Steering research on mRNA splicing in cancer towards clinical translation

Olga Anczukow; Frédéric H.T. Allain; Brittany L. Angarola; Douglas L. Black; Angela N. Brooks; Chonghui Cheng; Ana Conesa; Edie I. Crosse; Eduardo Eyras; Ernesto Guccione; Sydney X. Lu; Karla M. Neugebauer; Priyanka Sehgal; Xiao Song; Zuzana Tothova; Juan Valcárcel; Kevin M. Weeks; Gene W. Yeo; Andrei Thomas-Tikhonenko

doi:10.1038/s41568-024-00750-2

Steering research on mRNA splicing in cancer towards clinical translation

Olga Anczukow^*, Frédéric H.T. Allain, Brittany L. Angarola, Douglas L. Black, Angela N. Brooks, Chonghui Cheng, Ana Conesa, Edie I. Crosse, Eduardo Eyras, Ernesto Guccione, Sydney X. Lu, Karla M. Neugebauer, Priyanka Sehgal, Xiao Song, Zuzana Tothova, Juan Valcárcel, Kevin M. Weeks, Gene W. Yeo, Andrei Thomas-Tikhonenko^*

^*Corresponding author for this work

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

9 Citations (Scopus)

Abstract

Splicing factors are affected by recurrent somatic mutations and copy number variations in several types of haematologic and solid malignancies, which is often seen as prima facie evidence that splicing aberrations can drive cancer initiation and progression. However, numerous spliceosome components also ‘moonlight’ in DNA repair and other cellular processes, making their precise role in cancer difficult to pinpoint. Still, few would deny that dysregulated mRNA splicing is a pervasive feature of most cancers. Correctly interpreting these molecular fingerprints can reveal novel tumour vulnerabilities and untapped therapeutic opportunities. Yet multiple technological challenges, lingering misconceptions, and outstanding questions hinder clinical translation. To start with, the general landscape of splicing aberrations in cancer is not well defined, due to limitations of short-read RNA sequencing not adept at resolving complete mRNA isoforms, as well as the shallow read depth inherent in long-read RNA-sequencing, especially at single-cell level. Although individual cancer-associated isoforms are known to contribute to cancer progression, widespread splicing alterations could be an equally important and, perhaps, more readily actionable feature of human cancers. This is to say that in addition to ‘repairing’ mis-spliced transcripts, possible therapeutic avenues include exacerbating splicing aberration with small-molecule spliceosome inhibitors, targeting recurrent splicing aberrations with synthetic lethal approaches, and training the immune system to recognize splicing-derived neoantigens.

Original language	English
Pages (from-to)	887-905
Number of pages	19
Journal	Nature Reviews Cancer
Volume	24
Issue number	12
DOIs	https://doi.org/10.1038/s41568-024-00750-2
Publication status	Published - Dec 2024

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Anczukow, O., Allain, F. H. T., Angarola, B. L., Black, D. L., Brooks, A. N., Cheng, C., Conesa, A., Crosse, E. I., Eyras, E., Guccione, E., Lu, S. X., Neugebauer, K. M., Sehgal, P., Song, X., Tothova, Z., Valcárcel, J., Weeks, K. M., Yeo, G. W., & Thomas-Tikhonenko, A. (2024). Steering research on mRNA splicing in cancer towards clinical translation. Nature Reviews Cancer, 24(12), 887-905. https://doi.org/10.1038/s41568-024-00750-2

@article{befa5c33eb9d4181aa367dd78551811f,

title = "Steering research on mRNA splicing in cancer towards clinical translation",

abstract = "Splicing factors are affected by recurrent somatic mutations and copy number variations in several types of haematologic and solid malignancies, which is often seen as prima facie evidence that splicing aberrations can drive cancer initiation and progression. However, numerous spliceosome components also {\textquoteleft}moonlight{\textquoteright} in DNA repair and other cellular processes, making their precise role in cancer difficult to pinpoint. Still, few would deny that dysregulated mRNA splicing is a pervasive feature of most cancers. Correctly interpreting these molecular fingerprints can reveal novel tumour vulnerabilities and untapped therapeutic opportunities. Yet multiple technological challenges, lingering misconceptions, and outstanding questions hinder clinical translation. To start with, the general landscape of splicing aberrations in cancer is not well defined, due to limitations of short-read RNA sequencing not adept at resolving complete mRNA isoforms, as well as the shallow read depth inherent in long-read RNA-sequencing, especially at single-cell level. Although individual cancer-associated isoforms are known to contribute to cancer progression, widespread splicing alterations could be an equally important and, perhaps, more readily actionable feature of human cancers. This is to say that in addition to {\textquoteleft}repairing{\textquoteright} mis-spliced transcripts, possible therapeutic avenues include exacerbating splicing aberration with small-molecule spliceosome inhibitors, targeting recurrent splicing aberrations with synthetic lethal approaches, and training the immune system to recognize splicing-derived neoantigens.",

author = "Olga Anczukow and Allain, {Fr{\'e}d{\'e}ric H.T.} and Angarola, {Brittany L.} and Black, {Douglas L.} and Brooks, {Angela N.} and Chonghui Cheng and Ana Conesa and Crosse, {Edie I.} and Eduardo Eyras and Ernesto Guccione and Lu, {Sydney X.} and Neugebauer, {Karla M.} and Priyanka Sehgal and Xiao Song and Zuzana Tothova and Juan Valc{\'a}rcel and Weeks, {Kevin M.} and Yeo, {Gene W.} and Andrei Thomas-Tikhonenko",

note = "Publisher Copyright: {\textcopyright} Springer Nature Limited 2024.",

year = "2024",

month = dec,

doi = "10.1038/s41568-024-00750-2",

language = "English",

volume = "24",

pages = "887--905",

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Anczukow, O, Allain, FHT, Angarola, BL, Black, DL, Brooks, AN, Cheng, C, Conesa, A, Crosse, EI, Eyras, E, Guccione, E, Lu, SX, Neugebauer, KM, Sehgal, P, Song, X, Tothova, Z, Valcárcel, J, Weeks, KM, Yeo, GW & Thomas-Tikhonenko, A 2024, 'Steering research on mRNA splicing in cancer towards clinical translation', Nature Reviews Cancer, vol. 24, no. 12, pp. 887-905. https://doi.org/10.1038/s41568-024-00750-2

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T1 - Steering research on mRNA splicing in cancer towards clinical translation

AU - Anczukow, Olga

AU - Allain, Frédéric H.T.

AU - Angarola, Brittany L.

AU - Black, Douglas L.

AU - Brooks, Angela N.

AU - Cheng, Chonghui

AU - Conesa, Ana

AU - Crosse, Edie I.

AU - Eyras, Eduardo

AU - Guccione, Ernesto

AU - Lu, Sydney X.

AU - Neugebauer, Karla M.

AU - Sehgal, Priyanka

AU - Song, Xiao

AU - Tothova, Zuzana

AU - Valcárcel, Juan

AU - Weeks, Kevin M.

AU - Yeo, Gene W.

AU - Thomas-Tikhonenko, Andrei

PY - 2024/12

Y1 - 2024/12

N2 - Splicing factors are affected by recurrent somatic mutations and copy number variations in several types of haematologic and solid malignancies, which is often seen as prima facie evidence that splicing aberrations can drive cancer initiation and progression. However, numerous spliceosome components also ‘moonlight’ in DNA repair and other cellular processes, making their precise role in cancer difficult to pinpoint. Still, few would deny that dysregulated mRNA splicing is a pervasive feature of most cancers. Correctly interpreting these molecular fingerprints can reveal novel tumour vulnerabilities and untapped therapeutic opportunities. Yet multiple technological challenges, lingering misconceptions, and outstanding questions hinder clinical translation. To start with, the general landscape of splicing aberrations in cancer is not well defined, due to limitations of short-read RNA sequencing not adept at resolving complete mRNA isoforms, as well as the shallow read depth inherent in long-read RNA-sequencing, especially at single-cell level. Although individual cancer-associated isoforms are known to contribute to cancer progression, widespread splicing alterations could be an equally important and, perhaps, more readily actionable feature of human cancers. This is to say that in addition to ‘repairing’ mis-spliced transcripts, possible therapeutic avenues include exacerbating splicing aberration with small-molecule spliceosome inhibitors, targeting recurrent splicing aberrations with synthetic lethal approaches, and training the immune system to recognize splicing-derived neoantigens.

AB - Splicing factors are affected by recurrent somatic mutations and copy number variations in several types of haematologic and solid malignancies, which is often seen as prima facie evidence that splicing aberrations can drive cancer initiation and progression. However, numerous spliceosome components also ‘moonlight’ in DNA repair and other cellular processes, making their precise role in cancer difficult to pinpoint. Still, few would deny that dysregulated mRNA splicing is a pervasive feature of most cancers. Correctly interpreting these molecular fingerprints can reveal novel tumour vulnerabilities and untapped therapeutic opportunities. Yet multiple technological challenges, lingering misconceptions, and outstanding questions hinder clinical translation. To start with, the general landscape of splicing aberrations in cancer is not well defined, due to limitations of short-read RNA sequencing not adept at resolving complete mRNA isoforms, as well as the shallow read depth inherent in long-read RNA-sequencing, especially at single-cell level. Although individual cancer-associated isoforms are known to contribute to cancer progression, widespread splicing alterations could be an equally important and, perhaps, more readily actionable feature of human cancers. This is to say that in addition to ‘repairing’ mis-spliced transcripts, possible therapeutic avenues include exacerbating splicing aberration with small-molecule spliceosome inhibitors, targeting recurrent splicing aberrations with synthetic lethal approaches, and training the immune system to recognize splicing-derived neoantigens.

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JO - Nature Reviews Cancer

JF - Nature Reviews Cancer

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ER -

Steering research on mRNA splicing in cancer towards clinical translation

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