Top read articles in the last 30 days

Structural basis for simvastatin-induced skeletal muscle weakness associated with type 1 ryanodine receptor T4709M mutation

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Abstract

Statins lower cholesterol, reducing the risk of heart disease, and are among the most frequently prescribed drugs. Approximately 10% of individuals develop statin-associated muscle symptoms (SAMS; myalgias, rhabdomyolysis, and muscle weakness), often rendering them statin intolerant. The mechanism underlying SAMS remains poorly understood. Patients with mutations in the skeletal muscle ryanodine receptor 1 (RyR1)/calcium release channel can be particularly intolerant of statins. High-resolution structures revealed simvastatin binding sites in the pore region of RyR1. Simvastatin stabilized the open conformation of the pore and activated the RyR1 channel. In a mouse expressing a mutant RyR1-T4709M found in a patient with profound statin intolerance, simvastatin caused muscle weakness associated with leaky RyR1 channels. Cotreatment with a Rycal drug that stabilizes the channel closed state prevented simvastatin-induced muscle weakness. Thus, statin binding to RyR1 can cause SAMS, and patients with RyR1 mutations may represent a high-risk group for statin intolerance.

Authors

Gunnar Weninger, Haikel Dridi, Steven Reiken, Qi Yuan, Nan Zhao, Linda Groom, Jennifer Leigh, Yang Liu, Carl Tchagou, Jiayi Kang, Alexander Chang, Estefania Luna-Figueroa, Marco C. Miotto, Anetta Wronska, Robert T. Dirksen, Andrew R. Marks

Curing autoimmune diabetes in mice with islet and hematopoietic cell transplantation after CD117 antibody-based conditioning

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Abstract

Mixed hematopoietic chimerism after allogeneic hematopoietic cell transplantation (HCT) promotes tolerance of transplanted donor-matched solid organs, corrects autoimmunity, and could transform therapeutic strategies for autoimmune type 1 diabetes (T1D). However, development of nontoxic bone marrow conditioning protocols is needed to expand clinical use. We developed a chemotherapy-free, nonmyeloablative (NMA) conditioning regimen that achieves mixed chimerism and allograft tolerance across MHC barriers in NOD mice. We obtained durable mixed hematopoietic chimerism in prediabetic NOD mice using anti–CD117 monoclonal antibody, T cell depleting antibodies, JAK1/2 inhibition, and low-dose total body irradiation prior to transplantation of MHC-mismatched B6 hematopoietic cells, preventing diabetes in 100% of chimeric NOD:B6 mice. In overtly diabetic NOD mice, NMA conditioning followed by combined B6 HCT and islet transplantation durably corrected diabetes in 100% of chimeric mice without chronic immunosuppression or graft-versus-host disease (GVHD). Chimeric mice remained immunocompetent, as assessed by blood count recovery and rejection of third-party allogeneic islets. Adoptive transfer studies and analysis of autoreactive T cells confirmed correction of autoimmunity. Analysis of chimeric NOD mice revealed central thymic deletion and peripheral tolerance mechanisms. Thus, with NMA conditioning and cell transplantation, we achieved durable hematopoietic chimerism without GVHD, promoted islet allograft tolerance, and reversed established T1D.

Authors

Preksha Bhagchandani, Stephan A. Ramos, Bianca Rodriguez, Xueying Gu, Shiva Pathak, Yuqi Zhou, Yujin Moon, Nadia Nourin, Charles A. Chang, Jessica Poyser, Brenda J. Velasco, Weichen Zhao, Hye-Sook Kwon, Richard Rodriguez, Diego M. Burgos, Mario A. Miranda, Everett Meyer, Judith A. Shizuru, Seung K. Kim

Adipocyte-derived FABP4 promotes metabolism-associated steatotic liver–induced hepatocellular carcinoma by driving ITGB1-mediated β-catenin activation

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Abstract

Metabolic dysfunction–associated steatotic liver disease–induced (MASLD-induced) hepatocellular carcinoma (HCC) is an emerging malignancy linked to excessive accumulation of adipose tissue and hepatic fat. Understanding the role of adipocytes in the development of MASLD-induced HCC is crucial. In an in vitro coculture system, differentiated adipocytes were found to enhance cancer stemness and drug resistance in HCC through paracrine signaling. Fatty acid–binding protein 4 (FABP4) was preferentially secreted by adipocytes, and recombinant FABP4 further augmented the cancer stem cell (CSC) properties of HCC cells. Notably, Fabp4–/– mice exhibited a marked delay in the progression of MASLD-HCC, which correlated with the increased HCC risk observed in MASLD patients with elevated FABP4 expression. Mass spectrometry analysis identified integrin β 1 (ITGB1) as a binding partner of FABP4. These data, together with a substantial downregulation of the Wnt/β-catenin pathway in Fabp4–/– mouse tumors, revealed that FABP4 augmented liver CSC functions by activating PI3K/AKT/β-catenin signaling via ITGB1. We developed an anti-FABP4 neutralizing antibody that successfully inhibited FABP4-driven CSC functions and suppressed MASLD-induced HCC. In conclusion, our findings indicate that adipocyte-derived FABP4 plays a critical role in the development of MASLD-induced HCC and targeting the ITGB1/PI3K/AKT/β-catenin signaling cascade may offer a promising approach to combat this aggressive disease.

Authors

Carmen Oi Ning Leung, Shilpa Gurung, Katherine Po Sin Chung, Rainbow Wing Hei Leung, Martina Mang Leng Lei, Mandy Sze Man Chan, Gregory Kenneth Muliawan, Shakeel Ahmad Khan, Xue Qian Wu, Jun Yu, Hui Lian Zhu, Yin Ying Lu, Stephanie Ma, Xiaoping Wu, Ruby Lai Chong Hoo, Terence Kin Wah Lee

DLL4⁺ neutrophils promote Notch1-mediated endothelial PANoptosis to exacerbate acute lung injury in sepsis

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Abstract

Neutrophils play a critical role in sepsis-induced acute lung injury (ALI). Extracellular cold-inducible RNA-binding protein (eCIRP), a damage-associated molecular pattern, promotes neutrophil heterogeneity. While delta-like ligand 4 (DLL4) expression has been studied in various cell populations, its expression in neutrophils and impact on inflammation remain unknown. Here, we discovered that eCIRP induces DLL4+ neutrophils. These neutrophils trigger PANoptosis, a novel proinflammatory form of cell death initiated by Z-DNA–binding protein-1 (ZBP1) in pulmonary vascular endothelial cells (PVECs). In sepsis, DLL4+ neutrophils increase in the blood and lungs, upregulating ZBP1, cleaved gasdermin D, cleaved caspase-3, and phosphorylated MLKL, all of which are markers of PANoptosis, exacerbating ALI. DLL4 binds to Notch1 on PVECs and activates Notch1 intracellular domain to increase ZBP1-mediated endothelial PANoptosis. We discovered what we believe to be a novel Notch1-DLL4 inhibitor (NDI), derived from Notch1 to specifically block this interaction. Our findings reveal that NDI reduced endothelial PANoptosis in vitro and in vivo, attenuated pulmonary injury induced by DLL4+ neutrophils, and decreased lung water content and permeability, indicating improved barrier function. NDI also reduced serum injury and inflammatory markers and improved survival rate in sepsis. These findings underscore the Notch1-DLL4 pathway’s critical role in DLL4+ neutrophil–mediated ALI. Targeting the Notch1-DLL4 interaction with an NDI represents a promising therapeutic strategy for sepsis-induced ALI.

Authors

Hui Jin, Saoirse Holland, Alok Jha, Gaifeng Ma, Jingsong Li, Atsushi Murao, Monowar Aziz, Ping Wang

Targeting kinesin family member 20A sensitizes stem-like triple-negative breast cancer cells to standard chemotherapy

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Triple-negative breast cancer (TNBC), being both aggressive and highly lethal, poses a major clinical challenge in terms of treatment. Its heterogeneity and lack of hormone receptors or HER2 expression further restrict the availability of targeted therapy. Breast cancer stem cells (BCSCs), known to fuel TNBC malignancy, are now being exploited as a vulnerability for TNBC treatment. Here, we dissected the transcriptome of BCSCs and identified kinesin family member 20A (KIF20A) as a key regulator of BCSC survival and TNBC tumorigenesis. Genetic depletion or pharmacological inhibition of KIF20A impairs BCSC viability and tumor initiation and development in vitro and in vivo. Mechanistically, KIF20A supports BCSC stemness through modulation of mitochondrial oxidative phosphorylation, which is repressed by SMARCA4, a component of the SWI/SNF chromatin remodeling complex. Therapeutically, KIF20A inhibition sensitizes TNBC xenografts to standard-of-care chemotherapy. Our study highlights the importance of targeting KIF20A to exploit BCSC vulnerabilities in TNBC.

Authors

Yayoi Adachi, Weilong Chen, Cheng Zhang, Tao Wang, Nina Gildor, Rachel Shi, Haoyong Fu, Masashi Takeda, Qian Liang, Fangzhou Zhao, Hongyi Liu, Jun Fang, Jin Zhou, Hongwei Yao, Lianxin Hu, Shina Li, Lei Guo, Lin Xu, Ling Xie, Xian Chen, Chengheng Liao, Qing Zhang

Estimation of prevalence of autoimmune diseases in the United States using electronic health record data

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Abstract

BACKGROUND Previous epidemiologic studies of autoimmune diseases in the US have included a limited number of diseases or used metaanalyses that rely on different data collection methods and analyses for each disease.METHODS To estimate the prevalence of autoimmune diseases in the US, we used electronic health record data from 6 large medical systems in the US. We developed a software program using common methodology to compute the estimated prevalence of autoimmune diseases alone and in aggregate that can be readily used by other investigators to replicate or modify the analysis over time.RESULTS Our findings indicate that over 15 million people, or 4.6% of the US population, have been diagnosed with at least 1 autoimmune disease from January 1, 2011, to June 1, 2022, and 34% of those are diagnosed with more than 1 autoimmune disease. As expected, females (63% of those with autoimmune disease) were almost twice as likely as males to be diagnosed with an autoimmune disease. We identified the top 20 autoimmune diseases based on prevalence and according to sex and age.CONCLUSION Here, we provide, for what we believe to be the first time, a large-scale prevalence estimate of autoimmune disease in the US by sex and age.FUNDING Autoimmune Registry Inc., the National Heart Lung and Blood Institute, the National Center for Advancing Translational Sciences, the Intramural Research Program of the National Institute of Environmental Health Sciences.

Authors

Aaron H. Abend, Ingrid He, Neil Bahroos, Stratos Christianakis, Ashley B. Crew, Leanna M. Wise, Gloria P. Lipori, Xing He, Shawn N. Murphy, Christopher D. Herrick, Jagannadha Avasarala, Mark G. Weiner, Jacob S. Zelko, Erica Matute-Arcos, Mark Abajian, Philip R.O. Payne, Albert M. Lai, Heath A. Davis, Asher A. Hoberg, Chris E. Ortman, Amit D. Gode, Bradley W. Taylor, Kristen I. Osinski, Damian N. Di Florio, Noel R. Rose, Frederick W. Miller, George C. Tsokos, DeLisa Fairweather

S100a9 lactylation triggers neutrophil trafficking and cardiac inflammation in myocardial ischemia/reperfusion injury

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Abstract

Lactylation, a posttranslational modification derived from glycolysis, plays a pivotal role in ischemic heart disease. Neutrophils are predominantly glycolytic cells that trigger intensive inflammation of myocardial ischemia/reperfusion (MI/R). However, whether lactylation regulates neutrophil function during MI/R remains unknown. We applied lactyl proteomics analysis and found that S100a9 was lactylated at lysine 26 (S100a9K26la) in neutrophils, with elevated levels observed in both patients with acute myocardial infarction (AMI) and MI/R model mice. We demonstrated that S100a9K26la drove the development of MI/R using mutant knockin mice. Mechanistically, lactylated S100a9 translocated to the nucleus of neutrophils, where it bound to the promoters of migration-related genes, thereby enhancing their transcription as a coactivator and promoting neutrophil migration and cardiac recruitment. Additionally, lactylated S100a9 was released during neutrophil extracellular trap (NET) formation, leading to cardiomyocyte death by disrupting mitochondrial function. The enzyme dihydrolipoyllysine-residue acetyltransferase (DLAT) was identified as the lactyltransferase facilitating neutrophil S100a9K26la following MI/R, a process that could be restrained by α-lipoic acid. Consistently, we found that targeting the DLAT/S100a9K26la axis suppressed neutrophil burden and improved cardiac function following MI/R. In patients with AMI, elevated S100a9K26la levels in plasma were positively correlated with cardiac death. These findings highlight S100a9 lactylation as a potential therapeutic target for MI/R and as a promising biomarker for evaluating poor MI/R outcomes.

Authors

Xiaoqi Wang, Xiangyu Yan, Ge Mang, Yujia Chen, Shuang Liu, Jiayu Sui, Zhonghua Tong, Penghe Wang, Jingxuan Cui, Qiannan Yang, Yafei Zhang, Dongni Wang, Ping Sun, Weijun Song, Zexi Jin, Ming Shi, Peng Zhao, Jia Yang, Mingyang Liu, Naixin Wang, Tao Chen, Yong Ji, Bo Yu, Maomao Zhang

Auranofin attenuates TOPBP1-mediated ATR replication stress response and improves chemotherapeutic response in breast tumor models

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Abstract

Genome instability is most commonly caused by replication stress, which also renders cancer cells extremely vulnerable once their response to replication stress is impeded. Topoisomerase II binding protein 1 (TOPBP1), an allosteric activator of ataxia telangiectasia and Rad3-related kinase (ATR), coordinates ATR in replication stress response and has emerged as a potential therapeutic target for tumors. Here, we identify auranofin, the FDA-approved drug for rheumatoid arthritis, as a lead compound capable of binding to the BRCT 7–8 domains and blocking TOPBP1 interaction with PHF8 and FANCJ. The liquid-liquid phase separation of TOPBP1 is also disrupted by auranofin. Through targeting these TOPBP1-nucleated molecular machineries, auranofin leads to an accumulation of replication defects by impairing ATR activation and attenuating replication protein A loading on perturbed replication forks, and it shows significant anti–breast tumor activity in combination with a PARP inhibitor. This study provides mechanistic insights into how auranofin challenges replication integrity and expands the application of this FDA-approved drug in breast tumor intervention.

Authors

Shuai Ma, Yingying Han, Rui Gu, Qi Chen, Qiushi Guo, Yuan Yue, Cheng Cao, Ling Liu, Zhenzhen Yang, Yan Qin, Ying Yang, Kai Zhang, Fei Liu, Lin Liu, Na Yang, Jihui Hao, Jie Yang, Zhi Yao, Xiaoyun Mao, Lei Shi

Interlocking host and viral cis-regulatory networks drive Merkel cell carcinoma

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Abstract

Over 15% of cancers worldwide are caused by viruses. Merkel cell polyomavirus (MCPyV) is the most recently discovered human oncovirus and is the only polyomavirus that drives malignant tumors in humans. Here, we show that MCPyV+ Merkel cell carcinoma is defined by neuroendocrine-lineage core regulatory (CR) transcription factors (TFs) (ATOH1, INSM1, ISL1, LHX3, POU4F3, and SOX2) that were essential for tumor survival and that co-bound chromatin with the viral small T antigen at super enhancers. Moreover, MCPyV integration sites were enriched at these neuroendocrine super enhancers. We further discovered that the MCPyV noncoding control region contained a homeodomain binding motif absent in other polyomaviruses that bound ISL1 and LHX3 and depended on them for T antigen expression. To therapeutically target the CR factors, we used histone deacetylase (HDAC) inhibitors to collapse the chromatin architecture and induce topological blurring of superenhancer loops, abrogating core TF expression and halting tumor growth. To our knowledge, our study presents the first example of oncogenic cross-regulation between viral and human epigenomic circuitry to generate interlocking and essential transcriptional feedback circuits that explain why MCPyV causes neuroendocrine cancer and represent a tumor dependency that can be targeted therapeutically.

Authors

Lingling Miao, David Milewski, Amy Coxon, Tara Gelb, Khalid A. Garman, Jadon Porch, Arushi Khanna, Loren Collado, Natasha T. Hill, Kenneth Daily, Serena Vilasi, Danielle Reed, Tiffany Alexander, Gabriel J. Starrett, Maharshi Chakraborty, Young Song, Rachel Choi, Vineela Gangalapudi, Josiah Seaman, Andrew Morton, Klaus J. Busam, Christopher R. Vakoc, Daniel J. Urban, Min Shen, Matthew D. Hall, Richard Sallari, Javed Khan, Berkley E. Gryder, Isaac Brownell

Mitochondrial complex II orchestrates divergent effects in CD4⁺ and CD8⁺ T cells

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Abstract

Mitochondrial metabolism orchestrates T cell functions, yet the role of specific mitochondrial components in distinct T cell subsets remains poorly understood. Here, we explored the role of mitochondrial complex II (MC II), the only complex from the electron transport chain (ETC) that plays a role in both ETC and metabolism, in regulating T cell functions. Surprisingly, MC II exerts divergent effects on CD4+ and CD8+ T cell activation and function. Using T cell–specific MC II subunit, succinate dehydrogenase A–deficient (SDHA-deficient) mice, we integrated single-cell RNA-seq and metabolic profiling, with in vitro and in vivo T cell functional assays to illuminate these differences. SDHA deficiency induced metabolic changes and remodeled gene expression exclusively in activated T cells. In CD4+ T cells, SDHA loss dampened both oxidative phosphorylation (OXPHOS) and glycolysis, impaired cytokine production, proliferation, and reduced CD4+ T cell–mediated graft-versus-host disease after allogeneic stem cell transplantation (SCT). In contrast, SDHA deficiency in CD8+ T cells reduced OXPHOS but paradoxically upregulated glycolysis and demonstrated enhanced cytotoxic functions in vitro and in vivo. This metabolic reprogramming endowed SDHA-KO CD8+ T cells with superior in vivo antitumor efficacy after immune checkpoint inhibitor therapy and allogeneic SCT. These findings reveal MC II as a bifurcation point for metabolic and functional specialization in CD4+ and CD8+ T cells.

Authors

Keisuke Seike, Shih-Chun A. Chu, Yuichi Sumii, Takashi Ikeda, Meng-Chih Wu, Laure Maneix, Dongchang Zhao, Yaping Sun, Marcin Cieslik, Pavan Reddy