Michael A. Kalwat scite author profile

The maintenance of whole-body glucose homeostasis is critical for survival, and is controlled by the coordination of multiple organs and endocrine systems. Pancreatic islet β cells secrete insulin in response to nutrient stimuli, and insulin then travels through the circulation promoting glucose uptake into insulin-responsive tissues such as liver, skeletal muscle and adipose. Many of the genes identified in human genome-wide association studies of diabetic individuals are directly associated with β cell survival and function, giving credence to the idea that β-cell dysfunction is central to the development of type 2 diabetes. As such, investigations into the mechanisms by which β cells sense glucose and secrete insulin in a regulated manner are a major focus of current diabetes research. In particular, recent discoveries of the detailed role and requirements for reorganization/remodeling of filamentous actin (F-actin) in the regulation of insulin release from the β cell have appeared at the forefront of islet function research, having lapsed in prior years due to technical limitations. Recent advances in live-cell imaging and specialized reagents have revealed localized F-actin remodeling to be a requisite for the normal biphasic pattern of nutrient-stimulated insulin secretion. This review will provide an historical look at the emergent focus on the role of the actin cytoskeleton and its regulation of insulin secretion, leading up to the cutting-edge research in progress in the field today.

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Munc18c phosphorylation by the insulin receptor links cell signaling directly to SNARE exocytosis

Jewell

Ramalingam

et al. 2011

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Mechanisms of the amplifying pathway of insulin secretion in the β cell

Kalwat

Cobb

2017

Pharmacology & Therapeutics

127

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Pancreatic islet β cells secrete insulin in response to nutrient secretagogues, like glucose, dependent on calcium influx and nutrient metabolism. One of the most intriguing qualities of β cells is their ability to use metabolism to amplify the amount of secreted insulin independent of further alterations in intracellular calcium. Many years studying this amplifying process have shaped our current understanding of β cell stimulus-secretion coupling; yet, the exact mechanisms of amplification have been elusive. Recent studies utilizing metabolomics, computational modeling, and animal models have progressed our understanding of the metabolic amplifying pathway of insulin secretion from the β cell. New approaches will be discussed which offer in-roads to a more complete model of β cell function. The development of β cell therapeutics may be aided by such a model, facilitating the targeting of aspects of the metabolic amplifying pathway which are unique to the β cell.

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Munc18-1 Regulates First-phase Insulin Release by Promoting Granule Docking to Multiple Syntaxin Isoforms

Kalwat

Kim

et al. 2012

Journal of Biological Chemistry

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Background: Munc18-1 is expressed in islet ␤-cells, but its functional requirement remains unknown. Results: Munc18-1 knock-out mice have impaired glucose tolerance and first-phase insulin release defects. Munc18-1 overexpression enhances human islet insulin release and increases SNARE complex formation. Conclusion: Munc18-1 is required in insulin exocytosis for facilitating SNARE assembly using multiple syntaxin isoforms. Significance: Increased Munc18-1 in human islets enhances ␤-cell function.

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Michael A. Kalwat

Signaling mechanisms of glucose-induced F-actin remodeling in pancreatic islet β cells

Munc18c phosphorylation by the insulin receptor links cell signaling directly to SNARE exocytosis

Mechanisms of the amplifying pathway of insulin secretion in the β cell

Munc18-1 Regulates First-phase Insulin Release by Promoting Granule Docking to Multiple Syntaxin Isoforms

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