Your search keyword '"Sakaguchi, Masaji"' showing total 4 results

1. Adipose Tissue Plasticity and Insulin Signaling in the Pathogenesis of Type 2 Diabetes

Author

Sakaguchi, Masaji

Published

2024

2. Hepatic SerpinA1 improves energy and glucose metabolism through regulation of preadipocyte proliferation and UCP1 expression.

Author

Okagawa, Shota, Sakaguchi, Masaji, Okubo, Yuma, Takekuma, Yuri, Igata, Motoyuki, Kondo, Tatsuya, Takeda, Naoki, Araki, Kimi, Brandao, Bruna Brasil, Qian, Wei-Jun, Tseng, Yu-Hua, Kulkarni, Rohit N., Kubota, Naoto, Kahn, C. Ronald, and Araki, Eiichi

Abstract

Lipodystrophy and obesity are associated with insulin resistance and metabolic syndrome accompanied by fat tissue dysregulation. Here, we show that serine protease inhibitor A1 (SerpinA1) expression in the liver is increased during recovery from lipodystrophy caused by the adipocyte-specific loss of insulin signaling in mice. SerpinA1 induces the proliferation of white and brown preadipocytes and increases the expression of uncoupling protein 1 (UCP1) to promote mitochondrial activation in mature white and brown adipocytes. Liver-specific SerpinA1 transgenic mice exhibit increased browning of adipose tissues, leading to increased energy expenditure, reduced adiposity and improved glucose tolerance. Conversely, SerpinA1 knockout mice exhibit decreased adipocyte mitochondrial function, impaired thermogenesis, obesity, and systemic insulin resistance. SerpinA1 forms a complex with the Eph receptor B2 and regulates its downstream signaling in adipocytes. These results demonstrate that SerpinA1 is an important hepatokine that improves obesity, energy expenditure and glucose metabolism by promoting preadipocyte proliferation and activating mitochondrial UCP1 expression in adipocytes. Lipodystrophy and obesity are associated with insulin resistance and metabolic syndrome accompanied by fat tissue dysregulation. Here, the authors show that SerpinA1, secreted from the liver, activates mitochondrial UCP1 expression through interaction with EphB2 in adipocytes, contributing to increased energy expenditure, improved glucose metabolism and reduced obesity. [ABSTRACT FROM AUTHOR]

Published

2024

3. The role of insulin signaling with FOXO and FOXK transcription factors.

Author

Sakaguchi M

Subjects

Humans, Animals, Insulin Resistance physiology, Receptor, Insulin metabolism, Signal Transduction physiology, Insulin metabolism, Forkhead Transcription Factors metabolism, Forkhead Transcription Factors physiology

Abstract

Insulin is an essential hormone for animal activity and survival, and it controls the metabolic functions of the entire body. Throughout the evolution of metazoan animals and the development of their brains, a sustainable energy supply has been essential to overcoming the competition for survival under various environmental stresses. Managing energy for metabolism, preservation, and consumption inevitably involves high oxidative stress, causing tissue damage in various organs. In both mice and humans, excessive dietary intake can lead to insulin resistance in various organs, ultimately displaying metabolic syndrome and type 2 diabetes. Insulin signals require thorough regulation to maintain metabolism across diverse environments. Recent studies demonstrated that two types of forkhead-box family transcription factors, FOXOs and FOXKs, are related to the switching of insulin signals during fasting and feeding states. Insulin signaling plays a role in supporting higher activity during periods of sufficient food supply and in promoting survival during times of insufficient food supply. The insulin receptor depends on the tyrosine phosphatase feedback of insulin signaling to maintain adipocyte insulin responsiveness. α4, a regulatory subunit of protein phosphatase 2A (PP2A), has been shown to play a crucial role in modulating insulin signaling pathways by regulating the phosphorylation status of key proteins involved in these pathways. This short review summarizes the current understanding of the molecular mechanism related to the regulation of insulin signals.

Published

2024

4. Adipose Tissue Dynamics, Thermogenesis, and Interorgan Connections for Preventing Obesity and Metabolic Disorders.

Author

Sakaguchi M

Abstract

Adipose tissues, such as white, brown, and beige tissues, play pivotal roles in maintaining energy balance and metabolic health. Whereas white adipocytes store energy, brown and beige adipocytes exhibit high energy expenditure owing to their distinct mitochondrial density and UCP1 expression. Dysfunction in these tissues contributes to metabolic disorders such as type 2 diabetes and cardiovascular diseases. Adipose tissue expansion through cell enlargement or increased cell numbers caused by excess energy storage in white adipocytes substantially influences metabolic health. In obesity, hypertrophic adipocytes trigger inflammation, fibrosis, and hypoxia, whereas smaller adipocytes exert favorable metabolic effects, contributing to insulin sensitivity. Brown and beige adipocytes consume energy for thermogenesis to maintain body temperature, contributing to metabolic homeostasis. The intricate interactions between brown adipose tissues and various organs, such as the liver and heart, highlight the systemic implications of adipose tissue functions. Understanding the complex underlying mechanisms may lead to the development of innovative therapies targeting metabolic disorders by modulating the functions of brown adipose tissue and its interactions with other physiological systems. In this review, we discuss insights into the mechanisms underlying the dysregulation of metabolism owing to abnormalities in adipose tissue remodeling. We focus on the endocrine functions of thermogenic brown and beige adipocytes and explore the interorgan interactions that influence whole-body metabolism., Competing Interests: None, (Copyright © Japan Medical Association.)

Published

2024