Menin determines K-RAS proliferative outputs in endocrine cells
Chester E. Chamberlain, David W. Scheel, Kathleen McGlynn, Hail Kim, Takeshi Miyatsuka, Juehu Wang, Vinh Nguyen, Shuhong Zhao, Anastasia Mavropoulos, Aswin G. Abraham, Eric O’Neill, Gregory M. Ku, Melanie H. Cobb, Gail R. Martin, Michael S. German
Chester E. Chamberlain, David W. Scheel, Kathleen McGlynn, Hail Kim, Takeshi Miyatsuka, Juehu Wang, Vinh Nguyen, Shuhong Zhao, Anastasia Mavropoulos, Aswin G. Abraham, Eric O’Neill, Gregory M. Ku, Melanie H. Cobb, Gail R. Martin, Michael S. German
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Research Article

Menin determines K-RAS proliferative outputs in endocrine cells

Abstract

Endocrine cell proliferation fluctuates dramatically in response to signals that communicate hormone demand. The genetic alterations that override these controls in endocrine tumors often are not associated with oncogenes common to other tumor types, suggesting that unique pathways govern endocrine proliferation. Within the pancreas, for example, activating mutations of the prototypical oncogene KRAS drive proliferation in all pancreatic ductal adenocarcimomas but are never found in pancreatic endocrine tumors. Therefore, we asked how cellular context impacts K-RAS signaling. We found that K-RAS paradoxically suppressed, rather than promoted, growth in pancreatic endocrine cells. Inhibition of proliferation by K-RAS depended on antiproliferative RAS effector RASSF1A and blockade of the RAS-activated proproliferative RAF/MAPK pathway by tumor suppressor menin. Consistent with this model, a glucagon-like peptide 1 (GLP1) agonist, which stimulates ERK1/2 phosphorylation, did not affect endocrine cell proliferation by itself, but synergistically enhanced proliferation when combined with a menin inhibitor. In contrast, inhibition of MAPK signaling created a synthetic lethal interaction in the setting of menin loss. These insights suggest potential strategies both for regenerating pancreatic β cells for people with diabetes and for targeting menin-sensitive endocrine tumors.

Authors

Chester E. Chamberlain, David W. Scheel, Kathleen McGlynn, Hail Kim, Takeshi Miyatsuka, Juehu Wang, Vinh Nguyen, Shuhong Zhao, Anastasia Mavropoulos, Aswin G. Abraham, Eric O’Neill, Gregory M. Ku, Melanie H. Cobb, Gail R. Martin, Michael S. German

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Figure 3

K-RAS signaling suppresses endocrine cell growth.

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K-RAS signaling suppresses endocrine cell growth. (A and B) Projection i...
(A and B) Projection images of the dorsal pancreas were collected by whole-mount confocal microscopy from E13.5 mouse embryos of the indicated genotypes and immunostained for E-cadherin (blue), NEUROG3 (green), and glucagon and insulin (red). (C) The percentage of epithelial pancreas that stained for NEUROG3 was quantified (n = 3 Pdx1-Cre Kras+/+, n = 3 Pdx1-Cre Kras+/G12D). (D) The percentage of β cells expressing the proliferation marker p-H3 was quantified in pancreata from P5 neonatal mice of the indicated genotypes (n = 5 Ins2-Cre Kras+/+, n = 5 Ins2-Cre Kras+/G12D, >25,000 β cells counted in total). (EJ) Sections from P5 neonatal pancreata of the indicated genotypes (n = 5 each) were immunostained for insulin, B-RAF, p-ERK1/2 (Thr202/Tyr204), RASSF1, and p-RASSF1 (Ser131). (KL) Representative single optical sections from 12-week-old WT adult mouse islets treated with DMSO (K) or K-RAS inhibitor FTI-GGTI (L) that stained for β cell marker NKX6.1 (red), proliferation marker EdU (green), and nuclear DNA marker DAPI (blue). (M and N) The percentage of NKX6.1+ β cell nuclei that costained for the proliferation marker EdU was quantified in islets from 12-week-old mice of the indicated genotypes (M, n = 3 replicates of >20 islets each, >430,000 β cells counted in total) or from human donors (N, 6 different donors, n = 3 replicates with >20 human islets each, >230,000 β cells counted in total) cultured with the additives shown and stained as in K and L. All data points represent the mean ± SEM. *P < 0.05, **P < 0.01 versus control by 2-tailed Student’s t test. Scale bars: 50 μm. ND, none detected.