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猫脂肪来源的多能基质细胞转分化为功能性胰岛素分泌细胞团

Feline Adipose Derived Multipotent Stromal Cell Transdifferentiation Into Functional Insulin Producing Cell Clusters.

作者信息

Taguchi Takashi, Duan Wei, Wolfson Wendy, Duhon Brandy, Halphen Emily G, Lopez Mandi J

机构信息

Laboratory for Equine and Comparative Orthopedic Research, Department of Veterinary Clinical Sciences, School of Veterinary Medicine, Louisiana State University, Baton Rouge, LA, United States.

Department of Veterinary Clinical Sciences, School of Veterinary Medicine, Louisiana State University, Baton Rouge, LA, United States.

出版信息

Front Bioeng Biotechnol. 2022 Jun 8;10:904519. doi: 10.3389/fbioe.2022.904519. eCollection 2022.

DOI:10.3389/fbioe.2022.904519
PMID:35769100
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9234738/
Abstract

Diabetes mellitus (DM) is one of the most prevalent feline endocrinopathies, affecting up to 1% of pet cats. De novo generation of functional insulin producing cell (IPC) clusters transdifferentiation of feline adipose-derived multipotent stromal cells (ASCs) may not only provide a viable, functional cell therapy for feline DM, but may also serve as a platform for developing a comparable human treatment given feline and human DM similarities. Cells were induced to form IPCs with a novel, three-stage culture process with stromal or differentiation medium under static and dynamic conditions. Clusters were evaluated for intracellular zinc, viability, intracellular insulin, glucagon, and somatostatin, ultrastructure, glucose stimulated insulin secretion in the presence or absence of theophylline, and protein and gene expression. Isolated cells were multipotent, and cell clusters cultured in both media had robust cell viability. Those cultured in differentiation medium contained zinc and mono- or polyhormonal α-, β-, and δ-like cells based on immunohistochemical labeling and Mallory-Heidenhan Azan-Gomori's staining. Ultrastructurally, cell clusters cultured in differentiation medium contained insulin granules within vesicles, and clusters had a concentration-dependent insulin response to glucose in the presence and absence of theophylline which increased both insulin secretion and intracellular content. Expression of NK6.1, Pax6, Isl1, Glut2, RAB3A, glucagon, insulin, and somatostatin increased with differentiation stage for both sexes, and expression of nestin at stages 1 and 2 and Neurod1 at stage 2 was higher in cells from female donors. The cluster insulin secretion responses and endocrine and oncogene gene expression profiles were inconsistent with insulinoma characteristics. A total of 180 proteins were upregulated in differentiated clusters, and the majority were associated with biological regulation, metabolic processes, or stimulus response. Dynamic culture of IPC clusters resulted in clusters composed of cells primarily expressing insulin that released higher insulin with glucose stimulation than those in static culture. Collectively, the results of this study support generation of functional IPC clusters using feline ASCs isolated from tissues removed during routine sterilization. Further, cluster functionality is enhanced with dynamic, motion-driven shear stress. This work establishes a foundation for development of strategies for IPC therapy for short or long-term diabetes treatment and may represent an option to study prevention and treatment of diabetes across species.

摘要

糖尿病(DM)是猫最常见的内分泌疾病之一,影响着高达1%的宠物猫。从猫脂肪来源的多能基质细胞(ASC)转分化从头生成功能性胰岛素产生细胞(IPC)簇,不仅可为猫糖尿病提供一种可行的、功能性的细胞疗法,而且鉴于猫和人类糖尿病的相似性,还可作为开发类似人类治疗方法的平台。通过一种新的三阶段培养过程,在静态和动态条件下用基质或分化培养基诱导细胞形成IPC。对细胞簇进行细胞内锌、活力、细胞内胰岛素、胰高血糖素和生长抑素、超微结构、有无茶碱存在下的葡萄糖刺激胰岛素分泌以及蛋白质和基因表达的评估。分离的细胞具有多能性,在两种培养基中培养的细胞簇具有强大的细胞活力。基于免疫组织化学标记和马洛里-海登汉·阿赞-戈莫里染色,在分化培养基中培养的细胞含有锌以及单激素或多激素的α、β和δ样细胞。在超微结构上,在分化培养基中培养的细胞簇在囊泡内含有胰岛素颗粒,并且在有无茶碱存在的情况下,细胞簇对葡萄糖具有浓度依赖性胰岛素反应,这增加了胰岛素分泌和细胞内含量。NK6.1、Pax6、Isl1、Glut2、RAB3A、胰高血糖素、胰岛素和生长抑素的表达随分化阶段在两性中均增加,并且在第1和第2阶段巢蛋白以及第2阶段Neurod1在雌性供体细胞中的表达更高。细胞簇胰岛素分泌反应以及内分泌和癌基因表达谱与胰岛素瘤特征不一致。在分化的细胞簇中有180种蛋白质上调,并且大多数与生物调节、代谢过程或刺激反应相关。IPC簇的动态培养导致细胞簇主要由表达胰岛素的细胞组成,与静态培养相比,在葡萄糖刺激下释放更高水平的胰岛素。总体而言,本研究结果支持使用从常规绝育手术中切除的组织分离的猫ASC生成功能性IPC簇。此外,动态的、运动驱动的剪切应力可增强细胞簇的功能。这项工作为开发用于短期或长期糖尿病治疗的IPC治疗策略奠定了基础,并且可能代表了一种跨物种研究糖尿病预防和治疗的选择。

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