Abdualkader et al. report that SGLT2 inhibitors boost ketone production by directly activating a liver enzyme, revealing a mechanism that may contribute to their heart and kidney benefits. The cover image shows the crystal structure of human mitochondrial 3-hydroxy-3-methylglutaryl-CoA synthase 2 (HMGCS2) homodimer (rainbow ribbons) bound to empagliflozin (gray sticks). Molecular structures were visualized and rendered using PyMOL (Schrödinger, version 3.1.0).
BACKGROUND. In female murine models, one source of inflammation is a menopause-related increase in gut permeability. We examined whether the menopause transition (MT) in women is associated with an increase in markers of gut epithelial dysfunction and gut microbial product translocation, signals of compromised gut epithelial barrier integrity. METHODS. In 964 women, we measured markers of gut epithelial dysfunction (fatty acid binding protein 2, FABP2) and gut microbial antigen translocation (soluble CD14, sCD14) using sera collected before, during and after the MT. Multivariable mixed effects regressions fit piece-wise linear models to repeated FABP2 or sCD14 measures relative to time from final menstrual period (FMP). Covariates were age at FMP, race/ethnicity, and BMI. RESULTS. FABP2 and sCD14 did not change significantly until 2.5 years pre-FMP. At that point, FABP2 began rising; sCD14 began increasing 6 months later. FABP2 and sCD14 peaked 6 and 6.5 years post-FMP, respectively; subsequent levels remained stable. During the ~9-year interval of MT-related gain in gut barrier compromise markers, annual FABP2 and sCD14 increases were 2.6% (95% CI: 1.7 to 3.4%) and 0.8% (95% CI: 0.6 to 1.1%), respectively, among white women with sample-average BMI and age at FMP. FABP2 and sCD14 change rates did not differ significantly by race/ethnicity, BMI, or age at FMP. CONCLUSIONS. The MT is associated with a rise in markers of compromised gut barrier integrity, suggesting that this pathway of inflammation, previously described in animal models, occurs in humans. FUNDING. NIH U01NR004061, U01AG012505, U01AG012535, U01AG012531, U01AG012539, U01AG012546, U01AG012553, U01AG012554, U01AG012495, 5R01AR081794.
Albert Shieh, Marta Epeldegui, Arun S. Karlamangla, Rheinallt Jones, Roberto Pacifici, Gail A. Greendale
Sarcopenia is the age-related loss of muscle strength and size that leads to mobility limitations and loss of independence in older adults. The underlying cellular mechanisms remain unclear, and treatments are limited. As the critical interface between the nervous system and muscle, the neuromuscular junction (NMJ) is essential for muscle activation and force production. Here, we demonstrate that weak older individuals exhibit NMJ transmission failure that correlates with muscle weakness severity. Preclinical experiments showed similar NMJ transmission failure in aged rodents that was associated with localized loss of muscle fiber excitability at the NMJ. This excitability defect, distinct from potential synaptic cholinergic transmission abnormalities, represents a novel disease mechanism of sarcopenia. Across species, immunohistochemistry identified a localized reduction in the voltage-gated sodium channel specific for skeletal muscle (NaV1.4) at the post-synaptic NMJ membrane. Acute NaV1.4 inhibition with μ-conotoxin GIIIB in adult rats reproduced findings of NMJ transmission failure observed in aged rodents and humans. Finally, ClC-1 chloride ion channel inhibition enhanced muscle excitability and improved NMJ transmission and muscle function in old rodents. Together, these findings demonstrate that NMJ transmission deficits are a key, reversible driver of sarcopenia and reveal a novel therapeutic target for addressing muscle weakness in aging.
W. David Arnold, Jeanette Jeppesen Morgen, Pernille Bogetofte Thomasen, Martin Broch-Lips, Leatha A. Clark, Thomas Groennebaek, Martin Skov, Jeppe Blichfeldt Winther, Abdullah F. Ramadan, Philippa A. Rust, Jessica H. Myers, Fereshteh B. Darvishi, Anna R. Dashtmian, Lauren A. Fish, Deepti Chugh, Jane Bold, Jorge A. Quiroz, John Hutchison, Hiroshi Nishimune, Ross A. Jones, Xueyong Wang, Justin R. Fallon, Thomas H. Gillingwater, Mark M. Rich, Thomas Holm Pedersen, Brian C. Clark
Our research uncovers a new role for ATR in responding to extracellular matrix (ECM) stiffness and promoting epithelial-to-mesenchymal transition (EMT) and metastasis. ATR, when deubiquitinated and upregulated by USP21 under enhanced ECM stiffness conditions, phosphorylates the nuclear protein SUN2 which promotes β-catenin nuclear translocation and EMT. ATM mediated EMT promotes polymorphonuclear myeloid-derived suppressor cell recruitment and inhibits CD103+ dendritic cells, fostering an immunosuppressive tumor milieu. ATR inhibition disrupts this malignant cascade by promoting mesenchymal to epithelial transition to enhance anti-tumor immunity and mitigate metastases. Consistently, circulating HLA-DR+ dendritic cells were also enhanced following treatment with the ATR inhibitor, Berzosertib, in patients with therapeutically resistant early-stage breast cancer. Our data suggest that ATR targeted therapy may be optimized by considering both DNA damage dependent and EMT inducing effects of ATR.
Xinyi Tu, Xiangyu Zeng, Yaoliang Sun, Yaobin Ouyang, Lingling Zhu, Ping Yin, Kevin D. Pavelko, Roberto A. Leon-Ferre, Yanxia Jiang, Haidong Dong, Jodi M. Carter, Shouhai Zhu, Jann N. Sarkaria, Liewei Wang, Jinzhou Huang, Kuntian Luo, Yiqun Han, Zheming Wu, Zhenkun Lou, Robert W. Mutter
ATR inhibition is under evaluation for treatment of high-grade serous ovarian cancer (HGSOC) to reverse acquired resistance to poly (ADP-ribose) polymerase (PARP) inhibition and to exacerbate chemotherapy-induced replicative stress. Here, we define PTEN deficiency as a predictive biomarker for response to ATR inhibition, as monotherapy and in combination with PARP inhibition or gemcitabine. In response to ATR inhibition and compared to PTEN-proficient cells, PTEN-deficient cells are prone to (1) uncoupling of DNA polymerase and helicase activities, leading to excessive single-stranded DNA and replication stress; (2) cytoplasmic sequestration of CHK1, compromising cell cycle checkpoint control with reduced compensatory effects by ATM and DNA-PK, leading to mitotic catastrophe; and (3) reduced RAD51 recruitment, exacerbating replication fork instability, also leading to lethality. Retrospective analyses demonstrate that patients with HGSOC expressing low PTEN levels experience greater clinical benefit on ATR inhibitor-based trials than those with high levels. These results justify prospective trials evaluating ATR inhibition as a therapeutic strategy for PTEN-deficient tumors.
Jie Hao, Bose Kochupurakkal, Timothy B. Branigan, Ozge Sezin Somuncu, Renyan Liu, Heta Jadhav, Alexandre Andre B.A. da Costa, Yuqing Jiao, Jenny Z. Yu, David B. Martignetti, Golbahar Sadatrezaei, Sirisha Mukkavalli, Prafulla C. Gokhale, Su-Chun Cheng, Steven J. Skates, Dimitrios Nasioudis, Panagiotis A. Konstantinopoulos, Joyce F. Liu, Stephanie L. Gaillard, Robert L. Giuntoli II, Lainie P. Martin, Janos L. Tanyi, Nawar Latif, Ian S. Heller, Fiona Simpkins, Kalindi Parmar, Alan D. D'Andrea, Geoffrey I. Shapiro
Heterogeneous degeneration of the retinal pigment epithelium (RPE) leads to irreversible blindness in diseases associated with macular atrophy. However, the underlying mechanisms of regional RPE degeneration remain poorly understood. To address this gap, this study identifies a peripheral RPE subpopulation through spatial, transcriptomic, and functional analyses, thereby contributing to the understanding of the heterogeneity of degenerative RPE cells. Specifically, omics analyses in human and macaque RPE reveal a peripheral RPE cell population with high SERPINE3 expression, while SERPINE3-GFP knock-in mice show comparable expression patterns. In addition, SMART-seq2 analysis further distinguishes transcriptomic profiles between GFP-positive and GFP-negative RPE cells. Under oxidative stress, SERPINE3 expression increases, and GFP-positive cells exhibit improved survival and reentry into the cell cycle. Notably, genetic studies indicate that SERPINE3 is essential for the oxidative stress resistance of GFP-positive cells. Moreover, loss of SERPINE3 results in regional RPE degeneration and increased microglial accumulation in aged mice. Mechanistically, proteinase screening and co-immunoprecipitation indicate that SERPINE3 targets Caspase-1. Importantly, delivery of SERPINE3 via AAV-Serpine3 partially reduces RPE degeneration in an oxidative damage model. These findings advance the understanding of RPE heterogeneous degeneration and highlight SERPINE3 as a protective factor with therapeutic potential for macular atrophy.
Huirong Li, Takerra Johnson-Stephenson, Vincent P. Kunze, Wei Yan, David M. McGaughey, Temesgen D. Fufa, Koray Dogan Kaya, Ashley M. Rasys, Davide Ortolan, Dominik Reichert, Congxiao Zhang, Ruchi Sharma, Lijin Dong, Bin Guan, Brian P. Brooks, Tiansen Li, Wei Li, Wencan Wu, Kapil Bharti, Robert B. Hufnagel
The cyclic GMP-AMP synthase (cGAS)–stimulator of interferon genes (STING) pathway is a key component of innate immunity, linking DNA detection to inflammatory and antiviral responses. Originally identified as a sensor for microbial DNA, cGAS is now understood to also respond to endogenous cytosolic DNA, and the pathway has been implicated in a wide range of physiological and pathological processes, including cancer, autoimmunity, neuroinflammation, and aging. This review series, organized by Dr. Alex Stegh, consolidates current knowledge and highlights emerging developments that may lead to therapeutic targeting of the cGAS-STING pathway across a range of disorders.
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