Abstract
Terminal regions of Drosophila embryos are patterned by signaling through ERK, which is genetically deregulated in multiple human diseases. Quantitative studies of terminal patterning have been recently used to investigate gain-of-function variants of human MEK1, encoding the MEK kinase that directly activates ERK by dual phosphorylation. Unexpectedly, several mutations reduced ERK activation by extracellular signals, possibly through a negative feedback triggered by signal-independent activity of the mutant variants. Here we present experimental evidence supporting this model. Using a MEK variant that combines a mutation within the negative regulatory region with alanine substitutions in the activation loop, we prove that pathogenic variants indeed acquire signal-independent kinase activity. We also demonstrate that signal-dependent activation of these variants is independent of kinase suppressor of Ras, a conserved adaptor that is indispensable for activation of normal MEK. Finally, we show that attenuation of ERK activation by extracellular signals stems from transcriptional induction of Mkp3, a dual specificity phosphatase that deactivates ERK by dephosphorylation. These findings in the Drosophila embryo highlight its power for investigating diverse effects of human disease mutations.
Original language | English (US) |
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Pages (from-to) | 974-983 |
Number of pages | 10 |
Journal | Molecular biology of the cell |
Volume | 32 |
Issue number | 9 |
DOIs | |
State | Published - 2021 |
Funding
We thank Becky Burdine, Aleena Patel, Shannon Keenan, Bruce Gelb, Ben Neel, Nareg Djabrayan, and Vicki Patterson for many helpful discussions. We thank Gary Laevsky from the Princeton Nikon Imaging Facility for assistance with microscopy as well as the staff of the Sequencing Core Facility of the Lewis-Sigler Institute for help with the RNA-seq experiments. We also thank Kei Yamaya for contributions during the early stages of this work and all members of the Shvartsman Lab for comments and suggestions. This work was supported by National Institutes of Health (NIH) grants R01-GM086537 and R01-HD085870 (awarded to S.Y.S.). Y.G. acknowledges the support of Schmidt Science Fellowship (in partnership with the Rhodes Trust) and the Jane Coffin Childs Memorial Fund for Medical Research for their support. G.A.J. acknowledges support from American Heart Association Grant #18POST34030077 (Award year: 2018). G.A.J. acknowledges past support by the National Science Foundation Graduate Research Fellowship Grant DGE-1148900. National Science Foundation: ABI-1458457 (awarded to M.S.) and DGE-1148900 (awarded to J.W.) and NIH: R01-GM076275 (awarded to M.S.).
ASJC Scopus subject areas
- Molecular Biology
- Cell Biology