The pseudokinase tribbles homolog 3 interacts with ATF4 to negatively regulate insulin exocytosis in human and mouse β cells
Chong Wee Liew, … , Andrzej S. Krolewski, Rohit N. Kulkarni
Chong Wee Liew, … , Andrzej S. Krolewski, Rohit N. Kulkarni
Published July 1, 2010
Citation Information: J Clin Invest. 2010;120(8):2876-2888. https://doi.org/10.1172/JCI36849.
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Research Article Metabolism

The pseudokinase tribbles homolog 3 interacts with ATF4 to negatively regulate insulin exocytosis in human and mouse β cells

Abstract

Insufficient insulin secretion and reduced pancreatic β cell mass are hallmarks of type 2 diabetes (T2DM). Here, we confirm that a previously identified polymorphism (rs2295490/Q84R) in exon 2 of the pseudokinase-encoding gene tribbles 3 (TRB3) is associated with an increased risk for T2DM in 2 populations of people of mixed European descent. Carriers of the 84R allele had substantially reduced plasma levels of C-peptide, the product of proinsulin processing to insulin, suggesting a role for TRB3 in β cell function. Overexpression of TRB3 84R in mouse β cells, human islet cells, and the murine β cell line MIN6 revealed reduced insulin exocytosis, associated with a marked reduction in docked insulin granules visualized by electron microscopy. Conversely, knockdown of TRB3 in MIN6 cells restored insulin secretion and expression of exocytosis genes. Further analysis in MIN6 cells demonstrated that TRB3 interacted with the transcription factor ATF4 and that this complex acted as a competitive inhibitor of cAMP response element-binding (CREB) transcription factor in the regulation of key exocytosis genes. In addition, the 84R TRB3 variant exhibited greater protein stability than wild-type TRB3 and increased binding affinity to Akt. Mice overexpressing TRB3 84R in β cells displayed decreased β cell mass, associated with reduced proliferation and enhanced apoptosis rates. These data link a missense polymorphism in human TRB3 to impaired insulin exocytosis and thus increased risk for T2DM.

Authors

Chong Wee Liew, Jacek Bochenski, Dan Kawamori, Jiang Hu, Colin A. Leech, Krzysztof Wanic, Maciej Malecki, James H. Warram, Ling Qi, Andrzej S. Krolewski, Rohit N. Kulkarni

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Figure 6

Enhanced TRB3 function in β cells expressing 84R TRB3.

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Enhanced TRB3 function in β cells expressing 84R TRB3. (A) Immunoprecipi...
(A) Immunoprecipitation for TRB3 and Akt in MIN6 cells. Cell lysate (input) and IP lysate (pull down) were analyzed by Western blotting. Representative images from 3 independent experiments are shown. (B) Immunoprecipitation for Akt and immunoblotting in MIN6 cells expressing either Q84 TRB3 or 84R TRB3. Cell lysate (input) and IP lysate (pull down) were analyzed by Western blotting. Representative images from 4 independent experiments are shown. (C) Western blotting for TRB3 and Akt in MIN6 cells expressing either Q84 TRB3 or 84R TRB3. Indicated samples were treated with the proteasome inhibitor MG132 (5 μM, 16 hours prior to harvesting cells). Q, Q84 TRB3; R, 84R TRB3. Representative images from 3 independent experiments are shown. The white vertical line indicates noncontiguous lanes run on the same gel. (D) Pulse-chase experiment for TRB3 protein in MIN6 cells expressing either Q84 TRB3 or 84R TRB3 (n = 3 in each group). Q84 TRB3 or 84R TRB3 protein was labeled with modified methionine in vivo (pulse), then harvested at the indicated time points (chase), and immunoprecipitated with streptavidin beads. The rate of degradation of newly synthesized TRB3 and tubulin (internal control) was monitored by Western blotting, and the data was quantified and plotted as a percentage of initial labeled protein.