bims-ripira Biomed News
on RRM2B MDMD in Adults
Issue of 2026–03–15
seven papers selected by
Martín Lopo
  1. First case of schizophrenia and OCD in TK2-related mitochondrial DNA depletion myopathy: a case report.
  2. Clinical Heterogeneity and Candidate Biomarkers in POLG-Related Mitochondrial Disease.
  3. Beyond muscle weakness: pathogenesis of sepsis-induced myopathy and its management.
  4. New Insights into the Anti-Aging Mechanism of Collagen Peptides-Emphasis on Lysosomes and Mitochondria Function.
  5. DNA Polymerase Gamma Acetylation Governs Mitochondrial Homeostasis and Vascular Cell Senescence.
  6. Targeting mitochondrial metabolism with combined metabolic activators.
  7. Mitochondrial quality in aging and neurodegeneration: The emerging role of mitochondria-derived vesicles.
  1. BMC Psychiatry. 2026 Mar 10.
    First case of schizophrenia and OCD in TK2-related mitochondrial DNA depletion myopathy: a case report.
    Shu Hui Ngoh, Alakananda Gudi.
      
    Keywords:  Case report; Neuropsychiatry; Obsessive-compulsive; Psychopharmacology; Schizophrenia; TK2-related mitochondrial DNA depletion myopathy
    DOI:  https://doi.org/10.1186/s12888-026-07905-5
  2. Neurol Genet. 2026 Apr;12(2): e200365
    Clinical Heterogeneity and Candidate Biomarkers in POLG-Related Mitochondrial Disease.
    Laura Bermejo-Guerrero, Juan Luis Restrepo-Vera, Paloma Martin-Jimenez, Maria Navarro-Riquelme, Rocío Garrido-Moraga, Luz Edith Ochoa, Adrián González-Quintana, Aurelio Hernandez-Lain, Jessica Castillo-Villalba, Germán Morís, Nuria Muelas, Elena García-Arumí, Victoria González, Elena Martínez-Sáez, Ana Vesperinas, Laura Llansó, Raul Juntas-Morales, Carmen Paradas, Solange Kapetanovic, Alberto Blázquez, Ramon Martí, Joaquín Arenas, Miguel A Martín, Cristina Domínguez-González.
       Background and Objectives: POLG-related disorders exhibit marked phenotypic heterogeneity and frequent clinical overlap, often leading to delayed diagnosis. A precise delineation of their clinical spectrum, natural history, and the identification of reliable biomarkers is essential to improve diagnostic accuracy and guide therapeutic development.
    Methods: We analyzed a cohort of 34 patients with confirmed pathogenic POLG variants, assessing clinical phenotypes, molecular findings, and biomarkers (plasma growth differentiation factor-15 [GDF15] in 16, plasma neurofilament light chain [NF-L] in 14, and mitochondrial DNA [mtDNA] copy number in muscle in 16).
    Results: Thirty four patients (0.6-71 years) from 33 families were included. Juvenile/adult onset (12-40 years) was the most common presentation (62%). The predominant phenotypic categories were ataxia-neuropathy spectrum ([ANS], 44%), autosomal recessive PEO-plus (arPEO-plus, 26%), and autosomal dominant PEO-plus ([adPEO-plus], 15%), with frequent phenotypic overlap. Recessive inheritance accounted for 74% of cases, with the most common variants being p.([Thr251Ile; Pro587Leu]) paired on 1 allele, p.(Ala467Thr), and p.(Trp748Ser). Dominant variants were associated with milder, primarily myopathic phenotypes. The most common dominant variant was p.(Tyr955Cys). No clear genotype-phenotype correlations were identified among recessive variants. Compared with previously reported cohorts, our patients exhibited a lower prevalence of seizures, hepatopathy, and stroke-like episodes. GDF15 was elevated in 87.5% of patients, with a mean level of 3,315 pg/mL (±1,559.79), showing no significant differences between myopathic and ANS phenotypes, supporting its role as a general biomarker of mitochondrial dysfunction. NF-L was elevated in 78.6% of tested individuals but did not correlate with phenotype or clinical severity (as per Newcastle Mitochondrial Disease Adult Scale score).On average, muscle mtDNA copy number in patients was 76% of that observed in controls, with no differences by phenotype or inheritance pattern. All but 1 patient exhibited multiple mtDNA deletions, likely representing the primary mechanism of oxidative phosphorylation dysfunction rather than mtDNA depletion.
    Discussion: POLG-related disorders demonstrate extensive clinical variability with no consistent genotype-phenotype correlation. GDF15 and NF-L may serve as useful, though nonspecific, biomarkers of mitochondrial and neuroaxonal dysfunction, respectively. Prospective studies incorporating advanced molecular profiling are essential to establish reliable outcome measures and inform future therapeutic strategies.
    DOI:  https://doi.org/10.1212/NXG.0000000000200365
  3. Open Med (Wars). 2026 Jan;21(1): 20251342
    Beyond muscle weakness: pathogenesis of sepsis-induced myopathy and its management.
    Yukun Liu, Xuan Zhao, Zhikai Xu, Qinxin Liu, Yuchang Wang.
       Background: Sepsis-induced myopathy (SIM)significantly contributes to long-term disability and mortality among sepsis survivors. A comprehensive understanding of both the molecular mechanisms and rehabilitation strategies is crucial for effective management.
    Methods: A review of pertinent studies was conducted, focusing on the molecular pathogenesis, therapeutic strategies, and rehabilitation interventions for SIM, with particular attention to clinical and translational advancements.
    Results: Current management strategies encompass infection control, modulation of inflammation, nutritional support, and structured rehabilitation programs, including early mobilization and physiotherapy. Emerging therapies that target inflammation, cellular protection, and regeneration - such as stem cell therapy and gene-editing techniques - demonstrate potential. Furthermore, advancements in personalized medicine, including genomics, transcriptomics, and individualized metabolic interventions, may further improve outcomes.
    Conclusions: Optimizing both mechanistic and rehabilitation strategies is essential for enhancing functional recovery and quality of life in patients with SIM. An integrated clinical and molecular approach presents the most promising path forward. Keywords: sepsis-induced myopathy, sepsis.
    Keywords:  ICUAW; muscle atrophy; muscle wasting; sepsis; sepsis-induced myopathy
    DOI:  https://doi.org/10.1515/med-2025-1342
  4. Molecules. 2026 Feb 25. pii: 763. [Epub ahead of print]31(5):
    New Insights into the Anti-Aging Mechanism of Collagen Peptides-Emphasis on Lysosomes and Mitochondria Function.
    Wei Huang, Jinshan Ran, Yanli Du, Changwei Cao.
      With the intensification of social aging and the improvement of living standards, delaying aging has become a focus of common concern, especially in regard to skin aging. Although collagen peptides have been widely reported as therapeutic agents in relieving skin aging, the molecular mechanisms remain inadequately elucidated. This review emphasizes that the alleviation of skin aging by collagen peptides is a systematic and complex process, including the removal of reactive oxygen species, inhibition of inflammation, inhibition of extracellular matrix (ECM) degradation and melanin deposition, activation of lysosomal and mitochondrial function, and promotion of ECM synthesis. It also highlights that lysosomes and mitochondria may be the key organelles that regulate collagen peptides to alleviate skin aging. Current research on the mechanism of collagen peptides in alleviating skin aging still requires bold breakthroughs and should not be confined to the transforming growth factor (TGF-β)/Smad, mitogen-activated protein kinase, and nuclear factor kappa-B pathways. In addition, many natural antioxidant components have been proven to alleviate skin aging by regulating organelle function. Therefore, the regulatory effects of collagen peptides with antioxidant activity on mitochondrial and lysosome functions in aging skin need more attention and exploration, which is of great significance for further research on precise skin care and targeted anti-skin aging therapy.
    Keywords:  collagen peptides; lysosomes; mitochondria; precise anti-aging; skin aging
    DOI:  https://doi.org/10.3390/molecules31050763
  5. Int J Biol Sci. 2026 ;22(5): 2435-2451
    DNA Polymerase Gamma Acetylation Governs Mitochondrial Homeostasis and Vascular Cell Senescence.
    Pengbo Wang, Liming Yu, Kexin Cao, Xiaofan Guo, Lufan Sun, Shu Zhang, Tong Zhao, Yao Yu, Mengyao Xiong, Chang Liu, Naijin Zhang, Yingxian Sun, Guozhe Sun, Liu Cao.
      DNA polymerase gamma (Polγ), the sole polymerase for mitochondrial DNA (mtDNA), emerges as a critical regulator of metabolism-associated senescence. While lysine acetylation represents a key post-translational modification (PTM) influencing mitochondrial function, its mechanistic role in Polγ-mediated vascular aging remains undefined. Through combinatorial approaches employing in vitro acetylation models and POLG D257A/D257A mice, a validated model of mitochondrial dysfunction and senescence, we identify Lys 1039 (K1039) as a novel acetylation site which was dynamically regulated during aging process. Both D257A mutation-driven hyper-acetylation of Polγ K1039 reduced human aortic smooth muscle cell (HASMC) contractility, triggering pathological hyperproliferation and mitochondrial dysfunction, collectively culminating in premature cellular senescence. Pathological stimulation or genetic manipulation inducing hyperacetylation at K1039 disrupts Polγ's binding capacity with mtDNA. This molecular deficiency manifested functionally as compromised contractile performance in HASMCs and accelerated senescence phenotypes. Based on the above foundation and POLG D257A/D257A mice model, we demonstrated that D257A mutation reduced Sirt3-Polγ complex formation constituted the pathologically relevant molecular pathway driving aberrant acetylation homeostasis and leading to the senescence. Our findings establish a previously unrecognized regulatory axis wherein Polγ acetylation status at K1039 serves as a molecular switch coordinating mtDNA homeostasis, HASMCs functionality, and senescence progression. This mechanism might explain the remarkably consistent phenotypic manifestations of Polγ-induced dysfunction across diverse tissues and aging models. This work provides fundamental insights into the epigenetic-metabolic crosstalk governing vascular aging processes, providing a unifying framework for age-related vascular pathologies.
    Keywords:  Acetylation; DNA polymerase gamma; human aortic smooth muscle cells; mitochondrial homeostasis; senescence
    DOI:  https://doi.org/10.7150/ijbs.122298
  6. Trends Endocrinol Metab. 2026 Mar 07. pii: S1043-2760(26)00034-2. [Epub ahead of print]
    Targeting mitochondrial metabolism with combined metabolic activators.
    Hong Yang, Xiangtai Kong, Xinmeng Liao, Hasan Turkez, Jan Boren, Mathias Uhlen, Ozlem Altay, Adil Mardinoglu.
      Mitochondria play a central role in energy metabolism, redox balance, and cellular homeostasis, and their dysfunction has been implicated in the pathogenesis of complex human diseases. Advances in systems biology and omics technologies have elucidated the mechanisms underlying these conditions, including metabolic dysfunction, mitochondrial impairment, inflammation, and redox imbalance. Preclinical and early clinical studies of combined metabolic activators (CMA), a formulation of bioactive metabolites, have demonstrated improvements in mitochondrial function and systemic metabolic profiles across multiple diseases. In this review, we provide a comprehensive overview of the mechanistic rationale for CMA, summarize evidence from preclinical models and clinical studies investigating CMA and its components, and evaluate its translational potential and challenges as a mitochondrial-targeted therapeutic strategy for complex human diseases.
    Keywords:  NAD(+); combined metabolic activators; glutathione; l-carnitine tartrate; metabolic diseases; mitochondrial dysfunction; serine
    DOI:  https://doi.org/10.1016/j.tem.2026.01.018
  7. Mech Ageing Dev. 2026 Mar 05. pii: S0047-6374(26)00019-9. [Epub ahead of print]231 112167
    Mitochondrial quality in aging and neurodegeneration: The emerging role of mitochondria-derived vesicles.
    Emanuele Marzetti, Rosa Di Lorenzo, Riccardo Calvani, Hélio José Coelho-Júnior, Ettore D'Argento, Vito Pesce, Francesco Landi, Cecilia Bucci, Flora Guerra, Anna Picca.
      Mitochondria are central to cellular energy metabolism, redox balance, and signaling, and their integrity is maintained by a multilayered mitochondrial quality control (MQC) system. This system includes proteostasis, dynamics, biogenesis, and mitophagy, which together repair or remove damaged organelles. Mitochondria-derived vesicles (MDVs) have emerged as an additional MQC component. MDVs are small vesicles that bud from mitochondria and selectively transport damaged mitochondrial proteins, lipids, and nucleic acids to endolysosomal compartments or other intracellular destinations, enabling rapid and localized responses to mitochondrial stress. Acting upstream of or in parallel with mitophagy, MDVs can avoid or delay irreversible mitochondrial damage and help preserve cellular homeostasis. Aging and age-associated disorders are characterized by progressive mitochondrial dysfunction and chronic inflammation. Age-related changes in intracellular trafficking, lysosomal function, and vesicle dynamics may impair MDV formation, cargo selection, and targeting. Under conditions of defective degradation, mitochondrial components may also appear in extracellular vesicles, potentially contributing to altered intercellular signaling and inflammation. In the nervous system, where energetic demands are high and mitochondrial turnover requires tight regulation, such alterations may be especially harmful. This review summarizes MQC mechanisms in neurons, with a focus on MDVs, their dysregulation during aging and neurodegeneration, and implications for biomarkers and therapeutic strategies.
    Keywords:  Alzheimer’s disease; Huntington’s disease; Parkinson’s disease; Tau protein, α-synuclein
    DOI:  https://doi.org/10.1016/j.mad.2026.112167
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