The subclonal complexity of STIL-TAL1+ T-cell acute lymphoblastic leukaemia

Caroline L Furness; Marcela Mansur; victoria weston; Luca Ermini; Frederik van Delft; Sarah Jenkinson; Rosemary Gale; Christine J Harrison; Maria S Pombo-de-Oliveira; Marta Sanchez-Martin; Adolfo A Ferrando; Pamela Kearns; Ian Titley; Anthony M Ford; Nicola E Potter; Mel Greaves

doi:10.1038/s41375-018-0046-8

The subclonal complexity of STIL-TAL1+ T-cell acute lymphoblastic leukaemia

Caroline L Furness, Marcela Mansur, victoria weston, Luca Ermini, Frederik van Delft, Sarah Jenkinson, Rosemary Gale, Christine J Harrison, Maria S Pombo-de-Oliveira, Marta Sanchez-Martin, Adolfo A Ferrando, Pamela Kearns, Ian Titley, Anthony M Ford, Nicola E Potter, Mel Greaves

Cancer Clinical Trials Unit

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

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Abstract

Single-cell genetics were used to interrogate clonal complexity and the sequence of mutational events in STIL-TAL1+ T-ALL. Single-cell multicolour FISH was used to demonstrate that the earliest detectable leukaemia subclone contained the STIL-TAL1 fusion and copy number loss of 9p21.3 (CDKN2A/CDKN2B locus), with other copy number alterations including loss of PTEN occurring as secondary subclonal events. In three cases, multiplex qPCR and phylogenetic analysis were used to produce branching evolutionary trees recapitulating the snapshot history of T-ALL evolution in this leukaemia subtype, which confirmed that mutations in key T-ALL drivers, including NOTCH1 and PTEN, were subclonal and reiterative in distinct subclones. Xenografting confirmed that self-renewing or propagating cells were genetically diverse. These data suggest that the STIL-TAL1 fusion is a likely founder or truncal event. Therapies targeting the TAL1 auto-regulatory complex are worthy of further investigation in T-ALL.

Original language	English
Number of pages	10
Journal	Leukemia
Early online date	20 Mar 2018
DOIs	https://doi.org/10.1038/s41375-018-0046-8
Publication status	E-pub ahead of print - 20 Mar 2018

Keywords

cancer genomics
oncogenesis

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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The subclonal complexity of STIL-TAL1+ T-cell acute lymphoblastic leukaemiaFinal published version, 1.29 MBLicence: Creative Commons: Attribution (CC BY)

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Furness, C. L., Mansur, M., weston, V., Ermini, L., van Delft, F., Jenkinson, S., Gale, R., Harrison, C. J., Pombo-de-Oliveira, M. S., Sanchez-Martin, M., Ferrando, A. A., Kearns, P., Titley, I., Ford, A. M., Potter, N. E., & Greaves, M. (2018). The subclonal complexity of STIL-TAL1+ T-cell acute lymphoblastic leukaemia. Leukemia. Advance online publication. https://doi.org/10.1038/s41375-018-0046-8

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title = "The subclonal complexity of STIL-TAL1+ T-cell acute lymphoblastic leukaemia",

abstract = "Single-cell genetics were used to interrogate clonal complexity and the sequence of mutational events in STIL-TAL1+ T-ALL. Single-cell multicolour FISH was used to demonstrate that the earliest detectable leukaemia subclone contained the STIL-TAL1 fusion and copy number loss of 9p21.3 (CDKN2A/CDKN2B locus), with other copy number alterations including loss of PTEN occurring as secondary subclonal events. In three cases, multiplex qPCR and phylogenetic analysis were used to produce branching evolutionary trees recapitulating the snapshot history of T-ALL evolution in this leukaemia subtype, which confirmed that mutations in key T-ALL drivers, including NOTCH1 and PTEN, were subclonal and reiterative in distinct subclones. Xenografting confirmed that self-renewing or propagating cells were genetically diverse. These data suggest that the STIL-TAL1 fusion is a likely founder or truncal event. Therapies targeting the TAL1 auto-regulatory complex are worthy of further investigation in T-ALL.",

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author = "Furness, {Caroline L} and Marcela Mansur and victoria weston and Luca Ermini and {van Delft}, Frederik and Sarah Jenkinson and Rosemary Gale and Harrison, {Christine J} and Pombo-de-Oliveira, {Maria S} and Marta Sanchez-Martin and Ferrando, {Adolfo A} and Pamela Kearns and Ian Titley and Ford, {Anthony M} and Potter, {Nicola E} and Mel Greaves",

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AU - Furness, Caroline L

AU - Mansur, Marcela

AU - weston, victoria

AU - Ermini, Luca

AU - van Delft, Frederik

AU - Jenkinson, Sarah

AU - Gale, Rosemary

AU - Harrison, Christine J

AU - Pombo-de-Oliveira, Maria S

AU - Sanchez-Martin, Marta

AU - Ferrando, Adolfo A

AU - Kearns, Pamela

AU - Titley, Ian

AU - Ford, Anthony M

AU - Potter, Nicola E

AU - Greaves, Mel

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N2 - Single-cell genetics were used to interrogate clonal complexity and the sequence of mutational events in STIL-TAL1+ T-ALL. Single-cell multicolour FISH was used to demonstrate that the earliest detectable leukaemia subclone contained the STIL-TAL1 fusion and copy number loss of 9p21.3 (CDKN2A/CDKN2B locus), with other copy number alterations including loss of PTEN occurring as secondary subclonal events. In three cases, multiplex qPCR and phylogenetic analysis were used to produce branching evolutionary trees recapitulating the snapshot history of T-ALL evolution in this leukaemia subtype, which confirmed that mutations in key T-ALL drivers, including NOTCH1 and PTEN, were subclonal and reiterative in distinct subclones. Xenografting confirmed that self-renewing or propagating cells were genetically diverse. These data suggest that the STIL-TAL1 fusion is a likely founder or truncal event. Therapies targeting the TAL1 auto-regulatory complex are worthy of further investigation in T-ALL.

AB - Single-cell genetics were used to interrogate clonal complexity and the sequence of mutational events in STIL-TAL1+ T-ALL. Single-cell multicolour FISH was used to demonstrate that the earliest detectable leukaemia subclone contained the STIL-TAL1 fusion and copy number loss of 9p21.3 (CDKN2A/CDKN2B locus), with other copy number alterations including loss of PTEN occurring as secondary subclonal events. In three cases, multiplex qPCR and phylogenetic analysis were used to produce branching evolutionary trees recapitulating the snapshot history of T-ALL evolution in this leukaemia subtype, which confirmed that mutations in key T-ALL drivers, including NOTCH1 and PTEN, were subclonal and reiterative in distinct subclones. Xenografting confirmed that self-renewing or propagating cells were genetically diverse. These data suggest that the STIL-TAL1 fusion is a likely founder or truncal event. Therapies targeting the TAL1 auto-regulatory complex are worthy of further investigation in T-ALL.

KW - cancer genomics

KW - oncogenesis

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DO - 10.1038/s41375-018-0046-8

M3 - Article

SN - 0887-6924

JO - Leukemia

JF - Leukemia

ER -

The subclonal complexity of STIL-TAL1+ T-cell acute lymphoblastic leukaemia

Abstract

Keywords

UN SDGs

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