Beta-cell hubs maintain Ca2+ oscillations in human and mouse islet simulations.

IF 1.9 4区 医学 Q3 ENDOCRINOLOGY & METABOLISM
Chon-Lok Lei, Joely A Kellard, Manami Hara, James D Johnson, Blanca Rodriguez, Linford J B Briant
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引用次数: 36

Abstract

Islet β-cells are responsible for secreting all circulating insulin in response to rising plasma glucose concentrations. These cells are a phenotypically diverse population that express great functional heterogeneity. In mice, certain β-cells (termed 'hubs') have been shown to be crucial for dictating the islet response to high glucose, with inhibition of these hub cells abolishing the coordinated Ca2+ oscillations necessary for driving insulin secretion. These β-cell hubs were found to be highly metabolic and susceptible to pro-inflammatory and glucolipotoxic insults. In this study, we explored the importance of hub cells in human by constructing mathematical models of Ca2+ activity in human islets. Our simulations revealed that hubs dictate the coordinated Ca2+ response in both mouse and human islets; silencing a small proportion of hubs abolished whole-islet Ca2+ activity. We also observed that if hubs are assumed to be preferentially gap junction coupled, then the simulations better adhere to the available experimental data. Our simulations of 16 size-matched mouse and human islet architectures revealed that there are species differences in the role of hubs; Ca2+ activity in human islets was more vulnerable to hub inhibition than mouse islets. These simulation results not only substantiate the existence of β-cell hubs, but also suggest that hubs may be favorably coupled in the electrical and metabolic network of the islet, and that targeted destruction of these cells would greatly impair human islet function.

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β细胞中心维持Ca2+振荡在人类和小鼠胰岛模拟。
胰岛β细胞负责在血糖浓度升高时分泌所有循环胰岛素。这些细胞是表型多样化的群体,表达了巨大的功能异质性。在小鼠中,某些β细胞(称为“中枢”)已被证明对决定胰岛对高葡萄糖的反应至关重要,这些中枢细胞的抑制消除了驱动胰岛素分泌所必需的协调Ca2+振荡。这些β细胞中心被发现是高度代谢的,易受促炎和糖脂中毒的损害。在本研究中,我们通过构建人类胰岛Ca2+活性的数学模型来探讨中枢细胞在人类中的重要性。我们的模拟显示,中枢决定了小鼠和人类胰岛中协调的Ca2+反应;沉默一小部分中枢细胞可消除整个胰岛的Ca2+活性。我们还观察到,如果假设轮毂是优先的间隙连接耦合,那么模拟更符合现有的实验数据。我们对16种大小匹配的小鼠和人类胰岛结构的模拟表明,中枢的作用存在物种差异;人类胰岛的Ca2+活性比小鼠胰岛更容易受到中枢抑制。这些模拟结果不仅证实了β-细胞枢纽的存在,而且表明枢纽可能在胰岛的电和代谢网络中有利地偶联,并且这些细胞的靶向破坏将极大地损害人类胰岛的功能。
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来源期刊
Islets
Islets ENDOCRINOLOGY & METABOLISM-
CiteScore
3.30
自引率
4.50%
发文量
10
审稿时长
>12 weeks
期刊介绍: Islets is the first international, peer-reviewed research journal dedicated to islet biology. Islets publishes high-quality clinical and experimental research into the physiology and pathology of the islets of Langerhans. In addition to original research manuscripts, Islets is the leading source for cutting-edge Perspectives, Reviews and Commentaries. Our goal is to foster communication and a rapid exchange of information through timely publication of important results using print as well as electronic formats.
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