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- Hägg, Daniel, 1974, et al.
(författare)
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Osteoblast-lineage cells regulate metabolism and fat mass
- 2023
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Ingår i: Current Opinion in Endocrine and Metabolic Research. - 2451-9650. ; 31
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Forskningsöversikt (refereegranskat)abstract
- As energy depots in many circumstances have been limited during evolution, it is necessary to prioritize how to manage energy resources. In this review we summarize data from the last 15 years indicating that osteoblast-lineage cells are regulators of whole-body energy metabolism and fat mass. We focus mainly on three factors, osteocalcin, lipocalin-2 and sclerostin, that are released by osteoblast-lineage cells and proposed to exert endocrine effects on metabolism. In addition, we present a hypothesis on why osteoblast-lineage cells during evolution have developed a function to regulate metabolism and fat mass. We propose that osteoblast-lineage cells through the osteocyte network in bone are sensors of gravitational forces induced by body mass and gravity on land-living species. By sensing the body weight, the osteoblastlineage cells may then feed-back this information on the whole-body nutritional status via osteoblast-derived endocrine factors or via the nervous system to regulate energy metabolism and fat mass.
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| 2. |
- Jansson, John-Olov, 1954, et al.
(författare)
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The dual hypothesis of homeostatic body weight regulation, including gravity-dependent and leptin-dependent actions.
- 2023
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Ingår i: Philosophical transactions of the Royal Society of London. Series B, Biological sciences. - 1471-2970. ; 378:1888
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Forskningsöversikt (refereegranskat)abstract
- Body weight is tightly regulated when outside the normal range. It has been proposed that there are individual-specific lower and upper intervention points for when the homeostatic regulation of body weight is initiated. The nature of the homeostatic mechanisms regulating body weight at the lower and upper ends of the body weight spectrum might differ. Previous studies demonstrate that leptin is the main regulator of body weight at the lower end of the body weight spectrum. We have proposed that land-living animals use gravity to regulate their body weight. We named this homeostatic system the gravitostat and proposed that there are two components of the gravitostat. First, an obvious mechanism involves increased energy consumption in relation to body weight when working against gravity on land. In addition, we propose that there exists a component, involving sensing of the body weight by osteocytes in the weight-bearing bones, resulting in a feedback regulation of energy metabolism and body weight. The gravity-dependent homeostatic regulation is mainly active in obese mice. We, herein, propose the dual hypothesis of body weight regulation, including gravity-dependent actions (= gravitostat) at the upper end and leptin-dependent actions at the lower end of the body weight spectrum. This article is part of a discussion meeting issue 'Causes of obesity: theories, conjectures and evidence (Part II)'.
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| 3. |
- Smith, Ulf, 1943, et al.
(författare)
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Insulin signaling and action in fat cells: associations with insulin resistance and type 2 diabetes.
- 1999
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Ingår i: Annals of the New York Academy of Sciences. - 0077-8923. ; 892, s. 119-26
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Forskningsöversikt (refereegranskat)abstract
- Adipose tissue only accounts for a relatively small proportion (< 10%) of the peripheral glucose utilization in response to insulin. However, the fat cells may still play an important role in insulin resistance and Syndrome X through, for instance, its endocrine functions (production of leptin, TNF alpha, PAI-1, etc.) and involvement in lipid metabolism (FFA release and hydrolysis of triglycerides). The fat cells are also highly sensitive to insulin and may thus be used to elucidate molecular mechanisms for insulin resistance in man. Examinations of the intracellular signaling mechanisms for insulin in fat cells from individuals with Type 2 diabetes revealed markedly lower insulin-stimulated PI3-kinase activity. This was due to a pronounced reduction in the cellular expression of the docking protein, IRS 1, whereas expression of IRS 2 was normal. However, IRS 2-associated PI3-kinase activity was only approximately one-third of that found to be associated with IRS 1 in normal cells. Downstream activation and serine phosphorylation of PKB/Akt by insulin were also markedly reduced in Type 2 diabetes. Furthermore, the dose-response curve for this effect of insulin was similar to that for glucose transport in both normal and Type 2 diabetic cells. Thus, these data show that both PI3-kinase and PKB activation by insulin are markedly reduced in Type 2 diabetes. We also examined whether an attenuated activation of PI3-kinase by insulin can be seen in non-diabetic insulin-resistant states. Approximately 30% of healthy subjects with at least two first-degree relatives with Type 2 diabetes exhibited perturbations in IRS-1 expression and signaling. These individuals were characterized by insulin resistance as well as other markers of Syndrome X. Thus, impaired IRS-1 expression and downstream signaling events in fat cells in response to insulin are associated with insulin resistance and Syndrome X.
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