JNK3 regulates β cell responses to incretins in human islets and mouse models
Ruy A. Louzada, Marel Gonzalez Medina, Valentina Pita-Grisanti, Jessica Bouviere, Amanda F. Neves, Joana Almaça, Myoung Sook Han, Roger J. Davis, Gil Leibowitz, Manuel Blandino-Rosano, Ernesto Bernal-Mizrachi
Ruy A. Louzada, Marel Gonzalez Medina, Valentina Pita-Grisanti, Jessica Bouviere, Amanda F. Neves, Joana Almaça, Myoung Sook Han, Roger J. Davis, Gil Leibowitz, Manuel Blandino-Rosano, Ernesto Bernal-Mizrachi
View: Text | PDF
Research Article Endocrinology Metabolism

JNK3 regulates β cell responses to incretins in human islets and mouse models

Abstract

The c-Jun N-terminal kinases (JNKs) regulate diverse physiological processes. Whereas JNK1 and JNK2 are broadly expressed and associated with insulin resistance, inflammation, and stress responses, JNK3 is largely restricted to central nervous system neurons and pancreatic β cells, and its physiological role in β cells remains poorly defined. To investigate its function, we generated mice lacking JNK3 specifically in β cells (βJNK3-KO). These mice displayed glucose intolerance and defective insulin secretion, particularly after oral glucose challenge, indicating impaired incretin responses. Consistently, Exendin-4–stimulated (Ex4-stimulated) insulin secretion was blunted in βJNK3-KO islets, accompanied by reduced GLP-1R expression. Similar findings were observed in human islets treated with a selective JNK3 inhibitor (iJNK3). Downstream of GLP-1R, Ex4-induced CREB phosphorylation was diminished in βJNK3-KO islets, indicating impaired canonical signaling. Moreover, activation of the GLP-1R/CREB/IRS2 pathway, a key regulator of β cell survival, was reduced in βJNK3-KO islets and iJNK3-treated human islets. As a consequence, the protective effects of Ex4 were lost in cytokine-treated βJNK3-KO and human islets, and Ex4-mediated protection was partially attenuated in βJNK3-KO mice exposed to multiple low-dose streptozotocin. These findings identify JNK3 as a regulator of β cell function and survival and suggest that targeting this pathway may enhance incretin-based therapies.

Authors

Ruy A. Louzada, Marel Gonzalez Medina, Valentina Pita-Grisanti, Jessica Bouviere, Amanda F. Neves, Joana Almaça, Myoung Sook Han, Roger J. Davis, Gil Leibowitz, Manuel Blandino-Rosano, Ernesto Bernal-Mizrachi

×

Figure 7

Beneficial effect of Ex4 in improving glucose homeostasis and preserving β cell mass after low-dose STZ is partially dependent on JNK3 in β cells.

Options: View larger image (or click on image) Download as PowerPoint
Beneficial effect of Ex4 in improving glucose homeostasis and preserving...
(A) The data represents the average glucose of 2 to 3 measurements per week. Control Vehicle group (Black), Control+Ex4 group (Green), βJNK3-KO+Vehicle group (Red), and βJNK3-KO+Ex4 group (Blue) (n = 9–10). Treatment started 2 days before STZ protocol and was conducted daily for 4 weeks. Ex4 was injected intraperitoneally at 1 nmol/kg. (B) AUC over 4 weeks after STZ protocol. (C) Insulin levels at days 8, 15, and 22, normalized to the baseline (dashed lines) of each animal before STZ protocol. (D) Meal tolerance test (MTT) at 15 days after STZ, (E) AUC, and (F) insulin levels during MTT baseline and 15 minutes after gavage. (G) Representative images of islets insulin (green) and DAPI (blue); scale bar: 75 μm, (H) number of islets per area and (I) β cell mass of pancreases from all the groups. Dashed lines in I represent average of normoglycemic mice, for reference. In panels A and D, *P < 0.05 indicates differences between groups (Control versus KO treated with Ex4), and #P < 0.05 indicates differences within groups (vehicle versus Ex4 treated within the same genotype). *P < 0.05, **P < 0.01, ***P < 0.001, ****P < 0.0001. The results are expressed as means ± SEM.