在人类2型糖尿病中，通过胰岛素分泌途径的Cab45G运输发生改变。

Cab45G trafficking through the insulin secretory pathway is altered in human type 2 diabetes.

作者信息

Germanos Mark, Yau Belinda, Taper Matthew, Yeoman Cara, Wilson Amy, An Yousun, Cattin-Ortolá Jerome, Masler Drew, Tong Jason, Naghiloo Sheyda, Needham Elise J, van der Kraan A Gabrielle, Sun Kitty, Loudovaris Thomas, Diaz-Vegas Alexis, Larance Mark, Thomas Helen, von Blume Julia, Thorn Peter, Ailion Michael, Asensio Cedric, Kebede Melkam Alamerew

机构信息

School of Medical Sciences, Charles Perkins Centre, The University of Sydney, Camperdown, NSW, Australia.

Department of Biochemistry, University of Washington, Seattle, WA, USA.

出版信息

iScience. 2024 Dec 30;28(2):111719. doi: 10.1016/j.isci.2024.111719. eCollection 2025 Feb 21.

DOI:10.1016/j.isci.2024.111719

PMID:39898024

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11787600/

Abstract

In type 2 diabetes (T2D), the rate of insulin secretory granule biogenesis can limit insulin secretion from pancreatic β-cells. Using rat insulinoma INS1 β-cells, we show that the soluble Ca-binding/trafficking protein, Cab45G, serves as a non-essential chaperone for insulin granule biogenesis. In β-cells, Cab45G is stored within a -Golgi reservoir. Cab45G deletion dysregulates Ca homeostasis and leads to secretory abnormality, but insulin granule biogenesis remains intact. Increasing Cab45G biosynthesis leads to anterograde trafficking into insulin granules, stimulating their production. Using human donor islets, we identify increased anterograde Cab45G trafficking in obese humans with and without T2D, consistent with the heightened demand for granule biogenesis. However, humans with T2D demonstrate decreased Golgi Cab45G localization and increased granule Cab45G localization compared to those without T2D. Our study provides the first insight into Cab45G function in specialized secretory cells and opens avenues of investigation into mechanisms associated with β-cell compensation and failure.

摘要

在2型糖尿病（T2D）中，胰岛素分泌颗粒生物合成的速率可能会限制胰腺β细胞的胰岛素分泌。利用大鼠胰岛素瘤INS1β细胞，我们发现可溶性钙结合/运输蛋白Cab45G作为胰岛素颗粒生物合成的非必需伴侣蛋白。在β细胞中，Cab45G储存在高尔基体储存库中。Cab45G缺失会破坏钙稳态并导致分泌异常，但胰岛素颗粒生物合成仍保持完整。增加Cab45G的生物合成会导致其顺向运输到胰岛素颗粒中，从而刺激颗粒的产生。利用人类供体胰岛，我们发现在患有和未患有T2D的肥胖人群中，Cab45G的顺向运输均增加，这与对颗粒生物合成的更高需求一致。然而，与未患T2D的人相比，患T2D的人高尔基体中Cab45G的定位减少，颗粒中Cab45G的定位增加。我们的研究首次揭示了Cab45G在特殊分泌细胞中的功能，并为研究与β细胞代偿和功能衰竭相关的机制开辟了途径。

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在人类2型糖尿病中，通过胰岛素分泌途径的Cab45G运输发生改变。

Cab45G trafficking through the insulin secretory pathway is altered in human type 2 diabetes.

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