A role of arginase-1-expressing myeloid cells in cachexia.

IF 6 3区医学 Q1 CELL BIOLOGY

Cancer & Metabolism Pub Date : 2025-06-05 DOI:10.1186/s40170-025-00396-0

Lamsal Apsana, Andersen Sonja Benedikte, Nonstad Unni, Kurganovs Natalie Jayne, Skipworth Richard Je, Bjørkøy Geir, Pettersen Kristine

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引用次数: 0

Abstract

Background: Despite decades of efforts to find successful treatment approaches, cachexia remains a major unmet medical need. This condition, that affects patients with diverse underlying conditions, is characterized by severe muscle loss and is associated with reduced quality of life and limited survival. Search for underlying mechanisms that may guide cachexia treatment has mainly evolved around potential atrophy-inducing roles of inflammatory mediators, and in cancer patients, tumor-derived factors. Recently, a new paradigm emerged as it is becoming evident that specific immune cells inhabit atrophic muscle tissue. Arginase 1 (Arg1) expression is characteristic of these immune cells. Studies of potential contributions of these immune cells to loss of muscle mass and function is in its infancy, and the contribution of ARG1 to these processes remains elusive.

Methods: Analyses of RNA sequencing data from murine cachexia models and comprehensive, unbiased open approach proteomics analyses of skeletal myotubes was performed. In vitro techniques were employed to evaluate mitochondrial function and capacity in skeletal muscle cells and cardiomyocytes. Functional bioassays were used to measure autophagy activity. ARG1 level in patients' plasma was evaluated using ELISA, and the association between ARG1 level and patient survival, across multiple types of cancer, was examined using the online database Kaplan-Meier plotter.

Results: In line with arginine-degrading activity of ARG1, we found signs of arginine restriction in atrophic muscles. In response to arginine restriction, mitochondrial functions and ATP generation was severely compromised in both skeletal muscle cells and in cardiomyocytes. In skeletal muscle cells, arginine restriction enhanced the expression of autophagic proteins, suggesting autophagic degradation of cellular content. Reduction in mitochondria marker TIMM23 supports selective autophagic degradation of mitochondria (mitophagy). In arginine starved cardiomyocytes, mitochondrial dysfunction is accompanied by both increased bulk autophagy and mitophagy. In cancer patients, we found an association between ARG1 expression and accelerated weight loss and reduced survival, further supporting a role of ARG1-producing cells in cachexia pathogenesis.

Conclusion: Together, our findings point to a mechanism for cachexia which depends on expansion of ARG1-expressing myeloid cells, local restriction of arginine, loss of mitochondrial capacity and induced catabolism in skeletal muscle cells and in the heart.

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表达精氨酸酶-1的髓细胞在恶病质中的作用。

背景：尽管几十年来一直在努力寻找成功的治疗方法，但恶病质仍然是一个主要的未满足的医疗需求。这种情况会影响具有多种潜在疾病的患者，其特征是严重的肌肉损失，并与生活质量下降和生存期有限有关。对可能指导恶病质治疗的潜在机制的研究主要围绕炎症介质的潜在萎缩诱导作用以及癌症患者的肿瘤源性因素展开。最近，一种新的范式出现了，因为它越来越明显，特异性免疫细胞栖息在萎缩的肌肉组织。精氨酸酶1 （Arg1）的表达是这些免疫细胞的特征。关于这些免疫细胞对肌肉质量和功能丧失的潜在贡献的研究尚处于起步阶段，ARG1对这些过程的贡献仍然难以捉摸。方法：对小鼠恶病质模型的RNA测序数据进行分析，并对骨骼肌管进行全面、公正的开放方法蛋白质组学分析。采用体外技术评价骨骼肌细胞和心肌细胞的线粒体功能和容量。功能生物测定法测定自噬活性。采用ELISA法检测患者血浆中ARG1水平，并利用在线Kaplan-Meier绘图仪检测多种癌症患者血浆中ARG1水平与生存期之间的关系。结果：与ARG1的精氨酸降解活性一致，我们在萎缩肌肉中发现了精氨酸限制的迹象。作为精氨酸限制的反应，骨骼肌细胞和心肌细胞的线粒体功能和ATP生成严重受损。在骨骼肌细胞中，精氨酸限制增强了自噬蛋白的表达，表明细胞内容物发生了自噬降解。线粒体标志物TIMM23的减少支持线粒体的选择性自噬降解（mitophagy）。在精氨酸缺乏的心肌细胞中，线粒体功能障碍伴随着大量自噬和线粒体自噬的增加。在癌症患者中，我们发现ARG1表达与加速体重减轻和降低生存率之间存在关联，进一步支持ARG1产生细胞在恶病质发病机制中的作用。结论：总之，我们的研究结果指出恶病质的机制依赖于表达arg1的髓细胞的扩张、精氨酸的局部限制、线粒体能力的丧失以及骨骼肌细胞和心脏中诱导的分解代谢。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Cancer & Metabolism Multiple-

自引率

1.70%

发文量

审稿时长

14 weeks

期刊介绍： Cancer & Metabolism welcomes studies on all aspects of the relationship between cancer and metabolism, including: -Molecular biology and genetics of cancer metabolism -Whole-body metabolism, including diabetes and obesity, in relation to cancer -Metabolomics in relation to cancer; -Metabolism-based imaging -Preclinical and clinical studies of metabolism-related cancer therapies.