Skip to main content
Key Specialties
Cardiology Diabetology Endocrinology Gastroenterology Geriatrics and Gerontology Gynecology and Obstetrics Hematology Infectious Disease Internal Medicine Nephrology Neurology Oncology Pediatrics Respiratory Medicine Rheumatology Surgery
Congress Coverage
2024 ACC Congress 2023 ESMO Congress 2023 EASD Congress 2023 ERS Congress 2023 ESC Congress
Clinical Collections
Advances in Alzheimer’s

At a glance: The STEP trials

A round-up of the STEP phase 3 clinical trials evaluating semaglutide for weight loss in people with overweight or obesity.
ADVANCED SEARCH
Log in
Top
Neurogenetics
Published in: neurogenetics 2/2004

01-06-2004 | Original Article

Evidence for a modifier of onset age in Huntington disease linked to the HD gene in 4p16

Authors: Luc Djoussé, Beth Knowlton, Michael R. Hayden, Elisabeth W. Almqvist, Ryan R. Brinkman, Christopher A. Ross, Russel L. Margolis, Adam Rosenblatt, Alexandra Durr, Catherine Dode, Patrick J. Morrison, Andrea Novelletto, Marina Frontali, Ronald J. A. Trent, Elizabeth McCusker, Estrella Gómez-Tortosa, David Mayo Cabrero, Randi Jones, Andrea Zanko, Martha Nance, Ruth K. Abramson, Oksana Suchowersky, Jane S. Paulsen, Madaline B. Harrison, Qiong Yang, L. Adrienne Cupples, Jayalakshmi Mysore, James F. Gusella, Marcy E. MacDonald, Richard H. Myers

Published in: Neurogenetics | Issue 2/2004

Login to get access

Abstract.

Huntington disease (HD) is a neurodegenerative disorder caused by the abnormal expansion of CAG repeats in the HD gene on chromosome 4p16.3. A recent genome scan for genetic modifiers of age at onset of motor symptoms (AO) in HD suggests that one modifier may reside in the region close to the HD gene itself. We used data from 535 HD participants of the New England Huntington cohort and the HD MAPS cohort to assess whether AO was influenced by any of the three markers in the 4p16 region: MSX1 (Drosophila homeo box homologue 1, formerly known as homeo box 7, HOX7), Δ2642 (within the HD coding sequence), and BJ56 (D4S127). Suggestive evidence for an association was seen between MSX1 alleles and AO, after adjustment for normal CAG repeat, expanded repeat, and their product term (model P value 0.079). Of the variance of AO that was not accounted for by HD and normal CAG repeats, 0.8% could be attributed to the MSX1 genotype. Individuals with MSX1 genotype 3/3 tended to have younger AO. No association was found between Δ2642 (P=0.44) and BJ56 (P=0.73) and AO. This study supports previous studies suggesting that there may be a significant genetic modifier for AO in HD in the 4p16 region. Furthermore, the modifier may be present on both HD and normal chromosomes bearing the 3 allele of the MSX1 marker.
Literature
1.
Huntington G (1872) On chorea. Med Surg Rep 26:320–321
2.
Hayden MR, Berkowicz AL, Beighton PH, Yiptong C (1981) Huntington’s chorea on the island of Mauritius. S Afr Med J 60:1001–1002PubMed
3.
Folstein SE (1989) Huntington’s disease: a disorder of families. The Johns Hopkins University Press, Baltimore
4.
White RF, Vasterling JJ, Koroshetz W, Myers RH (1992) Neuropsychology of Huntington’s disease. In: White RF (ed) Clinical syndromes in adult neuropsychology: the practioners handbook. , Elsevier, New York, pp 213–251
5.
Gusella JF, Wexler NS, Conneally PM, Naylor SL, Anderson MA, Tanzi RE, Watkins PC, Ottina K, Wallace MR, Sakaguchi AY, Young AB, Shoulson I, Bonilla E, Martin JB (1983) A polymorphic DNA marker genetically linked to Huntington’s disease. Nature 306:234–238PubMed
6.
Huntington’s Disease Collaborative Research Group (1993) A novel gene containing a trinucleotide repeat that is expanded and unstable on Huntington’s disease chromosomes. Cell 79:971–983
7.
Duyao M, Ambrose C, Myers R, Novelletto A, Persichetti F, Frontali M, Folstein S, Ross C, Franz M, Abbott M, Gray J, Conneally P, Young A, Penney J, Hollingsworth Z, Shoulson I, Lazzarini A, Falek A, Koroshetz W, Sax D, Bird E, Vonsattel J, Bonilla E, Alvir J, Conde JB, Cha JH, Dure L, Gomez F, Ramos M, Sanchezramos J, Snodgrass S, Deyoung M, Wexler N, Moscowitz C, Penchaszadeh G, Macfarlane H, Anderson M, Jenkins B, Srinidhi J, Barnes G, Gusella J, Macdonald M (1993) Trinucleotide repeat length instability and age of onset in Huntington’s disease. Nat Genet 4:387–392PubMed
8.
Snell RG, MacMillan JC, Cheadle JP, Fenton I, Lazarou LP, Davies P, MacDonald ME, Gusella JF, Harper PS, Shaw DJ (1993) Relationship between trinucleotide repeat expansion and phenotypic variation in Huntington’s disease. Nat Genet 4:393–397PubMed
9.
Ranen NG, Stine OC, Abbott MH, Sherr M, Codori AM, Franz ML, Chao NI, Chung AS, Pleasant N, Callahan C, Kasch LM, Ghaffari M, Chase GA, Kazazian HH, Brandt J, Folstein SE, Ross CA (1995) Anticipation and instability of IT-15 (CAG)n repeats in parent-offspring pairs with Huntington disease. Am J Hum Genet 57:593–602PubMed
10.
Brinkman RR, Mezei MM, Theilmann J, Almqvist E, Hayden MR (1997) The likelihood of being affected with Huntington disease by a particular age, for a specific CAG size. Am J Hum Genet 60:1202–1210PubMed
11.
Farrer LA, Cupples LA, Wiater P, Conneally PM, Gusella JF, Myers RH (1993) The normal Huntington disease (HD) allele, or a closely linked gene, influences age at onset of HD. Am J Hum Genet 53:125–130PubMed
12.
Li J, Hayden MR, Almqvist EW, Brinkman RR, Durr A, Dode C, Morrison PJ, Sudo H, Ross CA, Margolis RL, Rosenblatt A, Gomez-Tortosa E, Cabrero DM, Novelletto A, Frontali M, Nance M, Trent RJ, McCusker E, Jones R, Paulsen JS, Harrison M, Zanko A, Abramson RK, Russ AL, Djousse L, Mysore JS, Tariot S, Gusella MF, Wheeler VC, Atwood LD, Cupples LA, Saint-Hilaire M, Cha JH, Hersch SM, Koroshetz WJ, Gusella JF, MacDonald ME, Myers RH (2003) A genome scan for modifiers of age at onset in Huntington’s disease: The HD MAPS Study. Am J Hum Genet 73:682–687CrossRefPubMed
13.
Ambrose CM, Duyao MP, Barnes G, Bates GP, Lin CS, Srinidhi J, Baxendale S, Hummerich H, Lehrach H, Altherr M, Wasmuth J, Buckler A, Church D, Housman D, Berks M, Micklem G, Durbin R, Dodge A, Read A, Gusella J, Macdonald ME (1994) Structure and expression of the Huntington’s disease gene: evidence against simple inactivation due to an expanded CAG repeat. Somat Cell Mol Genet 20:27–38PubMed
14.
Taylor SA, Barnes GT, MacDonald ME, Gusella JF (1992) A dinucleotide repeat polymorphism at the D4S127 locus. Hum Mol Genet 1:142
15.
Ivens A, Flavin N, Williamson R, Dixon M, Bates G, Buckingham M, Robert B (1990) The human homeobox gene HOX7 maps to chromosome 4p16.1 and may be implicated in Wolf-Hirschhorn syndrome. Hum Genet 84:473–476PubMed
16.
Djousse L, Knowlton B, Hayden M, Almqvist EW, Brinkman R, Ross C, Margolis R, Rosenblatt A, Durr A, Dode C, Morrison PJ, Novelletto A, Frontali M, Trent RJ, McCusker E, Gomez-Tortosa E, Mayo D, Jones R, Zanko A, Nance M, Abramson R, Suchowersky O, Paulsen J, Harrison M, Yang Q, Cupples LA, Gusella JF, MacDonald ME, Myers RH (2003) Interaction of normal and expanded CAG repeat sizes influences age at onset of Huntington disease. Am J Med Genet 119A:279–282CrossRefPubMed
17.
MacDonald ME, Novelletto A, Lin C, Tagle D, Barnes G, Bates G, Taylor S, Allitto B, Altherr M, Myers R, Lehrach H, Collins FS, Wasmuth JJ, Frontali M, Gusella JF (1992) The Huntington’s disease candidate region exhibits many different haplotypes. Nat Genet 1:99–103PubMed
18.
Myers RH, Madden JJ, Teague JL, Falek A (1982) Factors related to onset age of Huntington disease. Am J Hum Genet 34:481–488PubMed
19.
Conneally PM (1984) Huntington disease: genetics and epidemiology. Am J Hum Genet 36:506–526PubMed
20.
Farrer LA, Conneally PM (1987) Predictability of phenotype in Huntington’s disease. Arch Neurol. 44:109–113
21.
Barron LH, Warner JP, Porteous M, Holloway S, Simpson S, Davidson R, Brock DJ (1993) A study of the Huntington’s disease associated trinucleotide repeat in the Scottish population. J Med Genet 30:1003–1007PubMed
22.
Zuhlke C, Riess O, Schroder K, Siedlaczck I, Epplen JT, Engel W, Thies U (1993) Expansion of the (CAG)n repeat causing Huntington’s disease in 352 patients of German origin. Hum Mol Genet 2:1467–1469PubMed
23.
Myers RH, Marans K, MacDonald ME (1998) Huntington’s disease. In: Warren ST, Wells RT (eds) Genetic instabilities and hereditary neurological diseases. Academic Press, pp 301–323
24.
Rubinsztein DC, Leggo J, Chiano M, Dodge A, Norbury G, Rosser E, Craufurd D (1997) Genotypes at the GluR6 kainate receptor locus are associated with variation in the age of onset of Huntington disease. Proc Natl Acad Sci U S A 94:3872–3876CrossRefPubMed
25.
MacDonald ME, Vonsattel JP, Shrinidhi J, Couropmitree NN, Cupples LA, Bird ED, Gusella JF, Myers RH (1999) Evidence for the GluR6 gene associated with younger onset age of Huntington’s disease. Neurology 53:1330–1332PubMed
26.
Hewitt JE, Clark LN, Ivens A, Williamson R (1991) Structure and sequence of the human homeobox gene HOX7. Genomics 11:670–678PubMed
27.
Ingham PW (1988) The molecular genetics of embryonic pattern formation in Drosophila. Nature 335:25–34CrossRefPubMed
28.
Gehring WJ (1987) Homeo boxes in the study of development. Science 236:1245–1252PubMed
29.
Slack JM (1985) Homoeotic transformations in man: implications for the mechanism of embryonic development and for the organization of epithelia. J Theor Biol 114:463–490PubMed
30.
Jumlongras D, Bei M, Stimson JM, Wang WF, DePalma SR, Seidman CE, Felbor U, Maas R, Seidman JG, Olsen BR (2001) A nonsense mutation in MSX1 causes Witkop syndrome. Am J Hum Genet 69:67–74CrossRefPubMed
31.
Lidral AC, Reising BC (2002) The role of MSX1 in human tooth agenesis. J Dent Res 81:274–278PubMed
32.
Almqvist E, Spence N, Nichol K, Andrew SE, Vesa J, Peltonen L, Anvret M, Goto J, Kanazawa I, Goldberg YP, Hayden MR (1995) Ancestral differences in the distribution of the delta 2642 glutamic acid polymorphism is associated with varying CAG repeat lengths on normal chromosomes: insights into the genetic evolution of Huntington disease. Hum Mol Genet 4:207–214PubMed
33.
Novelletto A, Persichetti F, Sabbadini G, Mandich P, Bellone E, Ajmar F, Squitieri F, Campanella G, Bozza A, MacDonald ME, Gusella JF, Frontali M (1994) Polymorphism analysis of the huntingtin gene in Italian families affected with Huntington disease. Hum Mol Genet 3:1129–1132PubMed
34.
Lucotte G, Gerard N, Roubertoux P, Schmitt I, Riess O (1996) Relationships of the 2642 deletion polymorphism (delta 2642) in the huntingtin gene with the CAG repeat expansion length and age at onset of the disease. Genet Couns 7:297–302PubMed
Metadata
Title
Evidence for a modifier of onset age in Huntington disease linked to the HD gene in 4p16
Authors
Luc Djoussé
Beth Knowlton
Michael R. Hayden
Elisabeth W. Almqvist
Ryan R. Brinkman
Christopher A. Ross
Russel L. Margolis
Adam Rosenblatt
Alexandra Durr
Catherine Dode
Patrick J. Morrison
Andrea Novelletto
Marina Frontali
Ronald J. A. Trent
Elizabeth McCusker
Estrella Gómez-Tortosa
David Mayo Cabrero
Randi Jones
Andrea Zanko
Martha Nance
Ruth K. Abramson
Oksana Suchowersky
Jane S. Paulsen
Madaline B. Harrison
Qiong Yang
L. Adrienne Cupples
Jayalakshmi Mysore
James F. Gusella
Marcy E. MacDonald
Richard H. Myers
Publication date
01-06-2004
Publisher
Springer-Verlag
Published in
Neurogenetics / Issue 2/2004
Print ISSN: 1364-6745
Electronic ISSN: 1364-6753
DOI
https://doi.org/10.1007/s10048-004-0175-2

Other articles of this Issue 2/2004

neurogenetics 2/2004 Go to the issue

Original Article

The estrogen receptor 1 G594A polymorphism is associated with migraine susceptibility in two independent case/control groups

Original Article

Sequence variation in the proximity of IDE may impact age at onset of both Parkinson disease and Alzheimer disease

Original Article

Towards a transcriptome definition of microglial cells

Original Article

Mutations of the MTHFR gene (428C>T and [458G>T+459C>T]) markedly decrease MTHFR enzyme activity

Original Article

Evidence of linkage and association on chromosome 20 for late-onset Alzheimer disease

Original Article

Mitotic impairment by doublecortin is diminished by doublecortin mutations found in patients