Deciphering <i>TP53</i> mutant Cancer Evolution with Single-Cell Multi-Omics

Alba Rodríguez-Meira; Ruggiero Norfo; Wei Wen; Agathe L. Chédeville; Haseeb Rahman; Jennifer O’Sullivan; Guanlin Wang; Eleni Louka; Warren W. Kretzschmar; Aimee Paterson; Charlotte Brierley; Jean‐Edouard Martin; Caroline Demeule; Matthew Bashton; Nikolaos Sousos; Angela Hamblin; Hélène Guermouche; Florence Pasquier; Christophe Marzac; François Girodon; Mark W. Drummond; Claire Harrison; Isabelle Plo; Sten Eirik W. Jacobsen; Bethan Psaila; Supat Thongjuea; Iléana Antony‐Debré; Adam J. Mead

doi:10.1101/2022.03.28.485984

Deciphering <i>TP53</i> mutant Cancer Evolution with Single-Cell Multi-Omics

Alba Rodríguez-Meira(University of Oxford), Ruggiero Norfo(University of Oxford), Wei Wen(University of Oxford), Agathe L. Chédeville(Inserm), Haseeb Rahman(University of Oxford), Jennifer O’Sullivan(University of Oxford), Guanlin Wang(University of Oxford), Eleni Louka(University of Oxford), Warren W. Kretzschmar(Karolinska University Hospital), Aimee Paterson(University of Oxford), Charlotte Brierley(Memorial Sloan Kettering Cancer Center), Jean‐Edouard Martin(Inserm), Caroline Demeule(CHU Dijon Bourgogne), Matthew Bashton(Northumbria University), Nikolaos Sousos(University of Oxford), Angela Hamblin(National Institute for Health and Care Research), Hélène Guermouche(Inserm), Florence Pasquier(Inserm), Christophe Marzac(Inserm), François Girodon(Inserm), Mark W. Drummond(Beatson West of Scotland Cancer Centre), Claire Harrison(Guy's and St Thomas' NHS Foundation Trust), Isabelle Plo(Inserm), Sten Eirik W. Jacobsen(Karolinska University Hospital), Bethan Psaila(University of Oxford), Supat Thongjuea(University of Oxford), Iléana Antony‐Debré(Inserm), Adam J. Mead(University of Oxford)

bioRxiv (Cold Spring Harbor Laboratory)

March 29, 2022

10.1101/2022.03.28.485984

Cited by 12Open Access

Full Text

Abstract

Summary TP53 is the most commonly mutated gene in human cancer, typically occurring in association with complex cytogenetics and dismal outcomes. Understanding the genetic and non-genetic determinants of TP53- mutation driven clonal evolution and subsequent transformation is a crucial step towards the design of rational therapeutic strategies. Here, we carry out allelic resolution single-cell multi-omic analysis of haematopoietic stem/progenitor cells (HSPC) from patients with a myeloproliferative neoplasm who transform to TP53- mutant secondary acute myeloid leukaemia (AML), a tractable model of TP53 -mutant cancer evolution. All patients showed dominant TP53 ‘ multi-hit’ HSPC clones at transformation, with a leukaemia stem cell transcriptional signature strongly predictive of adverse outcome in independent cohorts, across both TP53- mutant and wild-type AML. Through analysis of serial samples and antecedent TP53 -heterozygous clones, we demonstrate a hitherto unrecognised effect of chronic inflammation, which supressed TP53 wild-type HSPC whilst enhancing the fitness advantage of TP53 mutant cells. Our findings will facilitate the development of risk-stratification, early detection and treatment strategies for TP53 -mutant leukaemia, and are of broader relevance to other cancer types.

Related Papers

No related papers found

Powered by citation graph analysis