Age-dependent genes in adipose stem and precursor cells affect regulation of fat cell differentiation and link aging to obesity via cellular and genetic interactions

IF 10.4 1区 生物学 Q1 GENETICS & HEREDITY Genome Medicine Pub Date : 2024-01-31 DOI:10.1186/s13073-024-01291-x
Asha Kar, Marcus Alvarez, Kristina M. Garske, Huiling Huang, Seung Hyuk T. Lee, Milena Deal, Sankha Subhra Das, Amogha Koka, Zoeb Jamal, Karen L. Mohlke, Markku Laakso, Sini Heinonen, Kirsi H. Pietiläinen, Päivi Pajukanta
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Abstract

Age and obesity are dominant risk factors for several common cardiometabolic disorders, and both are known to impair adipose tissue function. However, the underlying cellular and genetic factors linking aging and obesity on adipose tissue function have remained elusive. Adipose stem and precursor cells (ASPCs) are an understudied, yet crucial adipose cell type due to their deterministic adipocyte differentiation potential, which impacts the capacity to store fat in a metabolically healthy manner. We integrated subcutaneous adipose tissue (SAT) bulk (n=435) and large single-nucleus RNA sequencing (n=105) data with the UK Biobank (UKB) (n=391,701) data to study age-obesity interactions originating from ASPCs by performing cell-type decomposition, differential expression testing, cell-cell communication analyses, and construction of polygenic risk scores for body mass index (BMI). We found that the SAT ASPC proportions significantly decrease with age in an obesity-dependent way consistently in two independent cohorts, both showing that the age dependency of ASPC proportions is abolished by obesity. We further identified 76 genes (72 SAT ASPC marker genes and 4 transcription factors regulating ASPC marker genes) that are differentially expressed by age in SAT and functionally enriched for developmental processes and adipocyte differentiation (i.e., adipogenesis). The 76 age-perturbed ASPC genes include multiple negative regulators of adipogenesis, such as RORA, SMAD3, TWIST2, and ZNF521, form tight clusters of longitudinally co-expressed genes during human adipogenesis, and show age-based differences in cellular interactions between ASPCs and adipose cell types. Finally, our genetic data demonstrate that cis-regional variants of these genes interact with age as predictors of BMI in an obesity-dependent way in the large UKB, while no such gene-age interaction on BMI is observed with non-age-dependent ASPC marker genes, thus independently confirming our cellular ASPC results at the biobank level. Overall, we discover that obesity prematurely induces a decrease in ASPC proportions and identify 76 developmentally important ASPC genes that implicate altered negative regulation of fat cell differentiation as a mechanism for aging and directly link aging to obesity via significant cellular and genetic interactions.
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脂肪干细胞和前体细胞中与年龄有关的基因影响脂肪细胞分化的调控,并通过细胞和基因的相互作用将衰老与肥胖联系起来
年龄和肥胖是几种常见的心脏代谢疾病的主要风险因素,而这两种因素都会损害脂肪组织的功能。然而,将衰老和肥胖与脂肪组织功能联系在一起的潜在细胞和遗传因素仍然难以捉摸。脂肪干细胞和前体细胞(ASPCs)是一种未被充分研究但却至关重要的脂肪细胞类型,因为它们具有决定性的脂肪细胞分化潜能,这影响了以代谢健康的方式储存脂肪的能力。我们整合了皮下脂肪组织(SAT)批量(n=435)和大单核 RNA 测序(n=105)数据以及英国生物库(UKB)(n=391,701)数据,通过细胞类型分解、差异表达测试、细胞-细胞通讯分析以及构建体重指数(BMI)多基因风险评分,研究了源自 ASPC 的年龄-肥胖相互作用。我们发现,在两个独立的队列中,SAT ASPC 的比例随着年龄的增长而显著下降,其方式始终与肥胖有关,这两个队列都表明 ASPC 比例的年龄依赖性被肥胖所取消。我们进一步确定了 76 个基因(72 个 SAT ASPC 标记基因和 4 个调控 ASPC 标记基因的转录因子),这些基因在 SAT 中随年龄的变化而有不同的表达,并在发育过程和脂肪细胞分化(即脂肪生成)方面有功能富集。这 76 个受年龄干扰的 ASPC 基因包括多个脂肪生成的负调控因子,如 RORA、SMAD3、TWIST2 和 ZNF521,形成了人类脂肪生成过程中纵向共表达基因的紧密簇,并显示了 ASPC 与脂肪细胞类型之间基于年龄的细胞相互作用差异。最后,我们的遗传学数据表明,这些基因的顺式区域变异与年龄相互作用,成为英国大样本库中肥胖依赖的 BMI 预测因子,而非年龄依赖的 ASPC 标记基因则没有观察到这种基因与年龄对 BMI 的相互作用,从而在生物样本库水平上独立证实了我们的细胞 ASPC 结果。总之,我们发现肥胖过早地诱导了 ASPC 比例的下降,并确定了 76 个对发育非常重要的 ASPC 基因,这些基因暗示脂肪细胞分化负调控的改变是衰老的一种机制,并通过显著的细胞和遗传相互作用将衰老与肥胖直接联系起来。
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来源期刊
Genome Medicine
Genome Medicine GENETICS & HEREDITY-
CiteScore
20.80
自引率
0.80%
发文量
128
审稿时长
6-12 weeks
期刊介绍: Genome Medicine is an open access journal that publishes outstanding research applying genetics, genomics, and multi-omics to understand, diagnose, and treat disease. Bridging basic science and clinical research, it covers areas such as cancer genomics, immuno-oncology, immunogenomics, infectious disease, microbiome, neurogenomics, systems medicine, clinical genomics, gene therapies, precision medicine, and clinical trials. The journal publishes original research, methods, software, and reviews to serve authors and promote broad interest and importance in the field.
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