GPRC5B preserves a mature β cell state in obesity by controlling MafA expression
Tianpeng Wang, … , Stefan Günther, Nina Wettschureck
Tianpeng Wang, … , Stefan Günther, Nina Wettschureck
Published September 4, 2025
Citation Information: JCI Insight. 2025;10(20):e194115. https://doi.org/10.1172/jci.insight.194115.
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Research Article Endocrinology Metabolism

GPRC5B preserves a mature β cell state in obesity by controlling MafA expression

Abstract

In vitro studies have implicated orphan receptor GPRC5B in β cell survival, proliferation, and insulin secretion, but its relevance for glucose homeostasis in vivo is largely unknown. Using tamoxifen-inducible, β cell–specific GPRC5B-KO mice (Ins-G5b–KOs), we show here that loss of GPRC5B does not affect β cell function in the lean state but results in strongly reduced insulin secretion and disturbed glucose tolerance in mice subjected to high-fat diet for 16 weeks. Flow cytometry and single-cell expression analyses in islets from obese mice show a reduced β cell abundance and a less mature β cell phenotype in Ins-G5b–KOs. Expression of β cell–specific transcription factor MafA is reduced both on the RNA and protein level, as are transcripts of MafA target genes. Mechanistically, we show that phosphorylation of cAMP response element-binding protein (CREB), a major regulator of MafA expression, is reduced in islets of obese Ins-G5b–KOs, and we show that this phenotype precedes the downregulation of MafA and MafA target genes. Taken together, GPRC5B helps to maintain mature β cell function in obesity through cAMP/CREB-dependent regulation of MafA expression.

Authors

Tianpeng Wang, Remy Bonnavion, Janett Piesker, Stefan Günther, Nina Wettschureck

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Figure 5

Impaired cAMP/CREB/MafA signaling in obese Ins-G5b–KOs.

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Impaired cAMP/CREB/MafA signaling in obese Ins-G5b–KOs. (A and B) Immuno...
(A and B) Immunoblot analysis of MafA expression in lysates of islets harvested from obese control and Ins-G5b–KO mice: representative Western blot images (A) and statistical evaluation of band intensities (B, n = 6/6 mice). (C) Effect of 20 mM glucose (Glu) on calcium mobilization in HEK cells transfected with GPRC5B (G5B), a promiscuous G-protein, and a calcium sensor; iloprost-mediated (Ilo-mediated) stimulation of prostacyclin receptor IP-transfected cells serves as positive control (n = 6 G5B-Veh; n = 6 G5B-Glu; n = 4 IP-Veh; n = 4 IP-Glu). (DG) Immunoblot analysis of basal CREB phosphorylation in islets isolated from HFD-fed (D and E, n = 6/6) or lean (F and G, n = 4/4) mice; total CREB as loading control. (H and I) Immunoblot analysis of MafA expression in islets harvested from lean mice; α-tubulin was used as loading control (n = 4/3 mice). (J) Expression of MafA target genes was determined by mRNA-Seq of flow cytometry–isolated β cells harvested from lean control and Ins-G5b–KO mice (n = 3/2 mice). The y axis represents DESeq2 normalized counts. (K and L) Basal cAMP levels in islets from lean (K) and obese (L) Ins-G5b–KOs following overnight culture in complete RPMI-1640 media (11.1 mM glucose) (n = 7/8 and 5/5 mice). (M) Expression of genes related to cAMP production/breakdown was determined by mRNA-Seq in flow cytometry–isolated β cells harvested from lean mice (n = 3/2 mice). The y axis represents DESeq2 normalized counts. (N) Effect of 20 mM glucose (Glu) on cAMP production in GPRC5B-overexpressing (G5B-overexpressing) HEK cells was determined using a GloSensor-based cAMP assay; iloprost-mediated (Ilo-mediated) stimulation of prostacyclin receptor IP-transfected cells serves as positive control (n = 4, 6, 4, 4). Data are mean ± SEM; comparisons between control and KO samples were performed using unpaired Student’s t test (B, C, E, G, I, K, L, and N) and multiple unpaired Student’s t test with 2-stage linear step-up procedure of Benjamini, Krieger, and Yekutieli (J and M). n, number of mice per group/individual wells of cells. *P ≤ 0.05, **P ≤ 0.01, ***P ≤ 0.001.