Spatially interacting phosphorylation sites and mutations in cancer

Kuan lin Huang; Adam D. Scott; Daniel Cui Zhou; Liang Bo Wang; Amila Weerasinghe; Abdulkadir Elmas; Ruiyang Liu; Yige Wu; Michael C. Wendl; Matthew A. Wyczalkowski; Jessika Baral; Sohini Sengupta; Chin Wen Lai; Kelly Ruggles; Samuel H. Payne; Benjamin Raphael; David Fenyö; Ken Chen; Gordon Mills; Li Ding

doi:10.1038/s41467-021-22481-w

Spatially interacting phosphorylation sites and mutations in cancer

Kuan lin Huang, Adam D. Scott, Daniel Cui Zhou, Liang Bo Wang, Amila Weerasinghe, Abdulkadir Elmas, Ruiyang Liu, Yige Wu, Michael C. Wendl, Matthew A. Wyczalkowski, Jessika Baral, Sohini Sengupta, Chin Wen Lai, Kelly Ruggles, Samuel H. Payne, Benjamin Raphael, David Fenyö, Ken Chen, Gordon Mills, Li Ding

Cell Developmental and Cancer Biology

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

10 Scopus citations

Abstract

Advances in mass-spectrometry have generated increasingly large-scale proteomics datasets containing tens of thousands of phosphorylation sites (phosphosites) that require prioritization. We develop a bioinformatics tool called HotPho and systematically discover 3D co-clustering of phosphosites and cancer mutations on protein structures. HotPho identifies 474 such hybrid clusters containing 1255 co-clustering phosphosites, including RET p.S904/Y928, the conserved HRAS/KRAS p.Y96, and IDH1 p.Y139/IDH2 p.Y179 that are adjacent to recurrent mutations on protein structures not found by linear proximity approaches. Hybrid clusters, enriched in histone and kinase domains, frequently include expression-associated mutations experimentally shown as activating and conferring genetic dependency. Approximately 300 co-clustering phosphosites are verified in patient samples of 5 cancer types or previously implicated in cancer, including CTNNB1 p.S29/Y30, EGFR p.S720, MAPK1 p.S142, and PTPN12 p.S275. In summary, systematic 3D clustering analysis highlights nearly 3,000 likely functional mutations and over 1000 cancer phosphosites for downstream investigation and evaluation of potential clinical relevance.

Original language	English (US)
Article number	2313
Journal	Nature communications
Volume	12
Issue number	1
DOIs	https://doi.org/10.1038/s41467-021-22481-w
State	Published - Dec 1 2021

ASJC Scopus subject areas

General Chemistry
General Biochemistry, Genetics and Molecular Biology
General
General Physics and Astronomy

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Huang, K. L., Scott, A. D., Zhou, D. C., Wang, L. B., Weerasinghe, A., Elmas, A., Liu, R., Wu, Y., Wendl, M. C., Wyczalkowski, M. A., Baral, J., Sengupta, S., Lai, C. W., Ruggles, K., Payne, S. H., Raphael, B., Fenyö, D., Chen, K., Mills, G., & Ding, L. (2021). Spatially interacting phosphorylation sites and mutations in cancer. Nature communications, 12(1), Article 2313. https://doi.org/10.1038/s41467-021-22481-w

Huang, KL, Scott, AD, Zhou, DC, Wang, LB, Weerasinghe, A, Elmas, A, Liu, R, Wu, Y, Wendl, MC, Wyczalkowski, MA, Baral, J, Sengupta, S, Lai, CW, Ruggles, K, Payne, SH, Raphael, B, Fenyö, D, Chen, K, Mills, G & Ding, L 2021, 'Spatially interacting phosphorylation sites and mutations in cancer', Nature communications, vol. 12, no. 1, 2313. https://doi.org/10.1038/s41467-021-22481-w

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abstract = "Advances in mass-spectrometry have generated increasingly large-scale proteomics datasets containing tens of thousands of phosphorylation sites (phosphosites) that require prioritization. We develop a bioinformatics tool called HotPho and systematically discover 3D co-clustering of phosphosites and cancer mutations on protein structures. HotPho identifies 474 such hybrid clusters containing 1255 co-clustering phosphosites, including RET p.S904/Y928, the conserved HRAS/KRAS p.Y96, and IDH1 p.Y139/IDH2 p.Y179 that are adjacent to recurrent mutations on protein structures not found by linear proximity approaches. Hybrid clusters, enriched in histone and kinase domains, frequently include expression-associated mutations experimentally shown as activating and conferring genetic dependency. Approximately 300 co-clustering phosphosites are verified in patient samples of 5 cancer types or previously implicated in cancer, including CTNNB1 p.S29/Y30, EGFR p.S720, MAPK1 p.S142, and PTPN12 p.S275. In summary, systematic 3D clustering analysis highlights nearly 3,000 likely functional mutations and over 1000 cancer phosphosites for downstream investigation and evaluation of potential clinical relevance.",

author = "Huang, {Kuan lin} and Scott, {Adam D.} and Zhou, {Daniel Cui} and Wang, {Liang Bo} and Amila Weerasinghe and Abdulkadir Elmas and Ruiyang Liu and Yige Wu and Wendl, {Michael C.} and Wyczalkowski, {Matthew A.} and Jessika Baral and Sohini Sengupta and Lai, {Chin Wen} and Kelly Ruggles and Payne, {Samuel H.} and Benjamin Raphael and David Feny{\"o} and Ken Chen and Gordon Mills and Li Ding",

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AU - Scott, Adam D.

AU - Zhou, Daniel Cui

AU - Wang, Liang Bo

AU - Weerasinghe, Amila

AU - Elmas, Abdulkadir

AU - Liu, Ruiyang

AU - Wu, Yige

AU - Wendl, Michael C.

AU - Wyczalkowski, Matthew A.

AU - Baral, Jessika

AU - Sengupta, Sohini

AU - Lai, Chin Wen

AU - Ruggles, Kelly

AU - Payne, Samuel H.

AU - Raphael, Benjamin

AU - Fenyö, David

AU - Chen, Ken

AU - Mills, Gordon

AU - Ding, Li

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AB - Advances in mass-spectrometry have generated increasingly large-scale proteomics datasets containing tens of thousands of phosphorylation sites (phosphosites) that require prioritization. We develop a bioinformatics tool called HotPho and systematically discover 3D co-clustering of phosphosites and cancer mutations on protein structures. HotPho identifies 474 such hybrid clusters containing 1255 co-clustering phosphosites, including RET p.S904/Y928, the conserved HRAS/KRAS p.Y96, and IDH1 p.Y139/IDH2 p.Y179 that are adjacent to recurrent mutations on protein structures not found by linear proximity approaches. Hybrid clusters, enriched in histone and kinase domains, frequently include expression-associated mutations experimentally shown as activating and conferring genetic dependency. Approximately 300 co-clustering phosphosites are verified in patient samples of 5 cancer types or previously implicated in cancer, including CTNNB1 p.S29/Y30, EGFR p.S720, MAPK1 p.S142, and PTPN12 p.S275. In summary, systematic 3D clustering analysis highlights nearly 3,000 likely functional mutations and over 1000 cancer phosphosites for downstream investigation and evaluation of potential clinical relevance.

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Spatially interacting phosphorylation sites and mutations in cancer

Abstract

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