[ad_1]
Figure 1: Rubicon levels in fat tissue of mice decrease with age. (Mouse adipose tissue) The abundance of Rubicon in adipose tissue of 25 month old mice was significantly reduced compared to that of 3 month old mice. Levels of an autophagic substrate, p62, also decreased with age, suggesting that autophagy increases with age. Β-actin was used as a protein control. Credit: Osaka University
No matter how hard we try to fight it, aging is a part of life. High cholesterol, diabetes and fatty liver disease, all of the conditions called lifestyle diseases, become more and more common as we age. Interestingly, however, many of these age-related conditions are caused by changes inside adipocytes, the fat cells responsible for storing excess energy.
Now, in a study published in Nature’s communications, researchers led by Osaka University have discovered exactly how these changes lead to the onset of lifestyle-related diseases, in an attempt to reverse the process.
“Adipocytes produce hormones and cytokines that regulate the function of other metabolic organs,” says lead author Tadashi Yamamuro. “Age-related changes in adipose tissue lead to metabolic disturbances closely associated with life-threatening cardiovascular disease. However, no one really knows what causes adipocyte dysfunction in aging organisms.”
The research team decided to focus on autophagy, the process used by cells to remove unwanted or dysfunctional cellular components. Previous studies had shown that autophagy plays an important role in the prevention of various age-related disorders and is likely to be involved in the aging process. But most relevant was the finding that autophagy is essential for the normal function and longevity of normal organs, like the liver or kidneys.
Figure 2 Removal of Rubicon from adipose tissue results in leanness and glucose intolerance. The left panel shows the body weight of mice aged 5 to 21 months. Compared to controls, adipose-specific Rubicon knockout mice exhibited a leaner phenotype. The right panel shows the blood glucose levels of the mouse after the glucose injection. Compared to controls, adipose-specific Rubicon knockout mice exhibited higher glucose levels, suggesting glucose intolerance. Credit: Osaka University
According to Yamamuro, “We previously showed that a protein called Rubicon, which inhibits autophagy, is upregulated in aging tissue. We therefore hypothesized that Rubicon likely accumulates in aged fat cells, decreasing autophagic activity and contributing to the development of metabolic disorders. “
Surprisingly, however, the researchers found that Rubicon levels were actually lowered in the fatty tissue of elderly mice, which resulted in increased autophagic activity.
To explore the underlying mechanism, the researchers developed a mouse line in which Rubicon was specifically inactivated in adipose tissue.
“In the absence of Rubicon, we observed excessive autophagy in adipocytes and decreased adipocyte function,” explains lead author Tamotsu Yoshimori. “As a result, the mice developed lifestyle-related diseases such as diabetes and fatty liver disease and had significantly higher cholesterol levels, despite the same diet as the control animals.”
Figure 3: The proposed mechanism of the aging of adipose tissue. The rubicon in fatty tissue decreases with age, leading to excess autophagy. Excessive autophagy degrades the coactivators of PPARγ SRC-1 and TIF2, causing a decrease in PPARγ activity and adipocyte function and the development of lifestyle-related diseases. Credit: Osaka University
The researchers then identified the specific proteins affected by the increased levels of autophagy, showing that supplementation of these proteins in Rubicon deletion mice restored adipocyte function.
“This is a truly exciting discovery with important therapeutic implications,” says Yoshimori. “Because age-related loss of Fat Rubicon causes lifestyle-related diseases via excessive autophagy, inhibition of autophagy in fat cells may help prevent the onset of these prevalent and potentially deadly. ”
The key to increased lifespan? Rubicon impairs autophagy in animals during aging
Yamamuro et al., Rubicon fat loss as a function of age promotes metabolic disturbances via excess autophagy, Nature’s communications (2020). 10.1038 / s41467-020-17985-w
Provided by Osaka University
Quote: How Turning Back Time In Aging Fat Cells May Be A Cure For Lifestyle-Related Diseases (August 18, 2020) Retrieved August 18, 2020 from https://phys.org/news/2020-08-clock- aging-fat-cells- remedy.html
This document is subject to copyright. Other than fair use for private study or research purposes, no part may be reproduced without written permission. The content is provided for information only.
[ad_2]
Source link