bims-obesme Biomed News
on Obesity metabolism
Issue of 2025–07–06
nineteen papers selected by
Xiong Weng, University of Edinburgh
  1. An Epigenome Atlas of Mouse Adipocytes.
  2. Commitment of adipose-resident c-kit+ progenitors to brown adipocytes contributes to adipose tissue homeostasis and remodeling.
  3. Selfish mutations promote age-associated erosion of mtDNA integrity in mammals.
  4. Aging and Aging-Related Senescence in Liver.
  5. WSTF nuclear autophagy regulates chronic but not acute inflammation.
  6. cTAGE5 is essential for adipogenesis and adipose tissue development.
  7. Scalable screening of ternary-code DNA methylation dynamics associated with human traits.
  8. Profiling Epigenetic Aging at Cell-Type Resolution Through Long-Read Sequencing.
  9. Epigenetic erosion of H4K20me1 induced by inflammation drives aged stem cell ferroptosis.
  10. Identification of Functional Cellular Markers Related to Human Health, Frailty and Chronological Age.
  11. SUV39H1-dependent methyl-degron is a critical regulator of skeletal homeostasis.
  12. H3K79 methylation and H3K36 trimethylation synergistically regulate gene expression in pluripotent stem cells.
  13. Autoregulation of the real-time kinetics of the human mitochondrial replicative helicase.
  14. Visualizing PIEZO1 localization and activity in hiPSC-derived single cells and organoids with HaloTag technology.
  15. BAHCC1 binds H4K20me1 to facilitate the MCM complex loading and DNA replication.
  16. Tissue-specific responses to TFAM and mtDNA copy number manipulation in prematurely ageing mice.
  17. Mechanism of EHMT2-mediated genomic imprinting associated with Prader-Willi syndrome.
  18. Spatial patterns of hepatocyte glucose flux revealed by stable isotope tracing and multi-scale microscopy.
  19. Neuronal glycolysis meets mitophagy to govern organismal wellbeing.
  1. Mol Metab. 2025 Jun 27. pii: S2212-8778(25)00104-8. [Epub ahead of print] 102197
    An Epigenome Atlas of Mouse Adipocytes.
    Laura C Hinte, Adhideb Ghosh, Daniel Castellano-Castillo, Christian Wolfrum, Ferdinand von Meyenn.
       OBJECTIVE: Epigenetic modifications including histone post translational modifications can influence gene expression in adipocytes, potentially contributing to metabolic dysfunctions, obesity, and insulin resistance. Despite recent advances in the characterization of the mouse adipocyte epigenome, epigenetic characterization of adipocytes in vivo has been challenging, particularly across different adipose depots and of several epigenetic modifications.
    METHODS: Here, we use specific reporter mice labelling brown, beige and white adipocytes, diphtheria toxin-mediated ablation of beige adipocytes, and Cleavage Under Targets and Tagmentation (CUT&Tag) to generate paired single mouse datasets of five histone marks. We perform an integrative multi-omics factor analysis (MOFA) of H3K4me3, H3K27me3, H3K4me1, H3K27ac and H3K9me3 in brown, white and beige adipocytes from three distinct mouse adipose tissue depots obtained during cold exposure and thermoneutrality.
    RESULTS: Our analysis reveals that enhancers distinguish adipocytes by their tissue of origin, with H3K4me1 deposition differentiating between beige and brown adipocytes. Beige adipocytes poised promoters associated to thermogenic genes during warming. Diphtheria toxin-mediated ablation of beige adipocytes shows that non-beigeing white adipocytes in inguinal adipose tissue and beige adipocytes are not inherently epigenetically different suggesting that they share a common developmental progenitor.
    CONCLUSION: These paired multimodal data comprise an extensive resource (https://nme.ethz.ch/mAT_CEAtlas.html) for the further exploration of the mouse adipocyte epigenome which will enable discovery of regulatory elements governing adipocyte identity and gene regulation.
    Keywords:  Adipocytes; Beige; Brown; Enhancers; Epigenetics; Histone Marks; Multiomics; White
    DOI:  https://doi.org/10.1016/j.molmet.2025.102197
  2. Nat Commun. 2025 Jul 01. 16(1): 5883
    Commitment of adipose-resident c-kit+ progenitors to brown adipocytes contributes to adipose tissue homeostasis and remodeling.
    Qishan Chen, Ya Yu, Run Zhang, Qiaohang Zhao, Danqing Yu, Chun Feng, Jiaojiao Zhou, Meng Luo, Mei Yang, ShaSha Sun, Li Zhang, Min Jin.
      The global incidence of obesity-related metabolic disorders and their comorbidities continue to increase along with a demand for innovative therapeutic interventions. An in-depth understanding of de novo thermogenic adipogenesis is vital to harness the potential of these adipocytes. Here, we combine genetic lineage tracing and single-nucleus RNA sequencing to demonstrate that adult adipose-resident c-kit+ cells are previously unidentified brown adipocyte progenitor cells (APCs). c-kit+ APCs differentiate into brown adipocytes but not white adipocytes in adipose tissue homeostasis as well as in cold exposure-, high-fat diet (HFD)- and aging-induced adipose remodeling. More importantly, the vital role of c-kit+ APCs in the generation of brown adipocytes is indicated by decreased brown fat, impaired thermogenic capacity, and excessive fat accumulation in c-kit mutant mice of both genders. In conclusion, the present study demonstrates that adult c-kit+ APCs give rise to brown adipocytes which are responsible for fat homeostasis and remodeling. Thus, c-kit+ progenitors may be an innovative and crucial target for obesity and metabolic diseases.
    DOI:  https://doi.org/10.1038/s41467-025-60754-w
  3. Nat Commun. 2025 Jul 01. 16(1): 5435
    Selfish mutations promote age-associated erosion of mtDNA integrity in mammals.
    Ekaterina Korotkevich, Daniel N Conrad, Zev J Gartner, Patrick H O'Farrell.
      Mutations in mitochondrial DNA (mtDNA) accumulate during aging and contribute to age-related conditions. High mtDNA copy number masks newly emerged recessive mutations; however, phenotypes develop when cellular levels of a mutant mtDNA rise above a critical threshold. The process driving this increase is unknown. Single-cell DNA sequencing of mouse and human hepatocytes detected increases in abundance of mutant alleles in sequences governing mtDNA replication. These alleles provided a replication advantage (drive) leading to accumulation of the affected genome along with a wide variety of associated passenger mutations, some of which are detrimental. The most prevalent human mtDNA disease variant, the 3243A>G allele, behaved as a driver, suggesting that drive underlies prevalence. We conclude that replicative drive amplifies linked mtDNA mutations to a threshold at which phenotypes are seen thereby promoting age-associated erosion of the mtDNA and influencing the transmission and progression of mitochondrial diseases.
    DOI:  https://doi.org/10.1038/s41467-025-60477-y
  4. Semin Liver Dis. 2025 Jul 04.
    Aging and Aging-Related Senescence in Liver.
    Souradipta Ganguly, Sadatsugu Sakane, Kanani Hokutan, Vivian Zhang, Charlene Miciano, Allen Wang, David A Brenner, Tatiana Kisseleva.
      Aging is characterized by the progressive deterioration of cell and tissue functions. The liver, which regulates metabolic homeostasis, detoxification, and immune responses, undergoes structural and functional changes with age. These include increasing genomic instability, telomere attrition, epigenetic alterations, loss of proteostasis, deregulated nutrient-sensing and intracellular communication, mitochondrial dysfunction, cell senescence, stem cell exhaustion, chronic inflammation, disabled macroautophagy, and dysbiosis. These alterations contribute to hepatocyte dysfunction, impaired regenerative responses, and fibrosis risk, which all exacerbate existing liver diseases. Senescence involves irreversible cell cycle arrest resulting in an inflammatory, senescence-associated secretory cell phenotype. Senescent hepatocytes, liver sinusoidal endothelial cells, hepatic stellate cells, and Kupffer cells accumulate in the aged liver, creating an inflammatory and fibrotic microenvironment that promotes tumorigenesis. As the burden of aging-related liver disease increases, therapeutic strategies targeting hepatic senescence have gained attention. We review these, along with the mechanisms and pathogenic effects of liver aging.
    DOI:  https://doi.org/10.1055/a-2637-2549
  5. Nature. 2025 Jul 02.
    WSTF nuclear autophagy regulates chronic but not acute inflammation.
    Yu Wang, Vinay V Eapen, Yaosi Liang, Athanasios Kournoutis, Marc Samuel Sherman, Yanxin Xu, Angelique Onorati, Xianting Li, Xiaoting Zhou, Kathleen E Corey, Kuo Du, Ana Maria Cabral Burkard, Chia-Kang Ho, Jing Xie, Hui Zhang, Raquel Maeso-Díaz, Xinyi Ma, Ulrike Rieprecht, Tara O'Brien, Murat Cetinbas, Lu Wang, Jihe Liu, Corey Bretz, Aaron P Havas, Zhuo Zhou, Shannan J Ho Sui, Srinivas Vinod Saladi, Ruslan I Sadreyev, Peter D Adams, Robert E Kingston, Anna Mae Diehl, Benjamin Alman, Wolfram Goessling, Zhenyu Yue, Xiao-Fan Wang, Terje Johansen, Zhixun Dou.
      Acute inflammation is an essential response that our bodies use to combat infections1. However, in the absence of infections, chronic inflammation can have a pivotal role in the onset and progression of chronic diseases, such as arthritis, cancer, autoimmune disorders, metabolic-dysfunction-associated steatohepatitis (MASH), and most ageing-associated pathologies2,3. The underlying mechanisms that distinguish chronic inflammation from its acute counterpart remain unclear, posing challenges to the development of targeted therapies for these major diseases. Here we identify a mechanism that separates the two responses: during chronic but not acute inflammation, chromatin remodelling is influenced by nuclear autophagy, in which the WSTF protein of the ISWI chromatin-remodelling complex interacts with the ATG8 autophagy protein family in the nucleus. This interaction leads to WSTF nuclear export and subsequent degradation by autophagosomes and lysosomes in the cytoplasm. Loss of WSTF leads to chromatin opening over inflammatory genes, amplifying inflammation. Cell-penetrating peptides that block the WSTF-ATG8 interaction do not affect acute inflammation but suppress chronic inflammation in senescence as well as in MASH and osteoarthritis in mouse models and patient samples. The ability to specifically target chronic inflammation without blunting acute inflammation offers an approach for treating common chronic inflammatory diseases.
    DOI:  https://doi.org/10.1038/s41586-025-09234-1
  6. Nat Commun. 2025 Jul 01. 16(1): 5457
    cTAGE5 is essential for adipogenesis and adipose tissue development.
    Junwan Fan, Tiantian Ma, Xiaoping Ren, Zhilin Chang, Dan Zhang, Yi Wang, Shiyao Cheng, Xin Qi, Kehui Liu, Yan Wang, Yaqing Wang, Zhiheng Xu, Wenyan He.
      White adipocytes serve as primary energy reservoirs and their malfunction is linked to different metabolic disorders, yet the mechanisms underlying cellular specialization, a critical step during adipogenesis remain unknown. Here, we reveal the indispensable role of cutaneous T-cell lymphoma-associated antigen 5 (cTAGE5) in adipocyte differentiation and maturation. Conditional deletion of cTAGE5 in adipocyte precursor cells (APCs), rather than mature adipocytes, results in progressive loss of white adipose tissue and death of mice. Mechanistically, cTAGE5 deficiency in APCs disturbs pro-insulin receptor (IR) processing and impairs insulin signaling, accompanied by significant down-regulation of actin cytoskeleton related genes and defect in cytoskeleton remodeling, alongside enhanced expression of proteins associated with lipid catabolic process and lipolysis in adipocytes. Importantly, inhibitors targeting actin polymerization and lipolysis effectively restore adipocyte differentiation capacity in cTAGE5-deficient APCs. Collectively, our findings demonstrate that cTAGE5 plays pivotal roles in adipogenesis and adipose tissue development.
    DOI:  https://doi.org/10.1038/s41467-025-60698-1
  7. Cell Genom. 2025 Jul 02. pii: S2666-979X(25)00185-5. [Epub ahead of print] 100929
    Scalable screening of ternary-code DNA methylation dynamics associated with human traits.
    David C Goldberg, Cameron Cloud, Sol Moe Lee, Bret Barnes, Steven Gruber, Elliot Kim, Anita Pottekat, Maximillian S Westphal, Luana McAuliffe, Elisa Majounie, Manesh Kalayil Manian, Qingdi Zhu, Christine Tran, Mark Hansen, Jelena Stojakovic, Jared B Parker, Rahul M Kohli, Rishi Porecha, Nicole Renke, Wanding Zhou.
      Epigenome-wide association studies (EWASs) are transforming our understanding of the interplay between epigenetics and complex human traits. We introduce the methylation screening array (MSA) to enable scalable and quantitative screening of trait-associated DNA cytosine modifications in large human populations. The MSA integrates EWASs and cell-type-linked methylation signatures, covering diverse traits and diseases. Using the MSA to profile the ternary-code DNA methylations-dissecting 5-methylcytosine (5mC), 5-hydroxymethylcytosine (5hmC), and unmodified cytosine-revealed a previously unappreciated role of 5hmC in mediating human trait associations and epigenetic clocks. We demonstrated that 5hmCs complement 5mCs in defining epigenetic cell identities. In-depth analyses highlighted the cell-type context of EWAS and genome-wide association study (GWAS) hits. Targeting aging, we uncovered shared and tissue-specific 5hmC aging dynamics and tissue-specific rates of mitotic hyper- and hypomethylation. These findings chart a landscape of the complex interplay of the two forms of cytosine modifications in diverse human tissues and their roles in health and disease.
    Keywords:  5-hydroxymethylation; DNA methylation; Infinium array; epigenetic clock; epigenetics; epigenome-wide association study
    DOI:  https://doi.org/10.1016/j.xgen.2025.100929
  8. Aging Cell. 2025 Jul 02. e70084
    Profiling Epigenetic Aging at Cell-Type Resolution Through Long-Read Sequencing.
    Alec Eames, Mahdi Moqri, Jesse R Poganik, Vadim N Gladyshev.
      DNA methylation can give rise to robust biomarkers of aging, yet most studies profile it at the bulk tissue level, which masks cell type-specific alterations that may follow distinct aging trajectories. Long-read sequencing technology enables methylation profiling of extended DNA fragments, enabling mapping to their cell type of origin. In this study, we introduce a framework for evaluating cell type-specific aging using long-read sequencing data, without the need for cell sorting. Leveraging cell type-specific methylation patterns, we map long-read fragments to individual cell types and generate cell type-specific methylation profiles, which are used as input to a newly developed probabilistic aging model, LongReadAge, capable of predicting epigenetic age at the cell type level. We use LongReadAge to track aging of myeloid cells and lymphocytes from bulk leukocyte data as well as circulating cell-free DNA, demonstrating robust performance in predicting age despite limited shared features across samples. This approach provides a novel method for profiling the dynamics of epigenetic aging at cell type resolution.
    Keywords:  aging; epigenetics; long‐read sequencing
    DOI:  https://doi.org/10.1111/acel.70084
  9. Nat Aging. 2025 Jun 30.
    Epigenetic erosion of H4K20me1 induced by inflammation drives aged stem cell ferroptosis.
    Roméo S Blanc, Nidhi Shah, Sarah Hachmer, Noah A S Salama, Fanju W Meng, Alireza Mousaei, Gayatri Puri, Jeonghye Hannah Hwang, Elizabeth E Wacker, Benjamin A Yang, Carlos A Aguilar, Joe V Chakkalakal, John O Onukwufor, Patrick J Murphy, Laura M Calvi, F Jeffrey Dilworth, Robert T Dirksen.
      Aging is characterized by a decline in the functionality and number of stem cells across the organism. In this study, we uncovered a mechanism by which systemic inflammation drives muscle stem cell (MuSC) aging through epigenetic erosion. We demonstrate that age-related inflammation decreases monomethylation of H4K20 in MuSCs, disrupting their quiescence and inducing ferroptosis, a form of iron-dependent cell death. Our findings show that inflammatory signals downregulate Kmt5a, the enzyme responsible for depositing H4K20me1, leading to the epigenetic silencing of anti-ferroptosis genes. This results in aberrant iron metabolism, increased reactive oxygen species levels and lipid peroxidation in aged MuSCs. Notably, long-term inhibition of systemic inflammation that is initiated at 12 months of age effectively prevents ferroptosis, preserves MuSC numbers and enhances muscle regeneration and functional recovery. These findings reveal an epigenetic switch that links chronic inflammation to MuSC aging and ferroptosis, offering potential therapeutic strategies for combating age-related muscle degeneration.
    DOI:  https://doi.org/10.1038/s43587-025-00902-5
  10. Aging Cell. 2025 Jul 01. e70153
    Identification of Functional Cellular Markers Related to Human Health, Frailty and Chronological Age.
    IHU HealthAge/Open Science group
      Aging leads to a decline in physiological reserves, an increase in age-related diseases, reduced functional ability and a shortened healthspan. While molecular markers of chronological aging exist, their link to general health and intrinsic capacity (IC), a composite measure of physical and mental capacities, remains unclear. This study integrates the WHO's Healthy Aging framework with geroscience to explore fibroblasts as indicators of health. We assessed primary skin fibroblasts from 133 individuals aged 20-96, evaluating their ability to maintain tissue structure, modulate immune responses and regulate metabolism (SIM functions). By combining functional and molecular analyses, we investigated the relationship between fibroblast performance, chronological age and IC. Our results demonstrate that fibroblast SIM functions are modified with stressors and age, correlating with IC rather than just chronological age. Notably, fibroblasts from pre-frail and frail individuals exhibited reduced mitochondrial respiration and lower extracellular periostin levels, with periostin being able to capture IC status, irrespective of age and sex, reflecting a cellular 'health memory'. The SIM paradigm provides a complementary framework to the established hallmarks of aging, advancing our understanding of how cellular aging impacts functional decline. These findings suggest that fibroblast-derived markers could serve as indicators of frailty and reduced IC, enabling early detection of individuals at risk for health deterioration and laying the foundation for early identification of functional decline.
    Keywords:  cellular aging; dermal fibroblast; extracellular matrix; healthy aging; intrinsic capacity; metabolism
    DOI:  https://doi.org/10.1111/acel.70153
  11. Cell Rep. 2025 Jun 27. pii: S2211-1247(25)00681-3. [Epub ahead of print]44(7): 115910
    SUV39H1-dependent methyl-degron is a critical regulator of skeletal homeostasis.
    Qian Li, Hongguang An, Rushui Bai, Qiannan Sun, Ruili Yang, Tianyi Xin, Zimeng Zhuang, Yuntao Lu, Yunyi Tang, Gengyao Chen, Weifang Zhang, Yu Zhang, Bing Han.
      Bone homeostasis and skeletal fragility are sexually dimorphic in humans, with postmenopausal women at the highest risk of osteoporosis. Here, we identify X-linked methyltransferase SUV39H1 as a suppressor of osteogenesis in females. Both experiments in primary samples and Suv39h1-deficient mice show enhanced osteogenesis upon SUV39H1 ablation with gender differences. Transcriptomic analysis reveals the aberrant NF-κB activation and inflammation signatures independent of H3K9me3 underlying SUV39H1-inhibited osteogenesis. Surprisingly, SUV39H1 shows a unique cytoplasmic distribution in female osteoblasts and is directly engaged in inflammation response by catalyzing IκBα methylation at lysine 38 adjacent to its degradation motif. This SUV39H1-deposited methylation mark signals UACA binding and subsequently restrains bone formation by provoking IκBα destabilization. Importantly, intrinsically improved osteogenesis by Suv39h1 depletion ameliorates ovariectomy-induced osteoporotic bone loss. Together with the chronologically elevated female SUV39H1 levels, these data identify an SUV39H1-governed molecular amplifier in sexually divergent skeletal remodeling and highlight its potential as therapeutic avenue for osteoporosis.
    Keywords:  CP: Developmental biology; CP: Molecular biology; IκBα; NF-κB; SUV39H1; bone homeostasis; degradation; inflammation; methylation; osteogenic differentiation; protein stability; sexual dimorphism
    DOI:  https://doi.org/10.1016/j.celrep.2025.115910
  12. Sci Adv. 2025 Jul 04. 11(27): eadt8765
    H3K79 methylation and H3K36 trimethylation synergistically regulate gene expression in pluripotent stem cells.
    Emmalee W Cooke, Cheng Zeng, Suza Mohammad Nur, Yunbo Jia, Aileen Huang, Jiwei Chen, Peidong Gao, Fei Xavier Chen, Fulai Jin, Kaixiang Cao.
      Metazoan nucleosomes harboring H3K79 methylation (H3K79me) deposited by the methyltransferase DOT1L (disruptor of telomeric silencing 1-like) decorate actively transcribed genes. While DOT1L regulates transcription and the pathogenesis of leukemia and neurological disorders, the role of H3K79me remains elusive. Here, we reveal a functional synergism between H3K79me and H3K36 trimethylation (H3K36me3) in regulating gene expression and cellular differentiation. Simultaneous catalytic inactivation of DOT1L and the H3K36 methyltransferase SETD2 (SET domain containing 2) leads to hyperactive transcription and failures in neural differentiation. H3K79me/H3K36me3 loss causes increased transcription elongation, gained chromatin accessibility at a group of enhancers, and increased recruitment of TEAD4 (TEA domain transcription factor 4) and its coactivator YAP1 (Yes-associated protein 1) to these enhancers. Furthermore, YAP-TEAD inhibition restores the expression levels of genes hyperactivated by H3K79me/H3K36me3 loss. Together, we demonstrate a synergism of H3K79me and H3K36me3 in regulating transcription and cell fate transition, unveil the underlying mechanisms, and provide insight into targeting diseases driven by misregulation/mutations of DOT1L and/or SETD2.
    DOI:  https://doi.org/10.1126/sciadv.adt8765
  13. Nat Commun. 2025 Jul 01. 16(1): 5460
    Autoregulation of the real-time kinetics of the human mitochondrial replicative helicase.
    Ismael Plaza-G A, María Ortiz-Rodríguez, Seth P Buchanan, Samuel Miguez-Amil, Kateryna M Lemishko, Fernando Moreno-Herrero, Rafael Fernandez-Leiro, Grzegorz L Ciesielski, Borja Ibarra.
      The human mitochondrial helicase Twinkle is essential for mitochondrial DNA (mtDNA) replication and integrity. Using biochemical and single-molecule techniques, we investigated Twinkle's real-time kinetics, including DNA loading, unwinding, and rewinding, and their regulation by its N-terminal Zinc-binding domain (ZBD), C-terminal tail, and mitochondrial SSB protein (mtSSB). Our results indicate that Twinkle rapidly scans dsDNA to locate the fork, where specific interactions halt diffusion. During unwinding, ZBD-DNA interactions and C-terminal tail control of ATPase activity downregulate kinetics, slowing down the helicase. Binding of mtSSB to DNA likely outcompetes ZBD-DNA interactions, alleviating the downregulatory effects of this domain. Furthermore, we show that ZBD-DNA interactions and ATP binding also regulate rewinding kinetics following helicase stalling. Our findings reveal that ZBD and C-terminal tail play a major role in regulation of Twinkle´s real-time kinetics. Their interplay constitutes an auto-regulatory mechanism that may be relevant for coordinating the mtDNA maintenance activities of the helicase.
    DOI:  https://doi.org/10.1038/s41467-025-60289-0
  14. Nat Commun. 2025 Jul 01. 16(1): 5556
    Visualizing PIEZO1 localization and activity in hiPSC-derived single cells and organoids with HaloTag technology.
    Gabriella A Bertaccini, Ignasi Casanellas, Elizabeth L Evans, Jamison L Nourse, George D Dickinson, Gaoxiang Liu, Sayan Seal, Alan T Ly, Jesse R Holt, Tharaka D Wijerathne, Shijun Yan, Elliot E Hui, Jerome J Lacroix, Mitradas M Panicker, Srigokul Upadhyayula, Ian Parker, Medha M Pathak.
      PIEZO1 is critical to numerous physiological processes, transducing diverse mechanical stimuli into electrical and chemical signals. Recent studies underscore the importance of visualizing endogenous PIEZO1 activity and localization to understand its functional roles. To enable physiologically and clinically relevant studies on human PIEZO1, we genetically engineered human induced pluripotent stem cells (hiPSCs) to express a HaloTag fused to endogenous PIEZO1. Combined with advanced imaging, our chemogenetic platform allows precise visualization of PIEZO1 localization dynamics in various cell types. Furthermore, the PIEZO1-HaloTag hiPSC technology facilitates the non-invasive monitoring of channel activity across diverse cell types using Ca2+-sensitive HaloTag ligands, achieving temporal resolution approaching that of patch clamp electrophysiology. Finally, we use lightsheet microscopy on hiPSC-derived neural organoids to achieve molecular scale imaging of PIEZO1 in three-dimensional tissue. Our advances establish a platform for studying PIEZO1 mechanotransduction in human systems, with potential for elucidating disease mechanisms and targeted drug screening.
    DOI:  https://doi.org/10.1038/s41467-025-59150-1
  15. Nat Commun. 2025 Jul 01. 16(1): 5502
    BAHCC1 binds H4K20me1 to facilitate the MCM complex loading and DNA replication.
    Dongxu Li, Zhi-Min Zhang, Liu Mei, Yao Yu, Yiran Guo, Samuel G Mackintosh, Jianbin Chen, David F Allison, Arum Kim, Aaron J Storey, Ricky D Edmondson, Stephanie D Byrum, Alan J Tackett, Ling Cai, Jeanette G Cook, Jikui Song, Gang Greg Wang.
      Mono-methylation of histone H4 lysine 20 (H4K20me1) regulates DNA replication, cell cycle progression and DNA damage repair. How exactly H4K20me1 regulates these biological processes remains unclear. Here, we report that an evolutionarily conserved tandem Tudor domain (TTD) in BAHCC1 (BAHCC1TTD) selectively reads H4K20me1 for facilitating replication origin activation and DNA replication. Our biochemical, structural, genomic and cellular analyses demonstrate that BAHCC1TTD preferentially recognizes H4K20me1 to promote the recruitment of BAHCC1 and its interacting partners, notably Mini-chromosome Maintenance (MCM) complex, to replication origin sites. Combined actions of the H4K20me1-reading BAHCC1 and the H4K20me2-reading Origin Recognition Complex (ORC) ensure genomic loading of MCM for replication. Depletion of BAHCC1, or disruption of the BAHCC1TTD:H4K20me1 interaction, reduces H4K20me1 levels and MCM loading, leading to defects in replication origin activation and cell cycle progression. In summary, this study identifies BAHCC1TTD as an effector transducing H4K20me1 signals into MCM recruitment to promote DNA replication.
    DOI:  https://doi.org/10.1038/s41467-025-61284-1
  16. Elife. 2025 Jun 30. pii: RP104461. [Epub ahead of print]14
    Tissue-specific responses to TFAM and mtDNA copy number manipulation in prematurely ageing mice.
    Laura Sophie Kremer, Guanbin Gao, Giovanni Rigoni, Roberta Filograna, Mara Mennuni, Rolf Wibom, Ákos Végvári, Camilla Koolmeister, Nils-Göran Larsson.
      Somatic mitochondrial DNA (mtDNA) mutations are implicated as important drivers of ageing and age-related diseases. Their pathological effect can be counteracted by increasing the absolute amount of wild-type mtDNA via moderately upregulating TFAM, a protein important for mtDNA packaging and expression. However, strong TFAM overexpression can also have detrimental effects as it results in mtDNA hypercompaction and subsequent impairment of mtDNA gene expression. Here, we have experimentally addressed the propensity of moderate TFAM modulation to improve the premature ageing phenotypes of mtDNA mutator mice, carrying random mtDNA mutations. Surprisingly, we detect tissue-specific endogenous compensatory mechanisms acting in mtDNA mutator mice, which largely affect the outcome of TFAM modulation. Accordingly, moderate overexpression of TFAM can have negative and beneficial effects in different tissues of mtDNA mutator mice. We see a similar behavior for TFAM reduction, which improves brown adipocyte tissue homeostasis, while other tissues are unaffected. Our findings highlight that the regulation of mtDNA copy number and gene expression is complex and causes tissue-specific effects that should be considered when modulating TFAM levels. Additionally, we suggest that TFAM is not the sole determinant of mtDNA copy number in situations where oxidative phosphorylation (OXPHOS) is compromised, but other important players must be involved.
    Keywords:  biochemistry; chemical biology; genetics; genomics; mitochondrial DNA; mouse; mtDNA copy number; mtDNA mutations; tissue specificity
    DOI:  https://doi.org/10.7554/eLife.104461
  17. Nat Commun. 2025 Jul 03. 16(1): 6125
    Mechanism of EHMT2-mediated genomic imprinting associated with Prader-Willi syndrome.
    Sung Eun Wang, Yubao Cheng, Jaechul Lim, Mi-Ae Jang, Emily N Forrest, Yuna Kim, Meaghan Donahue, Sungsin Jo, Sheng-Nan Qiao, Dong Eun Lee, Jun Young Hong, Yan Xiong, Jian Jin, Siyuan Wang, Yong-Hui Jiang.
      Prader-Willi Syndrome (PWS) is caused by the loss of expression of paternally expressed genes in the human 15q11.2-q13 imprinting domain. A set of imprinted genes that are active on the paternal but silenced on the maternal chromosome are intricately regulated by a bipartite imprinting center (PWS-IC) located in the PWS imprinting domain. We previously discovered that euchromatic histone lysine N-methyltransferase-2 (EHMT2/G9a) inhibitors are capable of un-silencing PWS-associated genes by restoring their expression from the maternal chromosome. Here, in mice lacking the Ehmt2 gene, we document un-silencing of the imprinted Snrpn/Snhg14 gene on the maternal chromosome in the late embryonic and postnatal brain. Using PWS and Angelman syndrome patient derived cells with either paternal or maternal deletion of 15q11.2-q13, we have found that chromatin of maternal PWS-IC is closed and has compact 3D folding confirmation. We further show that a distinct noncoding RNA (TSS4-280118) preferentially transcribed from the upstream of the PWS-IC of maternal chromosome interacts with EHMT2 and forms a heterochromatin complex in CIS on the maternal chromosome. Inactivation of TSS4-280118 by CRISPR/Cas9 editing results in unsilencing of the expression of SNRPN and SNORD116 from the maternal chromosome. Taken together, these findings demonstrate that allele-specific recruitment of EHMT2 is required to maintain the maternal imprints. Our findings provide mechanistic insights and support a model for imprinting maintenance of the PWS imprinted domain.
    DOI:  https://doi.org/10.1038/s41467-025-61156-8
  18. Nat Commun. 2025 Jul 01. 16(1): 5850
    Spatial patterns of hepatocyte glucose flux revealed by stable isotope tracing and multi-scale microscopy.
    Aliyah Habashy, Christopher Acree, Keun-Young Kim, Ali Zahraei, Martin Dufresne, Sebastien Phan, Melanie Cutler, Emilee Patterson, Alexandra G Mulligan, Kristopher Burkewitz, Charles Robert Flynn, Louise Lantier, Thomas Deerinck, Owen P McGuinness, Jeffrey M Spraggins, Mark H Ellisman, Rafael Arrojo E Drigo.
      Metabolic homeostasis requires engagement of catabolic and anabolic pathways consuming nutrients that generate and consume energy and biomass. Our current understanding of cell homeostasis and metabolism, including how cells utilize nutrients, comes largely from tissue and cell models analyzed after fractionation, and that fail to reveal the spatial characteristics of cell metabolism, and how these aspects relate to the location of cells and organelles within tissue microenvironments. Here we show the application of multi-scale microscopy, machine learning-based image segmentation, and spatial analysis tools to quantitatively map the fate of nutrient-derived 13C atoms across spatiotemporal scales. This approach reveals the cellular and organellar features underlying the spatial pattern of glucose 13C flux in hepatocytes in situ, including the timeline of mitochondria-ER contact dynamics in response to changes in blood glucose levels, and the discovery of the ultrastructural relationship between glycogenesis and lipid droplets.
    DOI:  https://doi.org/10.1038/s41467-025-60994-w
  19. Trends Endocrinol Metab. 2025 Jul 02. pii: S1043-2760(25)00120-1. [Epub ahead of print]
    Neuronal glycolysis meets mitophagy to govern organismal wellbeing.
    Daniel Jimenez-Blasco, Rebeca Lapresa, Jesus Agulla, Angeles Almeida, Juan P Bolaños.
      Neurons are exceptionally energy-demanding cells but have limited energy storage, relying on a constant supply of fuel and oxygen. Although glucose is the brain's main energy source, neurons reduce glycolysis under normal conditions. This surprising strategy helps to protect mitochondria by preserving nicotinamide-adenine dinucleotide (NAD+), a vital cofactor consumed by glycolysis. NAD+ is needed for sirtuin-driven mitophagy, a process that removes damaged mitochondria. By saving NAD+, neurons can maintain healthy, energy-efficient mitochondria. These mitochondria then use alternative fuels such as lactate and ketone bodies from astrocytes. Here, we discuss the way in which this balance between reduced glycolysis and active mitophagy supports brain function and overall metabolic health, highlighting a sophisticated system that prioritizes mitochondrial quality for long-term cognitive performance and systemic homeostasis.
    Keywords:  NAD; glycolysis; mitophay; neuron; organismal wellbeing
    DOI:  https://doi.org/10.1016/j.tem.2025.05.005
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