Association analysis of chromosome X to identify genetic modifiers of Huntington’s disease (original) (raw)

Hong, E. P. et al. (2021) Association analysis of chromosome X to identify genetic modifiers of Huntington’s disease.Journal of Huntington's Disease, 10(3), pp. 367-375. (doi: 10.3233/JHD-210485) (PMID:34180418) (PMCID:PMC8860147)

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Abstract

Background: Huntington’s disease (HD) is caused by an expanded (>35) CAG trinucleotide repeat in huntingtin (HTT). Age-at-onset of motor symptoms is inversely correlated with the size of the inherited CAG repeat, which expands further in brain regions due to somatic repeat instability. Our recent genetic investigation focusing on autosomal SNPs revealed that age-at-onset is also influenced by genetic variation at many loci, the majority of which encode genes involved in DNA maintenance/repair processes and repeat instability. Objective: We performed a complementary association analysis to determine whether variants in the X chromosome modify HD. Methods: We imputed SNPs on chromosome X for ∼9,000 HD subjects of European ancestry and performed an X chromosome-wide association study (XWAS) to test for association with age-at-onset corrected for inherited CAG repeat length. Results: In a mixed effects model XWAS analysis of all subjects (males and females), assuming random X-inactivation in females, no genome-wide significant onset modification signal was found. However, suggestive significant association signals were detected at Xq12 (top SNP, rs59098970; p-value, 1.4E-6), near moesin (MSN), in a region devoid of DNA maintenance genes. Additional suggestive signals not involving DNA repair genes were observed in male- and female-only analyses at other locations. Conclusion: Although not genome-wide significant, potentially due to small effect size compared to the power of the current study, our data leave open the possibility of modification of HD by a non-DNA repair process. Our XWAS results are publicly available at the updated GEM EURO 9K website hosted at https://www.hdinhd.org/ for browsing, pathway analysis, and data download.

Item Type:	Articles
Additional Information:	This research was supported by the CHDI Foundation Inc., the U.S. National Institutes of Health (NS082079, NS091161, NS016367, NS049206, NS105709, NS119471), the Medical Research Council (UK MR/L010305/1and fellowship MR/P001629/1), and a Cardiff University School of Medicine studentship.
Keywords:	Genetic modifier, Huntington’s disease, residual age-at-onset, XWAS.
Status:	Published
Refereed:	Yes
Glasgow Author(s) Enlighten ID:	Monckton, Professor Darren and Ciosi, Dr Marc
Authors:	Hong, E. P., Chao, M. J., Thomas, M., McAllister, B., Lobanov, S., Lesley, J., Peter, H., Seung, K., Michael, O., Ciosi, M., Monckton, D. G., Jeffrey, D. L., Lucente, D., Wheeler, V., MacDonald, M. E., Gusella, J. F., and Lee, J.-M.
Subjects:	Q Science > QH Natural history > QH301 Biology Q Science > QH Natural history > QH426 Genetics
College/School:	College of Medical Veterinary and Life Sciences > School of Molecular Biosciences
Journal Name:	Journal of Huntington's Disease
Publisher:	IOS Press
ISSN:	1879-6397
ISSN (Online):	1879-6400
Published Online:	22 June 2021
Copyright Holders:	Copyright © 2021 – IOS Press
First Published:	First published in Journal of Huntington's Disease 10(3):367-375
Publisher Policy:	Reproduced in accordance with the publisher copyright policy

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Deposit and Record Details

ID Code:	376787
Depositing User:	Dr Marc Ciosi
Datestamp:	16 Jan 2026 09:17
Last Modified:	21 Jan 2026 02:32
Date of acceptance:	22 June 2021
Date of first online publication:	22 June 2021
Date Deposited:	20 January 2026
Data Availability Statement:	Yes