Uncovering a New Role for KSR1 in Hippo Signaling
Published in Cell & Molecular Biology
This project began with a simple curiosity: could a MAPK scaffold like KSR1 influence other major signaling pathways? Early experiments offered an unexpected clue—KSR1 consistently appeared in complexes with MST1, LATS1, and YAP. What seemed like a technical anomaly quickly became a turning point.
KSR1 was not just brushing against the Hippo pathway—it was organizing it.
As we followed this lead, diverse approaches—structural modeling, proteomics, imaging, and transcriptional analysis—converged on the same idea:
KSR1 functions as a scaffold for Hippo signaling, regulating YAP levels, nuclear localization, and mechanosensitive behavior through the RhoA–actin network.
One of the most striking findings was that external cues such as EGF could shift KSR1’s role between the MAPK and Hippo pathways, revealing a dynamic regulatory switch rather than a static scaffold.
Behind the scenes, this work required building new technical infrastructure and collaborating across structural biology, computation, and mechanobiology. Each piece brought clarity to a system that had been hiding in plain sight.
In the end, our study reframes KSR1 as a central coordinator of growth-control networks—crossing boundaries between mechanical cues, kinase cascades, and transcriptional programs.
Sometimes the most familiar proteins carry the most surprising stories; we just have to follow where the data lead.
I am a molecular biologist and clinician-scientist focused on how dysregulated cell signaling and mechanotransduction drive cancer progression. My work integrates advanced imaging, quantitative biology, and computational approaches to uncover the molecular rules governing cell behavior, transformation, and therapeutic response.
I am committed to building interdisciplinary collaborations that bridge molecular biology, engineering, and clinical research to accelerate discovery and develop precision treatments. My long-term goal is to translate fundamental insights in cell signaling and nuclear morphology into early-detection strategies and targeted therapies that improve patient outcomes.
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