay optic neuropathy. Materials and methods: We conducted a prospective, observational study that included nine patients treated with idebenone, followed for a period of 18 months. Results: Our findings suggest that the impact of treatment varies significantly depending on the disease phase. In the acute phase, visual acuity deteriorated from 0.67 logMAR at onset to 0.97 logMAR at 3 months, followed by a slight improvement to 0.88 logMAR at 9 months. In the chronic phase, average values decreased progressively from 1.44 logMAR at onset to 1.26 logMAR at 12 and 18 months. We also observed a consistent treatment benefit over time in eyes harbouring the m.11778 G > A mutation. Although the most powerful predictor of visual outcome remains the mtDNA genotype, young age at onset is correlated with a better prognosis. In the acute phase, more cases of a clinically relevant benefit were observed than expected (33.33% versus 22.22% expected), and fewer clinically relevant worsening cases were observed (0% versus 11.11% expected). Regarding OCT measurement, our study highlighted a significant difference in peripapillary retinal nerve fiber layer thickness between the initial evaluation and the 6-month follow-up (100.83 µm ± 30.2 at baseline versus 96.7 µm ± 24.8 at 6 months). Conclusions: Our paper demonstrates the benefit of idebenone treatment in improving visual acuity in patients with Leber hereditary optic neuropathy. We highlighted the importance of long-term treatment, emphasizing that extended administration is key to achieving favorable outcomes. Full article

Purpose: Neuroendocrine carcinomas (NECs) are aggressive tumors treated with cisplatin-based chemotherapy, though responses vary. As DNA damage response (DDR) pathways influence cisplatin sensitivity, this single-center retrospective study evaluates the efficacy of first-line cisplatin in recurrent or metastatic NEC based on DDR mutation status. Materials and Methods: This study analyzed patients with grade 3 recurrent or metastatic NEC treated with first-line etoposide plus cisplatin at Samsung Medical Center between January 2019 and September 2023. All patients underwent next-generation sequencing to determine DDR mutation status, defined by pathogenic alterations in major DNA repair pathways. Clinical outcomes were assessed per RECIST v1.1. Survival analyses were conducted using Kaplan–Meier methods and Cox regression models, with significance set at p ≤ 0.05. Results: A total of 40 patients with NEC were included in this study. There were 16 patients with DDR wild-type (WT) and 24 patients with DDR mutant type (MT). The most common primary tumor sites were the pancreas (25.0%), stomach (20.0%), and gallbladder/duct (12.5%). Among 40 patients, those with DDR mutations (n = 24) showed significantly higher objective response (58.3% vs. 12.5%) and disease control rates (91.7% vs. 50.0%) compared to patients with DDR WT (n = 16). The median progression-free survival (PFS) showed the favorable trend in the DDR mutant group (8.0 vs. 4.3 months; p = 0.15), with similar trends observed across homologous recombination repair (HRR), Fanconi anemia (FA), and mismatch repair (MMR) subgroups. Conclusions: This study revealed that patients with DDR mutations had significantly higher response to first-line etoposide–cisplatin, suggesting DDR mutation status as a potential predictive marker to guide treatment and improve outcomes in recurrent or metastatic NEC. Full article

The mitochondrial regulator MNRR1 is reduced in several pathologies, including the mitochondrial heteroplasmic disease MELAS, and genetic restoration of its level normalizes the pathological phenotype. Here, we investigate the upstream mechanism that reduces MNRR1 levels. We have identified the hypoxic regulator HIF2α to bind the MNRR1 promoter and inhibit transcription by competing with RBPJκ. In MELAS cells, there is a pseudohypoxic state that transcriptionally induces HIF2α and stabilizes HIF2α protein. MELAS cybrids harboring the m.3243A > G mutation display reduced levels of prolyl hydroxylase 3 (PHD3), which contributes to the HIF2α stabilization. These results prompted a search for compounds that could increase MNRR1 levels pharmacologically. The screening of a 2400-compound library uncovered the antifungal drug nitazoxanide and its metabolite tizoxanide as enhancers of MNRR1 transcription. We show that treating MELAS cybrids with tizoxanide restores cellular respiration, enhances mitophagy, and, importantly, shifts heteroplasmy toward wild-type mtDNA. Furthermore, in fibroblasts from MELAS patients, the compound improves mitochondrial biogenesis, enhances autophagy, and protects from LPS-induced inflammation. Mechanistically, nitazoxanide reduces HIF2α levels by increasing PHD3. Chemical activation of MNRR1 is thus a potential strategy to improve mitochondrial deficits seen in MELAS. Finally, our data suggests a broader physiological pathway wherein two proteins, induced under severe (1% O2; HIF2α) and moderate (4% O2; MNRR1) hypoxic conditions, regulate each other inversely. Full article