Integrative multi-omics defines melanoma drug response networks and ARID1A-dependent resistance mechanisms

Charlie George Barker; Sumana Sharma; Ana Mafalda Santos; Konstantinos Stylianos Nikolakopoulos; Athanassios D. Velentzas; Cristina Tormo-Garcia; Anushka Sharma; Franziska I. Völlmy; Angeliki Minia; Vicky Pliaka; Joseph Clarke; Maarten Altelaar; Gavin J. Wright; Leonidas G. Alexopoulos; Dimitrios J. Stravopodis; Evangelia Petsalaki

doi:10.1038/s44320-025-00183-5

Integrative multi-omics defines melanoma drug response networks and ARID1A-dependent resistance mechanisms

Charlie George Barker
, Sumana Sharma
, Ana Mafalda Santos
, Konstantinos Stylianos Nikolakopoulos
, Athanassios D. Velentzas
, Cristina Tormo-Garcia
, Anushka Sharma
, Franziska I. Völlmy
, Angeliki Minia
, Vicky Pliaka
, Joseph Clarke
, Maarten Altelaar
, Gavin J. Wright
, Leonidas G. Alexopoulos
, Dimitrios J. Stravopodis
, Evangelia Petsalaki^*

^*Corresponding author for this work

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

Abstract

Resistance to BRAF/MAPK inhibitors is a significant challenge in melanoma treatment, driven by adaptive and acquired mechanisms allowing tumor cells to evade therapy. We explored early signaling responses to BRAF and MAPK inhibition in a BRAFV600E-sensitive melanoma cell line and a drug-resistant ARID1A-knockout (KO) derivative. ARID1A, frequently mutated in melanoma, is linked to resistance and immune evasion. Through an innovative systems biology approach integrating multi-omics datasets, we identified critical resistance mechanisms. We found that ARID1A-KO cells exhibited transcriptional rewiring, sustaining MAPK1/3 and JNK activity post-treatment, suppressing PRKD1 activation, increasing JUN activity, and disrupting PKC dynamics via elevated RTKs (e.g., EGFR, ROS1) and Ephrin receptor activity. ARID1A-KO also reduced HLA-related protein expression and enhanced extracellular matrix components, potentially limiting immune infiltration and immunotherapy efficacy. Our multi-omics analysis revealed PRKD1, JUN, and NCK1 as key resistance nodes, offering potential targets for therapeutic strategies to counter resistance in melanoma.

Original language	English
Journal	Molecular Systems Biology
DOIs	https://doi.org/10.1038/s44320-025-00183-5
Publication status	E-pub ahead of print - 18 Feb 2026

Bibliographical note

Publisher Copyright:
© European Molecular Biology Laboratory and the Authors 2026.

Keywords

ARID1A
Data Integration
Drug Resistance
Melanoma
Network Analysis

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Barker, C. G., Sharma, S., Santos, A. M., Nikolakopoulos, K. S., Velentzas, A. D., Tormo-Garcia, C., Sharma, A., Völlmy, F. I., Minia, A., Pliaka, V., Clarke, J., Altelaar, M., Wright, G. J., Alexopoulos, L. G., Stravopodis, D. J., & Petsalaki, E. (2026). Integrative multi-omics defines melanoma drug response networks and ARID1A-dependent resistance mechanisms. Molecular Systems Biology. Advance online publication. https://doi.org/10.1038/s44320-025-00183-5

@article{ff910a329bf446f6905bf5dc4770672a,

title = "Integrative multi-omics defines melanoma drug response networks and ARID1A-dependent resistance mechanisms",

abstract = "Resistance to BRAF/MAPK inhibitors is a significant challenge in melanoma treatment, driven by adaptive and acquired mechanisms allowing tumor cells to evade therapy. We explored early signaling responses to BRAF and MAPK inhibition in a BRAFV600E-sensitive melanoma cell line and a drug-resistant ARID1A-knockout (KO) derivative. ARID1A, frequently mutated in melanoma, is linked to resistance and immune evasion. Through an innovative systems biology approach integrating multi-omics datasets, we identified critical resistance mechanisms. We found that ARID1A-KO cells exhibited transcriptional rewiring, sustaining MAPK1/3 and JNK activity post-treatment, suppressing PRKD1 activation, increasing JUN activity, and disrupting PKC dynamics via elevated RTKs (e.g., EGFR, ROS1) and Ephrin receptor activity. ARID1A-KO also reduced HLA-related protein expression and enhanced extracellular matrix components, potentially limiting immune infiltration and immunotherapy efficacy. Our multi-omics analysis revealed PRKD1, JUN, and NCK1 as key resistance nodes, offering potential targets for therapeutic strategies to counter resistance in melanoma.",

keywords = "ARID1A, Data Integration, Drug Resistance, Melanoma, Network Analysis",

author = "Barker, \{Charlie George\} and Sumana Sharma and Santos, \{Ana Mafalda\} and Nikolakopoulos, \{Konstantinos Stylianos\} and Velentzas, \{Athanassios D.\} and Cristina Tormo-Garcia and Anushka Sharma and V{\"o}llmy, \{Franziska I.\} and Angeliki Minia and Vicky Pliaka and Joseph Clarke and Maarten Altelaar and Wright, \{Gavin J.\} and Alexopoulos, \{Leonidas G.\} and Stravopodis, \{Dimitrios J.\} and Evangelia Petsalaki",

note = "Publisher Copyright: {\textcopyright} European Molecular Biology Laboratory and the Authors 2026.",

year = "2026",

month = feb,

day = "18",

doi = "10.1038/s44320-025-00183-5",

language = "English",

journal = "Molecular Systems Biology",

issn = "1744-4292",

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Barker, CG, Sharma, S, Santos, AM, Nikolakopoulos, KS, Velentzas, AD, Tormo-Garcia, C, Sharma, A, Völlmy, FI, Minia, A, Pliaka, V, Clarke, J, Altelaar, M, Wright, GJ, Alexopoulos, LG, Stravopodis, DJ & Petsalaki, E 2026, 'Integrative multi-omics defines melanoma drug response networks and ARID1A-dependent resistance mechanisms', Molecular Systems Biology. https://doi.org/10.1038/s44320-025-00183-5

TY - JOUR

T1 - Integrative multi-omics defines melanoma drug response networks and ARID1A-dependent resistance mechanisms

AU - Barker, Charlie George

AU - Sharma, Sumana

AU - Santos, Ana Mafalda

AU - Nikolakopoulos, Konstantinos Stylianos

AU - Velentzas, Athanassios D.

AU - Tormo-Garcia, Cristina

AU - Sharma, Anushka

AU - Völlmy, Franziska I.

AU - Minia, Angeliki

AU - Pliaka, Vicky

AU - Clarke, Joseph

AU - Altelaar, Maarten

AU - Wright, Gavin J.

AU - Alexopoulos, Leonidas G.

AU - Stravopodis, Dimitrios J.

AU - Petsalaki, Evangelia

PY - 2026/2/18

Y1 - 2026/2/18

N2 - Resistance to BRAF/MAPK inhibitors is a significant challenge in melanoma treatment, driven by adaptive and acquired mechanisms allowing tumor cells to evade therapy. We explored early signaling responses to BRAF and MAPK inhibition in a BRAFV600E-sensitive melanoma cell line and a drug-resistant ARID1A-knockout (KO) derivative. ARID1A, frequently mutated in melanoma, is linked to resistance and immune evasion. Through an innovative systems biology approach integrating multi-omics datasets, we identified critical resistance mechanisms. We found that ARID1A-KO cells exhibited transcriptional rewiring, sustaining MAPK1/3 and JNK activity post-treatment, suppressing PRKD1 activation, increasing JUN activity, and disrupting PKC dynamics via elevated RTKs (e.g., EGFR, ROS1) and Ephrin receptor activity. ARID1A-KO also reduced HLA-related protein expression and enhanced extracellular matrix components, potentially limiting immune infiltration and immunotherapy efficacy. Our multi-omics analysis revealed PRKD1, JUN, and NCK1 as key resistance nodes, offering potential targets for therapeutic strategies to counter resistance in melanoma.

AB - Resistance to BRAF/MAPK inhibitors is a significant challenge in melanoma treatment, driven by adaptive and acquired mechanisms allowing tumor cells to evade therapy. We explored early signaling responses to BRAF and MAPK inhibition in a BRAFV600E-sensitive melanoma cell line and a drug-resistant ARID1A-knockout (KO) derivative. ARID1A, frequently mutated in melanoma, is linked to resistance and immune evasion. Through an innovative systems biology approach integrating multi-omics datasets, we identified critical resistance mechanisms. We found that ARID1A-KO cells exhibited transcriptional rewiring, sustaining MAPK1/3 and JNK activity post-treatment, suppressing PRKD1 activation, increasing JUN activity, and disrupting PKC dynamics via elevated RTKs (e.g., EGFR, ROS1) and Ephrin receptor activity. ARID1A-KO also reduced HLA-related protein expression and enhanced extracellular matrix components, potentially limiting immune infiltration and immunotherapy efficacy. Our multi-omics analysis revealed PRKD1, JUN, and NCK1 as key resistance nodes, offering potential targets for therapeutic strategies to counter resistance in melanoma.

KW - ARID1A

KW - Data Integration

KW - Drug Resistance

KW - Melanoma

KW - Network Analysis

UR - https://www.scopus.com/pages/publications/105030516713

U2 - 10.1038/s44320-025-00183-5

DO - 10.1038/s44320-025-00183-5

M3 - Article

AN - SCOPUS:105030516713

SN - 1744-4292

JO - Molecular Systems Biology

JF - Molecular Systems Biology

ER -

Integrative multi-omics defines melanoma drug response networks and ARID1A-dependent resistance mechanisms

Abstract

Bibliographical note

Keywords

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