Human Tra2 proteins jointly control a CHEK1 splicing switch among alternative and constitutive target exons.

Andrew Best; Katherine James; Caroline Dalgliesh; Elaine Hong; Mahsa Kheirolahi-Kouhestani; Tomaz Curk; Yaobo Xu; Marina Danilenko; Rafiq Hussain; Bernard Keavney; Anil Wipat; Roscoe Klinck; Ian G Cowell; Ka Cheong Lee; Caroline A Austin; Julian P Venables; Benoit Chabot; Mauro Santibanez Koref; Alison Tyson-Capper; David J Elliott

doi:10.1038/ncomms5760

Human Tra2 proteins jointly control a CHEK1 splicing switch among alternative and constitutive target exons.

Andrew Best, Katherine James, Caroline Dalgliesh, Elaine Hong, Mahsa Kheirolahi-Kouhestani, Tomaz Curk, Yaobo Xu, Marina Danilenko, Rafiq Hussain, Bernard Keavney, Anil Wipat, Roscoe Klinck, Ian G Cowell, Ka Cheong Lee, Caroline A Austin, Julian P Venables, Benoit Chabot, Mauro Santibanez Koref, Alison Tyson-Capper, David J Elliott

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

Abstract

Alternative splicing--the production of multiple messenger RNA isoforms from a single gene--is regulated in part by RNA binding proteins. While the RBPs transformer2 alpha (Tra2α) and Tra2β have both been implicated in the regulation of alternative splicing, their relative contributions to this process are not well understood. Here we find simultaneous--but not individual--depletion of Tra2α and Tra2β induces substantial shifts in splicing of endogenous Tra2β target exons, and that both constitutive and alternative target exons are under dual Tra2α-Tra2β control. Target exons are enriched in genes associated with chromosome biology including CHEK1, which encodes a key DNA damage response protein. Dual Tra2 protein depletion reduces expression of full-length CHK1 protein, results in the accumulation of the DNA damage marker γH2AX and decreased cell viability. We conclude Tra2 proteins jointly control constitutive and alternative splicing patterns via paralog compensation to control pathways essential to the maintenance of cell viability.

Original language	English
Pages (from-to)	4760
Journal	Nature Communications
Volume	5
DOIs	https://doi.org/10.1038/ncomms5760
Publication status	Published - 11 Sept 2014

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Best, A., James, K., Dalgliesh, C., Hong, E., Kheirolahi-Kouhestani, M., Curk, T., Xu, Y., Danilenko, M., Hussain, R., Keavney, B., Wipat, A., Klinck, R., Cowell, I. G., Cheong Lee, K., Austin, C. A., Venables, J. P., Chabot, B., Santibanez Koref, M., Tyson-Capper, A., & Elliott, D. J. (2014). Human Tra2 proteins jointly control a CHEK1 splicing switch among alternative and constitutive target exons. Nature Communications, 5, 4760. https://doi.org/10.1038/ncomms5760

@article{cb1ecc83b6514b1788901f7dc5856920,

title = "Human Tra2 proteins jointly control a CHEK1 splicing switch among alternative and constitutive target exons.",

abstract = "Alternative splicing--the production of multiple messenger RNA isoforms from a single gene--is regulated in part by RNA binding proteins. While the RBPs transformer2 alpha (Tra2α) and Tra2β have both been implicated in the regulation of alternative splicing, their relative contributions to this process are not well understood. Here we find simultaneous--but not individual--depletion of Tra2α and Tra2β induces substantial shifts in splicing of endogenous Tra2β target exons, and that both constitutive and alternative target exons are under dual Tra2α-Tra2β control. Target exons are enriched in genes associated with chromosome biology including CHEK1, which encodes a key DNA damage response protein. Dual Tra2 protein depletion reduces expression of full-length CHK1 protein, results in the accumulation of the DNA damage marker γH2AX and decreased cell viability. We conclude Tra2 proteins jointly control constitutive and alternative splicing patterns via paralog compensation to control pathways essential to the maintenance of cell viability.",

author = "Andrew Best and Katherine James and Caroline Dalgliesh and Elaine Hong and Mahsa Kheirolahi-Kouhestani and Tomaz Curk and Yaobo Xu and Marina Danilenko and Rafiq Hussain and Bernard Keavney and Anil Wipat and Roscoe Klinck and Cowell, {Ian G} and {Cheong Lee}, Ka and Austin, {Caroline A} and Venables, {Julian P} and Benoit Chabot and {Santibanez Koref}, Mauro and Alison Tyson-Capper and Elliott, {David J}",

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year = "2014",

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doi = "10.1038/ncomms5760",

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Best, A, James, K, Dalgliesh, C, Hong, E, Kheirolahi-Kouhestani, M, Curk, T, Xu, Y, Danilenko, M, Hussain, R, Keavney, B, Wipat, A, Klinck, R, Cowell, IG, Cheong Lee, K, Austin, CA, Venables, JP, Chabot, B, Santibanez Koref, M, Tyson-Capper, A & Elliott, DJ 2014, 'Human Tra2 proteins jointly control a CHEK1 splicing switch among alternative and constitutive target exons.', Nature Communications, vol. 5, pp. 4760. https://doi.org/10.1038/ncomms5760

TY - JOUR

T1 - Human Tra2 proteins jointly control a CHEK1 splicing switch among alternative and constitutive target exons.

AU - Best, Andrew

AU - James, Katherine

AU - Dalgliesh, Caroline

AU - Hong, Elaine

AU - Kheirolahi-Kouhestani, Mahsa

AU - Curk, Tomaz

AU - Xu, Yaobo

AU - Danilenko, Marina

AU - Hussain, Rafiq

AU - Keavney, Bernard

AU - Wipat, Anil

AU - Klinck, Roscoe

AU - Cowell, Ian G

AU - Cheong Lee, Ka

AU - Austin, Caroline A

AU - Venables, Julian P

AU - Chabot, Benoit

AU - Santibanez Koref, Mauro

AU - Tyson-Capper, Alison

AU - Elliott, David J

N1 - 2009NOVPHD21, Breast Cancer Now, United KingdomBB/D013917/1, Biotechnology and Biological Sciences Research Council, United KingdomBB/I006923/1, Biotechnology and Biological Sciences Research Council, United KingdomFS/10/008/28146, British Heart Foundation, United KingdomFS/11/63/28944, British Heart Foundation, United KingdomMOP93917, Canadian Institutes of Health Research, CanadaWT080368MA, Wellcome Trust, United KingdomWT089225/Z/09/Z, Wellcome Trust, United Kingdom

PY - 2014/9/11

Y1 - 2014/9/11

N2 - Alternative splicing--the production of multiple messenger RNA isoforms from a single gene--is regulated in part by RNA binding proteins. While the RBPs transformer2 alpha (Tra2α) and Tra2β have both been implicated in the regulation of alternative splicing, their relative contributions to this process are not well understood. Here we find simultaneous--but not individual--depletion of Tra2α and Tra2β induces substantial shifts in splicing of endogenous Tra2β target exons, and that both constitutive and alternative target exons are under dual Tra2α-Tra2β control. Target exons are enriched in genes associated with chromosome biology including CHEK1, which encodes a key DNA damage response protein. Dual Tra2 protein depletion reduces expression of full-length CHK1 protein, results in the accumulation of the DNA damage marker γH2AX and decreased cell viability. We conclude Tra2 proteins jointly control constitutive and alternative splicing patterns via paralog compensation to control pathways essential to the maintenance of cell viability.

AB - Alternative splicing--the production of multiple messenger RNA isoforms from a single gene--is regulated in part by RNA binding proteins. While the RBPs transformer2 alpha (Tra2α) and Tra2β have both been implicated in the regulation of alternative splicing, their relative contributions to this process are not well understood. Here we find simultaneous--but not individual--depletion of Tra2α and Tra2β induces substantial shifts in splicing of endogenous Tra2β target exons, and that both constitutive and alternative target exons are under dual Tra2α-Tra2β control. Target exons are enriched in genes associated with chromosome biology including CHEK1, which encodes a key DNA damage response protein. Dual Tra2 protein depletion reduces expression of full-length CHK1 protein, results in the accumulation of the DNA damage marker γH2AX and decreased cell viability. We conclude Tra2 proteins jointly control constitutive and alternative splicing patterns via paralog compensation to control pathways essential to the maintenance of cell viability.

U2 - 10.1038/ncomms5760

DO - 10.1038/ncomms5760

M3 - Article

C2 - 25208576

SN - 2041-1723

VL - 5

SP - 4760

JO - Nature Communications

JF - Nature Communications

ER -

Human Tra2 proteins jointly control a CHEK1 splicing switch among alternative and constitutive target exons.

Abstract

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