Rare Missense and Synonymous Variants in UBE1 Are Associated with X-Linked Infantile Spinal Muscular Atrophy

Juliane Ramser; Mary Ellen Ahearn; Claus Lenski; Kemal O. Yariz; Heide Hellebrand; Michael von Rhein; Robin D. Clark; Rita K. Schmutzler; Peter Lichtner; Eric P. Hoffman; Alfons Meindl; Lisa Baumbach-Reardon

doi:10.1016/j.ajhg.2007.09.009

Rare Missense and Synonymous Variants in UBE1 Are Associated with X-Linked Infantile Spinal Muscular Atrophy

Juliane Ramser, Mary Ellen Ahearn, Claus Lenski, Kemal O. Yariz, Heide Hellebrand, Michael von Rhein, Robin D. Clark, Rita K. Schmutzler, Peter Lichtner, Eric P. Hoffman, Alfons Meindl, Lisa Baumbach-Reardon

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

Abstract

X-linked infantile spinal muscular atrophy (XL-SMA) is an X-linked disorder presenting with the clinical features hypotonia, areflexia, and multiple congenital contractures (arthrogryposis) associated with loss of anterior horn cells and infantile death. To identify the XL-SMA disease gene, we performed large-scale mutation analysis in genes located between markers DXS8080 and DXS7132 (Xp11.3-Xq11.1). This resulted in detection of three rare novel variants in exon 15 of UBE1 that segregate with disease: two missense mutations (c.1617 G→T, p.Met539Ile; c.1639 A→G, p.Ser547Gly) present each in one XL-SMA family, and one synonymous C→T substitution (c.1731 C→T, p.Asn577Asn) identified in another three unrelated families. Absence of the missense mutations was demonstrated for 3550 and absence of the synonymous mutation was shown in 7914 control X chromosomes; therefore, these results yielded statistical significant evidence for the association of the synonymous substitution and the two missense mutations with XL-SMA (p = 2.416 × 10^-10, p = 0.001815). We also demonstrated that the synonymous C→T substitution leads to significant reduction of UBE1 expression and alters the methylation pattern of exon 15, implying a plausible role of this DNA element in developmental UBE1 expression in humans. Our observations indicate first that XL-SMA is part of a growing list of neurodegenerative disorders associated with defects in the ubiquitin-proteasome pathway and second that synonymous C→T transitions might have the potential to affect gene expression.

Original language	English
Pages (from-to)	188-193
Number of pages	6
Journal	American Journal of Human Genetics
Volume	82
Issue number	1
DOIs	https://doi.org/10.1016/j.ajhg.2007.09.009
State	Published - Jan 10 2008

ASJC Scopus Subject Areas

Genetics
Genetics(clinical)

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Ramser, J., Ahearn, M. E., Lenski, C., Yariz, K. O., Hellebrand, H., von Rhein, M., Clark, R. D., Schmutzler, R. K., Lichtner, P., Hoffman, E. P., Meindl, A., & Baumbach-Reardon, L. (2008). Rare Missense and Synonymous Variants in UBE1 Are Associated with X-Linked Infantile Spinal Muscular Atrophy. American Journal of Human Genetics, 82(1), 188-193. https://doi.org/10.1016/j.ajhg.2007.09.009

Ramser, J, Ahearn, ME, Lenski, C, Yariz, KO, Hellebrand, H, von Rhein, M, Clark, RD, Schmutzler, RK, Lichtner, P, Hoffman, EP, Meindl, A & Baumbach-Reardon, L 2008, 'Rare Missense and Synonymous Variants in UBE1 Are Associated with X-Linked Infantile Spinal Muscular Atrophy', American Journal of Human Genetics, vol. 82, no. 1, pp. 188-193. https://doi.org/10.1016/j.ajhg.2007.09.009

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title = "Rare Missense and Synonymous Variants in UBE1 Are Associated with X-Linked Infantile Spinal Muscular Atrophy",

abstract = "X-linked infantile spinal muscular atrophy (XL-SMA) is an X-linked disorder presenting with the clinical features hypotonia, areflexia, and multiple congenital contractures (arthrogryposis) associated with loss of anterior horn cells and infantile death. To identify the XL-SMA disease gene, we performed large-scale mutation analysis in genes located between markers DXS8080 and DXS7132 (Xp11.3-Xq11.1). This resulted in detection of three rare novel variants in exon 15 of UBE1 that segregate with disease: two missense mutations (c.1617 G→T, p.Met539Ile; c.1639 A→G, p.Ser547Gly) present each in one XL-SMA family, and one synonymous C→T substitution (c.1731 C→T, p.Asn577Asn) identified in another three unrelated families. Absence of the missense mutations was demonstrated for 3550 and absence of the synonymous mutation was shown in 7914 control X chromosomes; therefore, these results yielded statistical significant evidence for the association of the synonymous substitution and the two missense mutations with XL-SMA (p = 2.416 × 10-10, p = 0.001815). We also demonstrated that the synonymous C→T substitution leads to significant reduction of UBE1 expression and alters the methylation pattern of exon 15, implying a plausible role of this DNA element in developmental UBE1 expression in humans. Our observations indicate first that XL-SMA is part of a growing list of neurodegenerative disorders associated with defects in the ubiquitin-proteasome pathway and second that synonymous C→T transitions might have the potential to affect gene expression.",

author = "Juliane Ramser and Ahearn, {Mary Ellen} and Claus Lenski and Yariz, {Kemal O.} and Heide Hellebrand and Michael von Rhein and Clark, {Robin D.} and Schmutzler, {Rita K.} and Peter Lichtner and Hoffman, {Eric P.} and Alfons Meindl and Lisa Baumbach-Reardon",

note = "Funding Information: The authors are grateful to the numerous clinicians and families that have supported these studies through their cooperation throughout the years. In particular, we would like to acknowledge the contributions of Dr. R. Best and J. Edwards (University of South Carolina Medical Center); R.D.C. and her genetic counselling staff (Loma Linda Medical Center); Drs. D. Rita, C. Booth, and E. Moran (Lutheran General Hospital); Dr. R. Martin (St. Louis University); Dr. K. Flannigan (University of Utah School of Medicine); and Dr. S. Sacharow (Dr. John T. Macdonald Center for Medical Genetics, Miami). We would also like to thank Baylor College of Medicine, Institute of Human Genetics Cell Line facility (J. Belmont, M.D., Director), and the University of Miami Gene Cure Cytogenetics Laboratory (Y.-S. Fan, M.D., Director) for the establishment and maintenance of family cell lines. We would like to thank the German Breast Cancer Consortium for providing DNA samples. We would also like to acknowledge the helpful discussions and information provided by Dr. S. Khuri (Dr. John T. Macdonald Center for Medical Genetics, Miami, FL) and the guidance of Drs. R. Howell, W. Bradley, and L. Elsas throughout the course of these studies. We also thank Dr. B. Mueller-Myhsok for support in statistical analysis and M. Bertone for technical assistance. This work was supported in the United States by funds from the Dr. John T. Macdonald Center for Medical Genetics, University of Miami—Miller School of Medicine and the University of Miami—Miller School of Medicine (to L.B.-R.). The national Muscular Dystrophy Association and the Families of SMA have also provided past support to L.B.-R. and E.P.H. for these investigations. This work was supported in Europe by the German Ministry for Research and Education grant BMBF 01KW9974 (to A.M.). C.L. was supported by the FAZIT-Stiftung, Frankfurt/Main, Germany. ",

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T1 - Rare Missense and Synonymous Variants in UBE1 Are Associated with X-Linked Infantile Spinal Muscular Atrophy

AU - Ramser, Juliane

AU - Ahearn, Mary Ellen

AU - Lenski, Claus

AU - Yariz, Kemal O.

AU - Hellebrand, Heide

AU - von Rhein, Michael

AU - Clark, Robin D.

AU - Schmutzler, Rita K.

AU - Lichtner, Peter

AU - Hoffman, Eric P.

AU - Meindl, Alfons

AU - Baumbach-Reardon, Lisa

N1 - Funding Information: The authors are grateful to the numerous clinicians and families that have supported these studies through their cooperation throughout the years. In particular, we would like to acknowledge the contributions of Dr. R. Best and J. Edwards (University of South Carolina Medical Center); R.D.C. and her genetic counselling staff (Loma Linda Medical Center); Drs. D. Rita, C. Booth, and E. Moran (Lutheran General Hospital); Dr. R. Martin (St. Louis University); Dr. K. Flannigan (University of Utah School of Medicine); and Dr. S. Sacharow (Dr. John T. Macdonald Center for Medical Genetics, Miami). We would also like to thank Baylor College of Medicine, Institute of Human Genetics Cell Line facility (J. Belmont, M.D., Director), and the University of Miami Gene Cure Cytogenetics Laboratory (Y.-S. Fan, M.D., Director) for the establishment and maintenance of family cell lines. We would like to thank the German Breast Cancer Consortium for providing DNA samples. We would also like to acknowledge the helpful discussions and information provided by Dr. S. Khuri (Dr. John T. Macdonald Center for Medical Genetics, Miami, FL) and the guidance of Drs. R. Howell, W. Bradley, and L. Elsas throughout the course of these studies. We also thank Dr. B. Mueller-Myhsok for support in statistical analysis and M. Bertone for technical assistance. This work was supported in the United States by funds from the Dr. John T. Macdonald Center for Medical Genetics, University of Miami—Miller School of Medicine and the University of Miami—Miller School of Medicine (to L.B.-R.). The national Muscular Dystrophy Association and the Families of SMA have also provided past support to L.B.-R. and E.P.H. for these investigations. This work was supported in Europe by the German Ministry for Research and Education grant BMBF 01KW9974 (to A.M.). C.L. was supported by the FAZIT-Stiftung, Frankfurt/Main, Germany.

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N2 - X-linked infantile spinal muscular atrophy (XL-SMA) is an X-linked disorder presenting with the clinical features hypotonia, areflexia, and multiple congenital contractures (arthrogryposis) associated with loss of anterior horn cells and infantile death. To identify the XL-SMA disease gene, we performed large-scale mutation analysis in genes located between markers DXS8080 and DXS7132 (Xp11.3-Xq11.1). This resulted in detection of three rare novel variants in exon 15 of UBE1 that segregate with disease: two missense mutations (c.1617 G→T, p.Met539Ile; c.1639 A→G, p.Ser547Gly) present each in one XL-SMA family, and one synonymous C→T substitution (c.1731 C→T, p.Asn577Asn) identified in another three unrelated families. Absence of the missense mutations was demonstrated for 3550 and absence of the synonymous mutation was shown in 7914 control X chromosomes; therefore, these results yielded statistical significant evidence for the association of the synonymous substitution and the two missense mutations with XL-SMA (p = 2.416 × 10-10, p = 0.001815). We also demonstrated that the synonymous C→T substitution leads to significant reduction of UBE1 expression and alters the methylation pattern of exon 15, implying a plausible role of this DNA element in developmental UBE1 expression in humans. Our observations indicate first that XL-SMA is part of a growing list of neurodegenerative disorders associated with defects in the ubiquitin-proteasome pathway and second that synonymous C→T transitions might have the potential to affect gene expression.

AB - X-linked infantile spinal muscular atrophy (XL-SMA) is an X-linked disorder presenting with the clinical features hypotonia, areflexia, and multiple congenital contractures (arthrogryposis) associated with loss of anterior horn cells and infantile death. To identify the XL-SMA disease gene, we performed large-scale mutation analysis in genes located between markers DXS8080 and DXS7132 (Xp11.3-Xq11.1). This resulted in detection of three rare novel variants in exon 15 of UBE1 that segregate with disease: two missense mutations (c.1617 G→T, p.Met539Ile; c.1639 A→G, p.Ser547Gly) present each in one XL-SMA family, and one synonymous C→T substitution (c.1731 C→T, p.Asn577Asn) identified in another three unrelated families. Absence of the missense mutations was demonstrated for 3550 and absence of the synonymous mutation was shown in 7914 control X chromosomes; therefore, these results yielded statistical significant evidence for the association of the synonymous substitution and the two missense mutations with XL-SMA (p = 2.416 × 10-10, p = 0.001815). We also demonstrated that the synonymous C→T substitution leads to significant reduction of UBE1 expression and alters the methylation pattern of exon 15, implying a plausible role of this DNA element in developmental UBE1 expression in humans. Our observations indicate first that XL-SMA is part of a growing list of neurodegenerative disorders associated with defects in the ubiquitin-proteasome pathway and second that synonymous C→T transitions might have the potential to affect gene expression.

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Rare Missense and Synonymous Variants in UBE1 Are Associated with X-Linked Infantile Spinal Muscular Atrophy

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