Structure–function relationships explain CTCF zinc finger mutation phenotypes in cancer

Charles G. Bailey; Shailendra Gupta; Cynthia Metierre; Punkaja M.S. Amarasekera; Patrick O’Young; Wunna Kyaw; Tatyana Laletin; Habib Francis; Crystal Semaan; Mehdi Sharifi Tabar; Krishna P. Singh; Charles G. Mullighan; Olaf Wolkenhauer; Ulf Schmitz; John E.J. Rasko

doi:10.1007/s00018-021-03946-z

Structure–function relationships explain CTCF zinc finger mutation phenotypes in cancer

Charles G. Bailey, Shailendra Gupta, Cynthia Metierre, Punkaja M.S. Amarasekera, Patrick O’Young, Wunna Kyaw, Tatyana Laletin, Habib Francis, Crystal Semaan, Mehdi Sharifi Tabar, Krishna P. Singh, Charles G. Mullighan, Olaf Wolkenhauer, Ulf Schmitz, John E.J. Rasko^*

^*Corresponding author for this work

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

12 Scopus citations

Abstract

CCCTC-binding factor (CTCF) plays fundamental roles in transcriptional regulation and chromatin architecture maintenance. CTCF is also a tumour suppressor frequently mutated in cancer, however, the structural and functional impact of mutations have not been examined. We performed molecular and structural characterisation of five cancer-specific CTCF missense zinc finger (ZF) mutations occurring within key intra- and inter-ZF residues. Functional characterisation of CTCF ZF mutations revealed a complete (L309P, R339W, R377H) or intermediate (R339Q) abrogation as well as an enhancement (G420D) of the anti-proliferative effects of CTCF. DNA binding at select sites was disrupted and transcriptional regulatory activities abrogated. Molecular docking and molecular dynamics confirmed that mutations in residues specifically contacting DNA bases or backbone exhibited loss of DNA binding. However, R339Q and G420D were stabilised by the formation of new primary DNA bonds, contributing to gain-of-function. Our data confirm that a spectrum of loss-, change- and gain-of-function impacts on CTCF zinc fingers are observed in cell growth regulation and gene regulatory activities. Hence, diverse cellular phenotypes of mutant CTCF are clearly explained by examining structure–function relationships.

Original language	English
Pages (from-to)	7519-7536
Number of pages	18
Journal	Cellular and Molecular Life Sciences
Volume	78
Issue number	23
DOIs	https://doi.org/10.1007/s00018-021-03946-z
State	Published - Dec 2021
Externally published	Yes

Keywords

CTCF
Cancer
Gain-of-function
Loss-of-function
Molecular docking
Molecular dynamics
Somatic mutation
Zinc finger

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Bailey, C. G., Gupta, S., Metierre, C., Amarasekera, P. M. S., O’Young, P., Kyaw, W., Laletin, T., Francis, H., Semaan, C., Sharifi Tabar, M., Singh, K. P., Mullighan, C. G., Wolkenhauer, O., Schmitz, U., & Rasko, J. E. J. (2021). Structure–function relationships explain CTCF zinc finger mutation phenotypes in cancer. Cellular and Molecular Life Sciences, 78(23), 7519-7536. https://doi.org/10.1007/s00018-021-03946-z

@article{7d6fea6195c747a69ff2a2ecb0ced9f8,

title = "Structure–function relationships explain CTCF zinc finger mutation phenotypes in cancer",

abstract = "CCCTC-binding factor (CTCF) plays fundamental roles in transcriptional regulation and chromatin architecture maintenance. CTCF is also a tumour suppressor frequently mutated in cancer, however, the structural and functional impact of mutations have not been examined. We performed molecular and structural characterisation of five cancer-specific CTCF missense zinc finger (ZF) mutations occurring within key intra- and inter-ZF residues. Functional characterisation of CTCF ZF mutations revealed a complete (L309P, R339W, R377H) or intermediate (R339Q) abrogation as well as an enhancement (G420D) of the anti-proliferative effects of CTCF. DNA binding at select sites was disrupted and transcriptional regulatory activities abrogated. Molecular docking and molecular dynamics confirmed that mutations in residues specifically contacting DNA bases or backbone exhibited loss of DNA binding. However, R339Q and G420D were stabilised by the formation of new primary DNA bonds, contributing to gain-of-function. Our data confirm that a spectrum of loss-, change- and gain-of-function impacts on CTCF zinc fingers are observed in cell growth regulation and gene regulatory activities. Hence, diverse cellular phenotypes of mutant CTCF are clearly explained by examining structure–function relationships.",

keywords = "CTCF, Cancer, Gain-of-function, Loss-of-function, Molecular docking, Molecular dynamics, Somatic mutation, Zinc finger",

author = "Bailey, \{Charles G.\} and Shailendra Gupta and Cynthia Metierre and Amarasekera, \{Punkaja M.S.\} and Patrick O{\textquoteright}Young and Wunna Kyaw and Tatyana Laletin and Habib Francis and Crystal Semaan and \{Sharifi Tabar\}, Mehdi and Singh, \{Krishna P.\} and Mullighan, \{Charles G.\} and Olaf Wolkenhauer and Ulf Schmitz and Rasko, \{John E.J.\}",

note = "Publisher Copyright: {\textcopyright} 2021, The Author(s).",

year = "2021",

month = dec,

doi = "10.1007/s00018-021-03946-z",

language = "English",

volume = "78",

pages = "7519--7536",

journal = "Cellular and Molecular Life Sciences",

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Bailey, CG, Gupta, S, Metierre, C, Amarasekera, PMS, O’Young, P, Kyaw, W, Laletin, T, Francis, H, Semaan, C, Sharifi Tabar, M, Singh, KP, Mullighan, CG, Wolkenhauer, O, Schmitz, U & Rasko, JEJ 2021, 'Structure–function relationships explain CTCF zinc finger mutation phenotypes in cancer', Cellular and Molecular Life Sciences, vol. 78, no. 23, pp. 7519-7536. https://doi.org/10.1007/s00018-021-03946-z

TY - JOUR

T1 - Structure–function relationships explain CTCF zinc finger mutation phenotypes in cancer

AU - Bailey, Charles G.

AU - Gupta, Shailendra

AU - Metierre, Cynthia

AU - Amarasekera, Punkaja M.S.

AU - O’Young, Patrick

AU - Kyaw, Wunna

AU - Laletin, Tatyana

AU - Francis, Habib

AU - Semaan, Crystal

AU - Sharifi Tabar, Mehdi

AU - Singh, Krishna P.

AU - Mullighan, Charles G.

AU - Wolkenhauer, Olaf

AU - Schmitz, Ulf

AU - Rasko, John E.J.

PY - 2021/12

Y1 - 2021/12

N2 - CCCTC-binding factor (CTCF) plays fundamental roles in transcriptional regulation and chromatin architecture maintenance. CTCF is also a tumour suppressor frequently mutated in cancer, however, the structural and functional impact of mutations have not been examined. We performed molecular and structural characterisation of five cancer-specific CTCF missense zinc finger (ZF) mutations occurring within key intra- and inter-ZF residues. Functional characterisation of CTCF ZF mutations revealed a complete (L309P, R339W, R377H) or intermediate (R339Q) abrogation as well as an enhancement (G420D) of the anti-proliferative effects of CTCF. DNA binding at select sites was disrupted and transcriptional regulatory activities abrogated. Molecular docking and molecular dynamics confirmed that mutations in residues specifically contacting DNA bases or backbone exhibited loss of DNA binding. However, R339Q and G420D were stabilised by the formation of new primary DNA bonds, contributing to gain-of-function. Our data confirm that a spectrum of loss-, change- and gain-of-function impacts on CTCF zinc fingers are observed in cell growth regulation and gene regulatory activities. Hence, diverse cellular phenotypes of mutant CTCF are clearly explained by examining structure–function relationships.

AB - CCCTC-binding factor (CTCF) plays fundamental roles in transcriptional regulation and chromatin architecture maintenance. CTCF is also a tumour suppressor frequently mutated in cancer, however, the structural and functional impact of mutations have not been examined. We performed molecular and structural characterisation of five cancer-specific CTCF missense zinc finger (ZF) mutations occurring within key intra- and inter-ZF residues. Functional characterisation of CTCF ZF mutations revealed a complete (L309P, R339W, R377H) or intermediate (R339Q) abrogation as well as an enhancement (G420D) of the anti-proliferative effects of CTCF. DNA binding at select sites was disrupted and transcriptional regulatory activities abrogated. Molecular docking and molecular dynamics confirmed that mutations in residues specifically contacting DNA bases or backbone exhibited loss of DNA binding. However, R339Q and G420D were stabilised by the formation of new primary DNA bonds, contributing to gain-of-function. Our data confirm that a spectrum of loss-, change- and gain-of-function impacts on CTCF zinc fingers are observed in cell growth regulation and gene regulatory activities. Hence, diverse cellular phenotypes of mutant CTCF are clearly explained by examining structure–function relationships.

KW - CTCF

KW - Cancer

KW - Gain-of-function

KW - Loss-of-function

KW - Molecular docking

KW - Molecular dynamics

KW - Somatic mutation

KW - Zinc finger

UR - https://www.scopus.com/pages/publications/85117130258

U2 - 10.1007/s00018-021-03946-z

DO - 10.1007/s00018-021-03946-z

M3 - Article

C2 - 34657170

AN - SCOPUS:85117130258

SN - 1420-682X

VL - 78

SP - 7519

EP - 7536

JO - Cellular and Molecular Life Sciences

JF - Cellular and Molecular Life Sciences

IS - 23

ER -

Structure–function relationships explain CTCF zinc finger mutation phenotypes in cancer

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