Proteomic analyses identify targets, pathways, and cellular consequences of oncogenic KRAS signaling

Nicole Kabella; Florian P. Bayer; Konstantinos Stamatiou; Miriam Abele; Amirhossein Sakhteman; Yun Chien Chang; Vinona Wagner; Antje Gabriel; Johannes Krumm; Maria Reinecke; Melanie Holzner; Michael Aigner; Matthew The; Hannes Hahne; Florian Bassermann; Christina Ludwig; Paola Vagnarelli; Bernhard Kuster

doi:10.1126/scisignal.adt6552

Proteomic analyses identify targets, pathways, and cellular consequences of oncogenic KRAS signaling

Nicole Kabella
, Florian P. Bayer
, Konstantinos Stamatiou
, Miriam Abele
, Amirhossein Sakhteman
, Yun Chien Chang
, Vinona Wagner
, Antje Gabriel
, Johannes Krumm
, Maria Reinecke
, Melanie Holzner
, Michael Aigner
, Matthew The
, Hannes Hahne
, Florian Bassermann
, Christina Ludwig
, Paola Vagnarelli
, Bernhard Kuster

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

Mutations that activate the small GTPase KRAS are a frequent genetic alteration in cancer, and drug discovery efforts have led to inhibitors that block KRAS activity. We sought to better understand oncogenic KRAS signaling and the cytostatic effects of drugs that target this system. We performed proteomic analyses to investigate changes in protein abundance and posttranslational modifications in inhibitor-treated human KRAS-mutant pancreatic (KRAS G12C and G12D) and lung cancer (KRAS G12C) cells. The inhibitors used target these mutant forms of KRAS, the downstream effectors MEK and ERK, and the upstream regulators SHP2 and SOS1. Comparisons of phosphoproteomes between cell lines revealed a core KRAS signaling signature and cell line–specific signaling networks. In all cell lines, phosphoproteomes were dominated by different degrees of autonomous, oncogenic KRAS activity. Comparison of phosphoproteomes after short and long drug exposures revealed the temporal dynamics of KRAS-MEK-ERK axis inhibition that resulted in cell cycle exit. This transition to a quiescent state occurred in the absence of substantial proteome remodeling but included broad changes in protein phosphorylation and ubiquitylation. The collective data reveal insights into oncogenic KRAS signaling, place many additional proteins into this functional context, and implicate cell cycle exit as a mechanism by which cells evade death upon KRAS signaling inhibition.

Original language	English
Article number	eadt6552
Journal	Science Signaling
Volume	18
Issue number	897
DOIs	https://doi.org/10.1126/scisignal.adt6552
State	Published - 29 Jul 2025

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Kabella, N., Bayer, F. P., Stamatiou, K., Abele, M., Sakhteman, A., Chang, Y. C., Wagner, V., Gabriel, A., Krumm, J., Reinecke, M., Holzner, M., Aigner, M., The, M., Hahne, H., Bassermann, F., Ludwig, C., Vagnarelli, P., & Kuster, B. (2025). Proteomic analyses identify targets, pathways, and cellular consequences of oncogenic KRAS signaling. Science Signaling, 18(897), Article eadt6552. https://doi.org/10.1126/scisignal.adt6552

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title = "Proteomic analyses identify targets, pathways, and cellular consequences of oncogenic KRAS signaling",

abstract = "Mutations that activate the small GTPase KRAS are a frequent genetic alteration in cancer, and drug discovery efforts have led to inhibitors that block KRAS activity. We sought to better understand oncogenic KRAS signaling and the cytostatic effects of drugs that target this system. We performed proteomic analyses to investigate changes in protein abundance and posttranslational modifications in inhibitor-treated human KRAS-mutant pancreatic (KRAS G12C and G12D) and lung cancer (KRAS G12C) cells. The inhibitors used target these mutant forms of KRAS, the downstream effectors MEK and ERK, and the upstream regulators SHP2 and SOS1. Comparisons of phosphoproteomes between cell lines revealed a core KRAS signaling signature and cell line–specific signaling networks. In all cell lines, phosphoproteomes were dominated by different degrees of autonomous, oncogenic KRAS activity. Comparison of phosphoproteomes after short and long drug exposures revealed the temporal dynamics of KRAS-MEK-ERK axis inhibition that resulted in cell cycle exit. This transition to a quiescent state occurred in the absence of substantial proteome remodeling but included broad changes in protein phosphorylation and ubiquitylation. The collective data reveal insights into oncogenic KRAS signaling, place many additional proteins into this functional context, and implicate cell cycle exit as a mechanism by which cells evade death upon KRAS signaling inhibition.",

author = "Nicole Kabella and Bayer, \{Florian P.\} and Konstantinos Stamatiou and Miriam Abele and Amirhossein Sakhteman and Chang, \{Yun Chien\} and Vinona Wagner and Antje Gabriel and Johannes Krumm and Maria Reinecke and Melanie Holzner and Michael Aigner and Matthew The and Hannes Hahne and Florian Bassermann and Christina Ludwig and Paola Vagnarelli and Bernhard Kuster",

note = "Publisher Copyright: {\textcopyright} 2025 The Authors, some rights reserved.",

year = "2025",

month = jul,

day = "29",

doi = "10.1126/scisignal.adt6552",

language = "English",

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journal = "Science Signaling",

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Kabella, N, Bayer, FP, Stamatiou, K, Abele, M, Sakhteman, A, Chang, YC, Wagner, V, Gabriel, A, Krumm, J, Reinecke, M, Holzner, M, Aigner, M, The, M, Hahne, H, Bassermann, F, Ludwig, C, Vagnarelli, P & Kuster, B 2025, 'Proteomic analyses identify targets, pathways, and cellular consequences of oncogenic KRAS signaling', Science Signaling, vol. 18, no. 897, eadt6552. https://doi.org/10.1126/scisignal.adt6552

TY - JOUR

T1 - Proteomic analyses identify targets, pathways, and cellular consequences of oncogenic KRAS signaling

AU - Kabella, Nicole

AU - Bayer, Florian P.

AU - Stamatiou, Konstantinos

AU - Abele, Miriam

AU - Sakhteman, Amirhossein

AU - Chang, Yun Chien

AU - Wagner, Vinona

AU - Gabriel, Antje

AU - Krumm, Johannes

AU - Reinecke, Maria

AU - Holzner, Melanie

AU - Aigner, Michael

AU - The, Matthew

AU - Hahne, Hannes

AU - Bassermann, Florian

AU - Ludwig, Christina

AU - Vagnarelli, Paola

AU - Kuster, Bernhard

PY - 2025/7/29

Y1 - 2025/7/29

N2 - Mutations that activate the small GTPase KRAS are a frequent genetic alteration in cancer, and drug discovery efforts have led to inhibitors that block KRAS activity. We sought to better understand oncogenic KRAS signaling and the cytostatic effects of drugs that target this system. We performed proteomic analyses to investigate changes in protein abundance and posttranslational modifications in inhibitor-treated human KRAS-mutant pancreatic (KRAS G12C and G12D) and lung cancer (KRAS G12C) cells. The inhibitors used target these mutant forms of KRAS, the downstream effectors MEK and ERK, and the upstream regulators SHP2 and SOS1. Comparisons of phosphoproteomes between cell lines revealed a core KRAS signaling signature and cell line–specific signaling networks. In all cell lines, phosphoproteomes were dominated by different degrees of autonomous, oncogenic KRAS activity. Comparison of phosphoproteomes after short and long drug exposures revealed the temporal dynamics of KRAS-MEK-ERK axis inhibition that resulted in cell cycle exit. This transition to a quiescent state occurred in the absence of substantial proteome remodeling but included broad changes in protein phosphorylation and ubiquitylation. The collective data reveal insights into oncogenic KRAS signaling, place many additional proteins into this functional context, and implicate cell cycle exit as a mechanism by which cells evade death upon KRAS signaling inhibition.

AB - Mutations that activate the small GTPase KRAS are a frequent genetic alteration in cancer, and drug discovery efforts have led to inhibitors that block KRAS activity. We sought to better understand oncogenic KRAS signaling and the cytostatic effects of drugs that target this system. We performed proteomic analyses to investigate changes in protein abundance and posttranslational modifications in inhibitor-treated human KRAS-mutant pancreatic (KRAS G12C and G12D) and lung cancer (KRAS G12C) cells. The inhibitors used target these mutant forms of KRAS, the downstream effectors MEK and ERK, and the upstream regulators SHP2 and SOS1. Comparisons of phosphoproteomes between cell lines revealed a core KRAS signaling signature and cell line–specific signaling networks. In all cell lines, phosphoproteomes were dominated by different degrees of autonomous, oncogenic KRAS activity. Comparison of phosphoproteomes after short and long drug exposures revealed the temporal dynamics of KRAS-MEK-ERK axis inhibition that resulted in cell cycle exit. This transition to a quiescent state occurred in the absence of substantial proteome remodeling but included broad changes in protein phosphorylation and ubiquitylation. The collective data reveal insights into oncogenic KRAS signaling, place many additional proteins into this functional context, and implicate cell cycle exit as a mechanism by which cells evade death upon KRAS signaling inhibition.

UR - https://www.scopus.com/pages/publications/105012649434

U2 - 10.1126/scisignal.adt6552

DO - 10.1126/scisignal.adt6552

M3 - Article

C2 - 40729433

AN - SCOPUS:105012649434

SN - 1945-0877

VL - 18

JO - Science Signaling

JF - Science Signaling

IS - 897

M1 - eadt6552

ER -

Proteomic analyses identify targets, pathways, and cellular consequences of oncogenic KRAS signaling

Abstract

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