| Abstract: | Adipocytes are embedded in a unique extracellular matrix whose main function is to provide mechanical support, in addition to participating in a variety of signaling events. During adipose tissue expansion, the extracellular matrix requires remodeling to accommodate adipocyte growth. Here, we demonstrate a general upregulation of several extracellular matrix components in adipose tissue in the diabetic state, therefore implicating “adipose tissue fibrosis” as a hallmark of metabolically challenged adipocytes. Collagen VI is a highly enriched extracellular matrix component of adipose tissue. The absence of collagen VI results in the uninhibited expansion of individual adipocytes and is paradoxically associated with substantial improvements in whole-body energy homeostasis, both with high-fat diet exposure and in the ob/ob background. Collectively, our data suggest that weakening the extracellular scaffold of adipocytes enables their stress-free expansion during states of positive energy balance, which is consequently associated with an improved inflammatory profile. Therefore, the disproportionate accumulation of extracellular matrix components in adipose tissue may not be merely an epiphenomenon of metabolically challenging conditions but may also directly contribute to a failure to expand adipose tissue mass during states of excess caloric intake.Adipose tissue is a key regulator of systemic energy homeostasis. The physiological state of adipose tissue is driven by cell-autonomous processes within the adipocyte. In addition to this, the adipocyte itself is subject to major modifications by other cell types that infiltrate adipose tissue, such as macrophages and vascular cells; moreover, adipocytes can be markedly influenced by several hormones and cytokines that circulate systemically.Although all these cellular interactions have been the subject of extensive studies in numerous laboratories, the extracellular matrix of adipose tissue has received limited attention to date, despite evidence suggesting that it is a functionally relevant constituent of adipose tissue physiology.It is currently unknown what consequential effects metabolic stress exerts on the extracellular matrix and vice versa. In other words, what is the impact of dysregulation of the extracellular constituents of adipose tissue on the systemic metabolic state? Here, we approach this subject from two different perspectives. We first assessed the overall level of extracellular matrix components under different metabolic conditions and established that the extracellular constituents are globally upregulated during metabolically challenging conditions. We then selected a specific member of the collagen family, collagen VI (exhibiting predominant expression in adipose tissue), and utilized a genetic model of collagen VI disruption to investigate the effects of disruption of the extracellular matrix of adipose tissue. Remarkably, our studies demonstrated that such weakening of adipose tissue extracellular matrix results in considerable improvement of the metabolic phenotype in the context of both a high-fat diet and a challenge with the ob/ob mutation.Our observations highlight the extracellular matrix of adipose tissue as an important and novel site of modulation of systemic metabolism. Obese adipose tissue displays hallmarks similar to other fibrotic tissues, such as the liver; this suggests that specific constituents of this normally rather rigid extracellular matrix environment may provide possible targets for pharmacological intervention for the treatment of metabolic disorders. |
