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Mutations in the intellectual disability gene KDM5C reduce protein stability and demethylase activity

Mutations in the intellectual disability gene KDM5C reduce protein stability and demethylase activity
Mutations in the intellectual disability gene KDM5C reduce protein stability and demethylase activity
Mutations in KDM5C are an important cause of X-linked intellectual disability in males. KDM5C encodes a histone demethylase, suggesting that alterations in chromatin landscape may contribute to disease. We used primary patient cells and biochemical approaches to investigate the effects of patient mutations on KDM5C expression, stability and catalytic activity. We report and characterize a novel nonsense mutation, c.3223delG (p.V1075Yfs*2), which leads to loss of KDM5C protein. We also characterize two KDM5C missense mutations, c.1439C>T (p.P480L) and c.1204G>T (p.D402Y) that are compatible with protein production, but compromise stability and enzymatic activity. Finally, we demonstrate that a c.2T>C mutation in the translation initiation codon of KDM5C results in translation re-start and production of a N-terminally truncated protein (p.M1_E165del) that is unstable and lacks detectable demethylase activity. Patient fibroblasts do not show global changes in histone methylation but we identify several up-regulated genes, suggesting local changes in chromatin conformation and gene expression. This thorough examination of KDM5C patient mutations demonstrates the utility of examining the molecular consequences of patient mutations on several levels, ranging from enzyme production to catalytic activity, when assessing the functional outcomes of intellectual disability mutations.
0964-6906
2861-2872
Brookes, Emily
425dafc2-111b-4f6c-9336-f720c4ef8cac
Laurent, Benoit
7da5a6eb-c5c2-4545-99fb-13453113b98e
Ounap, Katrin
0acf2ca4-66ff-43f4-b0b1-11e73e729fb9
Carroll, Renee
ec1c8521-cfc0-4024-a27f-c480b23847a4
Moeschler, John B.
e51b7c23-c324-47e3-aa67-63c501771c33
Field, Michael
2e5b15b5-4949-49b0-893a-4dacfc4fad55
Schwartz, Charles E
3644491d-a5c6-4260-9f77-e799201d1196
Gecz, Jozef
2439d993-6c0d-46f5-b10b-e3fd00618ace
Shi, Yang
123f38c3-5fd5-42ea-95a4-695b1ebb668a
Brookes, Emily
425dafc2-111b-4f6c-9336-f720c4ef8cac
Laurent, Benoit
7da5a6eb-c5c2-4545-99fb-13453113b98e
Ounap, Katrin
0acf2ca4-66ff-43f4-b0b1-11e73e729fb9
Carroll, Renee
ec1c8521-cfc0-4024-a27f-c480b23847a4
Moeschler, John B.
e51b7c23-c324-47e3-aa67-63c501771c33
Field, Michael
2e5b15b5-4949-49b0-893a-4dacfc4fad55
Schwartz, Charles E
3644491d-a5c6-4260-9f77-e799201d1196
Gecz, Jozef
2439d993-6c0d-46f5-b10b-e3fd00618ace
Shi, Yang
123f38c3-5fd5-42ea-95a4-695b1ebb668a

Brookes, Emily, Laurent, Benoit, Ounap, Katrin, Carroll, Renee, Moeschler, John B., Field, Michael, Schwartz, Charles E, Gecz, Jozef and Shi, Yang (2015) Mutations in the intellectual disability gene KDM5C reduce protein stability and demethylase activity. Human Molecular Genetics, 24 (10), 2861-2872. (doi:10.1093/hmg/ddv046).

Record type: Article

Abstract

Mutations in KDM5C are an important cause of X-linked intellectual disability in males. KDM5C encodes a histone demethylase, suggesting that alterations in chromatin landscape may contribute to disease. We used primary patient cells and biochemical approaches to investigate the effects of patient mutations on KDM5C expression, stability and catalytic activity. We report and characterize a novel nonsense mutation, c.3223delG (p.V1075Yfs*2), which leads to loss of KDM5C protein. We also characterize two KDM5C missense mutations, c.1439C>T (p.P480L) and c.1204G>T (p.D402Y) that are compatible with protein production, but compromise stability and enzymatic activity. Finally, we demonstrate that a c.2T>C mutation in the translation initiation codon of KDM5C results in translation re-start and production of a N-terminally truncated protein (p.M1_E165del) that is unstable and lacks detectable demethylase activity. Patient fibroblasts do not show global changes in histone methylation but we identify several up-regulated genes, suggesting local changes in chromatin conformation and gene expression. This thorough examination of KDM5C patient mutations demonstrates the utility of examining the molecular consequences of patient mutations on several levels, ranging from enzyme production to catalytic activity, when assessing the functional outcomes of intellectual disability mutations.

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e-pub ahead of print date: 9 February 2015
Published date: 15 May 2015

Identifiers

Local EPrints ID: 472088
URI: http://eprints.soton.ac.uk/id/eprint/472088
ISSN: 0964-6906
PURE UUID: b1b289f9-762f-4992-a371-5fe73dab8cdb
ORCID for Emily Brookes: ORCID iD orcid.org/0000-0003-2175-4349

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Date deposited: 25 Nov 2022 17:36
Last modified: 17 Mar 2024 04:14

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Contributors

Author: Emily Brookes ORCID iD
Author: Benoit Laurent
Author: Katrin Ounap
Author: Renee Carroll
Author: John B. Moeschler
Author: Michael Field
Author: Charles E Schwartz
Author: Jozef Gecz
Author: Yang Shi

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