Cellular Senescence in Diabetes Mellitus: Distinct Senotherapeutic Strategies for Adipose Tissue and Pancreatic β Cells.
Study Goal
The researchers aimed to explore the role of cellular senescence in high-fat-diet-induced diabetes and obesity, focusing on its impact on insulin resistance and β-cell dysfunction.
Results Summary
The study found that high-fat diets contribute to cellular senescence, leading to dysfunctional adipose tissues and impaired insulin secretion, exacerbating diabetes. Senescent cells exhibit a proinflammatory phenotype (SASP), which negatively affects metabolic health.
Population
Mouse models with high-fat-diet-induced obesity and diabetes.
Effective Dosage
Not specified
Duration
Not specified
Interactions
None mentioned
| Intervention | Direction | Endpoint | Population | Dosage | Impact | Claim # |
|---|---|---|---|---|---|---|
obesity | increase | insulin resistance | patients with type 2 diabetes mellitus | - | accelerated | #1 |
aging | increase | T2DM | - | - | significantly affected | #2 |
aging | decrease | β-cell mass | - | - | diminishes | #3 |
obesity and hyperglycemia-related metabolic changes | increase | senescent cells | multiple organs | - | associated with accumulation | #4 |
senescent cells | increase | proinflammatory cytokines and chemokines | - | - | secrete | #5 |
senescence-associated secretory phenotype (SASP) | decrease | adipose tissues and pancreatic β-cells | - | - | has a negative impact | #6 |
senolysis | decrease | aging-related diseases, including diabetes | - | - | can be a promising therapeutic approach to prevent or improve | #7 |
attenuation of a SASP | neutral | - | - | - | may be beneficial | #8 |
high-fat-diet | increase | diabetes with obesity | mouse | - | induced | #9 |
high-fat-diet induced diabetes with obesity | increase | adipose tissues | mouse | - | display accumulation | #10 |
Increased insulin resistance and impaired insulin secretion are significant characteristics manifested by patients with type 2 diabetes mellitus (T2DM). The degree and extent of these two features in T2DM vary among races and individuals. Insulin resistance is accelerated by obesity and is accompanied by accumulation of dysfunctional adipose tissues. In addition, dysfunction of pancreatic β-cells impairs insulin secretion. T2DM is significantly affected by aging, as the β-cell mass diminishes with age. Moreover, both obesity and hyperglycemia-related metabolic changes in developing diabetes are associated with accumulation of senescent cells in multiple organs, that is, organismal aging. Cellular senescence is defined as a state of irreversible cell cycle arrest with concomitant functional decline. It is caused by telomere shortening or senescence-inducing stress. Senescent cells secrete proinflammatory cytokines and chemokines, which is designated as the senescence-associated secretory phenotype (SASP), and this has a negative impact on adipose tissues and pancreatic β-cells. Recent advances in aging research have suggested that senolysis, the removal of senescent cells, can be a promising therapeutic approach to prevent or improve aging-related diseases, including diabetes. The attenuation of a SASP may be beneficial, although the pathophysiological involvement of cellular senescence in diabetes is not fully understood. In the clinical application of senotherapy, tissue-context-dependent senescent cells are increasingly being recognized as an issue to be solved. Recent studies have observed highly heterogenic and complex senescent cell populations that serve distinct roles among tissues, various stages of disease, and different ages. For example, in high-fat-diet induced diabetes with obesity, mouse adipose tissues display accumulation of