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14-3-3ζ Constrains insulin secretion by regulating mitochondrial function in pancreatic β cells
Yves Mugabo, Cheng Zhao, Ju Jing Tan, Anindya Ghosh, Scott A. Campbell, Evgenia Fadzeyeva, Frédéric Paré, Siew Siew Pan, Maria Galipeau, Julia Ast, Johannes Broichhagen, David J. Hodson, Erin E. Mulvihill, Sophie Petropoulos, Gareth E. Lim
Yves Mugabo, Cheng Zhao, Ju Jing Tan, Anindya Ghosh, Scott A. Campbell, Evgenia Fadzeyeva, Frédéric Paré, Siew Siew Pan, Maria Galipeau, Julia Ast, Johannes Broichhagen, David J. Hodson, Erin E. Mulvihill, Sophie Petropoulos, Gareth E. Lim
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Research Article Endocrinology Metabolism

14-3-3ζ Constrains insulin secretion by regulating mitochondrial function in pancreatic β cells

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Abstract

While critical for neurotransmitter synthesis, 14-3-3 proteins are often assumed to have redundant functions due to their ubiquitous expression, but despite this assumption, various 14-3-3 isoforms have been implicated in regulating metabolism. We previously reported contributions of 14-3-3ζ in β cell function, but these studies were performed in tumor-derived MIN6 cells and systemic KO mice. To further characterize the regulatory roles of 14-3-3ζ in β cell function, we generated β cell–specific 14-3-3ζ–KO mice. Although no effects on β cell mass were detected, potentiated glucose-stimulated insulin secretion (GSIS), mitochondrial function, and ATP synthesis were observed. Deletion of 14-3-3ζ also altered the β cell transcriptome, as genes associated with mitochondrial respiration and oxidative phosphorylation were upregulated. Acute 14-3-3 protein inhibition in mouse and human islets recapitulated the enhancements in GSIS and mitochondrial function, suggesting that 14-3-3ζ is the critical isoform in β cells. In dysfunctional db/db islets and human islets from type 2 diabetic donors, expression of Ywhaz/YWHAZ, the gene encoding 14-3-3ζ, was inversely associated with insulin secretion, and pan–14-3-3 protein inhibition led to enhanced GSIS and mitochondrial function. Taken together, this study demonstrates important regulatory functions of 14-3-3ζ in the regulation of β cell function and provides a deeper understanding of how insulin secretion is controlled in β cells.

Authors

Yves Mugabo, Cheng Zhao, Ju Jing Tan, Anindya Ghosh, Scott A. Campbell, Evgenia Fadzeyeva, Frédéric Paré, Siew Siew Pan, Maria Galipeau, Julia Ast, Johannes Broichhagen, David J. Hodson, Erin E. Mulvihill, Sophie Petropoulos, Gareth E. Lim

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Figure 4

Single-cell transcriptome analyses of β14-3-3ζ–KO islets.

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Single-cell transcriptome analyses of β14-3-3ζ–KO islets.
(A) UMAP plot ...
(A) UMAP plot of all cells from WT and KO mouse pancreas colored by cell type. (B) Dot plots of candidate marker genes specific for cell types. The size and the color of the dot encode the percentage of cells and average expression level across all cells within each group (red and blue represent high expression levels in WT and KO cells, respectively). (C) UMAP plot of all endocrine cells from WT and KO mouse pancreas colored by cell subtypes. (D) UMAP plot as in C but split into WT and KO cells, illustrating the expression of the 4 endocrine hormones (both mouse Ins1 and Ins2 will encode for mature insulin protein): Ins1, Ins2, Gcg, Sst, and Ppy. The color scale is according to log-transformed normalization values, with light gray and red corresponding to the minimum and maximum expression, respectively. (E) Violin plot showing the expression of Ywhaz in different types of cells. (F) Volcano plot of the distribution of genes with at least 0.1 difference in log2 fold change in expression level, mapping the 351 upregulated genes (blue) and 358 downregulated genes (red). –Log10 FDR > 20 was set to avoid extremely high values. (G) Dot plot showing enriched GO from genes highly expressed in WT and KO β cells, respectively. The size and the color of the dot encode the numbers of DEGs and the significance of corresponding enriched GO. Data are an aggregate of n = 3 WT and n = 3 β14-3-3ζ–KO mice per group.

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