Molecular diagnosis of hereditary inclusion body myopathy by linkage analysis and identification of a novel splice site mutation in GNE

Steven E. Boyden; Anna R. Duncan; Elicia A. Estrella; Hart G.W. Lidov; Lane J. Mahoney; Jonathan S. Katz; Louis M. Kunkel; Peter B. Kang

doi:10.1186/1471-2350-12-87

Molecular diagnosis of hereditary inclusion body myopathy by linkage analysis and identification of a novel splice site mutation in GNE

Steven E. Boyden, Anna R. Duncan, Elicia A. Estrella, Hart G.W. Lidov, Lane J. Mahoney, Jonathan S. Katz, Louis M. Kunkel, Peter B. Kang

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Abstract

Background: Many myopathies share clinical features in common, and diagnosis often requires genetic testing. We ascertained a family in which five siblings presented with distal muscle weakness of unknown etiology.Methods: We performed high-density genomewide linkage analysis and mutation screening of candidate genes to identify the genetic defect in the family. Preserved clinical biopsy material was reviewed to confirm the diagnosis, and reverse transcriptase PCR was used to determine the molecular effect of a splice site mutation.Results: The linkage scan excluded the majority of known myopathy genes, but one linkage peak included the gene GNE, in which mutations cause autosomal recessive hereditary inclusion body myopathy type 2 (HIBM2). Muscle biopsy tissue from a patient showed myopathic features, including small basophilic fibers with vacuoles. Sequence analysis of GNE revealed affected individuals were compound heterozygous for a novel mutation in the 5' splice donor site of intron 10 (c.1816+5G>A) and a previously reported missense mutation (c.2086G>A, p.V696M), confirming the diagnosis as HIBM2. The splice site mutation correlated with exclusion of exon 10 from the transcript, which is predicted to produce an in-frame deletion (p.G545_D605del) of 61 amino acids in the kinase domain of the GNE protein. The father of the proband was heterozygous for the splice site mutation and exhibited mild distal weakness late in life.Conclusions: Our study expands on the extensive allelic heterogeneity of HIBM2 and demonstrates the value of linkage analysis in resolving ambiguous clinical findings to achieve a molecular diagnosis.

Original language	English (US)
Article number	87
Journal	BMC medical genetics
Volume	12
DOIs	https://doi.org/10.1186/1471-2350-12-87
State	Published - Jun 28 2011
Externally published	Yes

Bibliographical note

Funding Information:
The authors thank the patients and their family for their participation in this study, Jerry Mendell for clinical histological examination and interpretation, Caitlin Kreitman and Michael Lawlor for technical assistance, and Juan Carlos Casar, Jennifer Myers, and Genri Kawahara for helpful discussions. This work was supported by K08 NS048180 (PBK), the Genise Goldenson Fund (PBK), Muscular Dystrophy Association Research Grant 186796 (PBK), the Howard Hughes Medical Institute (LMK), the Manton Center for Orphan Disease Research (LMK), and the Bernard and Alva B. Gimbel Foundation (LMK). Microarray genotyping and DNA sequencing experiments were performed in the Molecular Genetics Core Facility at Children’s Hospital Boston, supported by NIH-P30-HD18655 through the Intellectual and Developmental Disabilities Research Center and NIH-P50-NS40828 through the Neuromuscular Disease Project.

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@article{68449063c99b4e11beae3a60738ed02c,

title = "Molecular diagnosis of hereditary inclusion body myopathy by linkage analysis and identification of a novel splice site mutation in GNE",

abstract = "Background: Many myopathies share clinical features in common, and diagnosis often requires genetic testing. We ascertained a family in which five siblings presented with distal muscle weakness of unknown etiology.Methods: We performed high-density genomewide linkage analysis and mutation screening of candidate genes to identify the genetic defect in the family. Preserved clinical biopsy material was reviewed to confirm the diagnosis, and reverse transcriptase PCR was used to determine the molecular effect of a splice site mutation.Results: The linkage scan excluded the majority of known myopathy genes, but one linkage peak included the gene GNE, in which mutations cause autosomal recessive hereditary inclusion body myopathy type 2 (HIBM2). Muscle biopsy tissue from a patient showed myopathic features, including small basophilic fibers with vacuoles. Sequence analysis of GNE revealed affected individuals were compound heterozygous for a novel mutation in the 5' splice donor site of intron 10 (c.1816+5G>A) and a previously reported missense mutation (c.2086G>A, p.V696M), confirming the diagnosis as HIBM2. The splice site mutation correlated with exclusion of exon 10 from the transcript, which is predicted to produce an in-frame deletion (p.G545_D605del) of 61 amino acids in the kinase domain of the GNE protein. The father of the proband was heterozygous for the splice site mutation and exhibited mild distal weakness late in life.Conclusions: Our study expands on the extensive allelic heterogeneity of HIBM2 and demonstrates the value of linkage analysis in resolving ambiguous clinical findings to achieve a molecular diagnosis.",

author = "Boyden, {Steven E.} and Duncan, {Anna R.} and Estrella, {Elicia A.} and Lidov, {Hart G.W.} and Mahoney, {Lane J.} and Katz, {Jonathan S.} and Kunkel, {Louis M.} and Kang, {Peter B.}",

note = "Funding Information: The authors thank the patients and their family for their participation in this study, Jerry Mendell for clinical histological examination and interpretation, Caitlin Kreitman and Michael Lawlor for technical assistance, and Juan Carlos Casar, Jennifer Myers, and Genri Kawahara for helpful discussions. This work was supported by K08 NS048180 (PBK), the Genise Goldenson Fund (PBK), Muscular Dystrophy Association Research Grant 186796 (PBK), the Howard Hughes Medical Institute (LMK), the Manton Center for Orphan Disease Research (LMK), and the Bernard and Alva B. Gimbel Foundation (LMK). Microarray genotyping and DNA sequencing experiments were performed in the Molecular Genetics Core Facility at Children{\textquoteright}s Hospital Boston, supported by NIH-P30-HD18655 through the Intellectual and Developmental Disabilities Research Center and NIH-P50-NS40828 through the Neuromuscular Disease Project.",

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doi = "10.1186/1471-2350-12-87",

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T1 - Molecular diagnosis of hereditary inclusion body myopathy by linkage analysis and identification of a novel splice site mutation in GNE

AU - Boyden, Steven E.

AU - Duncan, Anna R.

AU - Estrella, Elicia A.

AU - Lidov, Hart G.W.

AU - Mahoney, Lane J.

AU - Katz, Jonathan S.

AU - Kunkel, Louis M.

AU - Kang, Peter B.

N1 - Funding Information: The authors thank the patients and their family for their participation in this study, Jerry Mendell for clinical histological examination and interpretation, Caitlin Kreitman and Michael Lawlor for technical assistance, and Juan Carlos Casar, Jennifer Myers, and Genri Kawahara for helpful discussions. This work was supported by K08 NS048180 (PBK), the Genise Goldenson Fund (PBK), Muscular Dystrophy Association Research Grant 186796 (PBK), the Howard Hughes Medical Institute (LMK), the Manton Center for Orphan Disease Research (LMK), and the Bernard and Alva B. Gimbel Foundation (LMK). Microarray genotyping and DNA sequencing experiments were performed in the Molecular Genetics Core Facility at Children’s Hospital Boston, supported by NIH-P30-HD18655 through the Intellectual and Developmental Disabilities Research Center and NIH-P50-NS40828 through the Neuromuscular Disease Project.

PY - 2011/6/28

Y1 - 2011/6/28

N2 - Background: Many myopathies share clinical features in common, and diagnosis often requires genetic testing. We ascertained a family in which five siblings presented with distal muscle weakness of unknown etiology.Methods: We performed high-density genomewide linkage analysis and mutation screening of candidate genes to identify the genetic defect in the family. Preserved clinical biopsy material was reviewed to confirm the diagnosis, and reverse transcriptase PCR was used to determine the molecular effect of a splice site mutation.Results: The linkage scan excluded the majority of known myopathy genes, but one linkage peak included the gene GNE, in which mutations cause autosomal recessive hereditary inclusion body myopathy type 2 (HIBM2). Muscle biopsy tissue from a patient showed myopathic features, including small basophilic fibers with vacuoles. Sequence analysis of GNE revealed affected individuals were compound heterozygous for a novel mutation in the 5' splice donor site of intron 10 (c.1816+5G>A) and a previously reported missense mutation (c.2086G>A, p.V696M), confirming the diagnosis as HIBM2. The splice site mutation correlated with exclusion of exon 10 from the transcript, which is predicted to produce an in-frame deletion (p.G545_D605del) of 61 amino acids in the kinase domain of the GNE protein. The father of the proband was heterozygous for the splice site mutation and exhibited mild distal weakness late in life.Conclusions: Our study expands on the extensive allelic heterogeneity of HIBM2 and demonstrates the value of linkage analysis in resolving ambiguous clinical findings to achieve a molecular diagnosis.

AB - Background: Many myopathies share clinical features in common, and diagnosis often requires genetic testing. We ascertained a family in which five siblings presented with distal muscle weakness of unknown etiology.Methods: We performed high-density genomewide linkage analysis and mutation screening of candidate genes to identify the genetic defect in the family. Preserved clinical biopsy material was reviewed to confirm the diagnosis, and reverse transcriptase PCR was used to determine the molecular effect of a splice site mutation.Results: The linkage scan excluded the majority of known myopathy genes, but one linkage peak included the gene GNE, in which mutations cause autosomal recessive hereditary inclusion body myopathy type 2 (HIBM2). Muscle biopsy tissue from a patient showed myopathic features, including small basophilic fibers with vacuoles. Sequence analysis of GNE revealed affected individuals were compound heterozygous for a novel mutation in the 5' splice donor site of intron 10 (c.1816+5G>A) and a previously reported missense mutation (c.2086G>A, p.V696M), confirming the diagnosis as HIBM2. The splice site mutation correlated with exclusion of exon 10 from the transcript, which is predicted to produce an in-frame deletion (p.G545_D605del) of 61 amino acids in the kinase domain of the GNE protein. The father of the proband was heterozygous for the splice site mutation and exhibited mild distal weakness late in life.Conclusions: Our study expands on the extensive allelic heterogeneity of HIBM2 and demonstrates the value of linkage analysis in resolving ambiguous clinical findings to achieve a molecular diagnosis.

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Molecular diagnosis of hereditary inclusion body myopathy by linkage analysis and identification of a novel splice site mutation in GNE

Abstract

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