Your search keyword '"Aiyar, R."' showing total 1 results

1. Narrowing in on the causative defect of an intriguing X-linked myopathy with excessive autophagy.

Author

Minassian BA, Aiyar R, Alic S, Banwell B, Villanova M, Fardeau M, Mandell JW, Juel VC, Rafii M, Auranen M, and Kalimo H

Subjects

Adolescent, Calcium metabolism, Child, Complement Membrane Attack Complex biosynthesis, DNA Mutational Analysis, Finland epidemiology, France epidemiology, Genetic Markers, Humans, Male, Microsatellite Repeats, Muscle, Skeletal metabolism, Muscle, Skeletal pathology, Muscular Diseases diagnosis, Muscular Diseases epidemiology, Muscular Diseases pathology, United States epidemiology, Autophagy genetics, Genetic Linkage, Muscular Diseases genetics, Physical Chromosome Mapping, X Chromosome genetics

Abstract

Background: X-Linked myopathy with excessive autophagy (XMEA) is a childhood-onset slowly progressive disease of skeletal muscle with no cardiac, nervous system, or other organ involvement. Pathology is distinctive: membrane-bound autophagic vacuoles, multifold reduplication of the basement membrane, and intense deposition of membrane attack complex and calcium at the myofiber surface. XMEA has been linked to the most telomeric 10.5 cM of Xq28. The authors now report identification of new families, refinement of the locus, mapping of genes to the region, and screening of candidate genes for mutations., Methods and Results: Seven new families were ascertained, including an American family with XMEA. Using 11 new microsatellite genetic markers, the authors fine-mapped a recombination in this family and a common ancestral haplotype in two French families, which localized the gene in a 4.37-Mb region. Sequence data were assembled from public and private databases and a near-continuous sequence derived for the entire region. With this sequence, a gene map of 82 genes and 28 expressed sequence tag clusters was constructed; to date, 12 candidate genes have been screened for mutations., Conclusions: This study doubles the number of reported families with XMEA and more firmly establishes its distinctive clinicopathologic features. It also advances the search for the XMEA causative defect by reducing the disease locus to approximately half its previous size, assembling an almost complete sequence of the refined region, identifying all known genes in this sequence, and excluding the presence of mutations in 10% of these genes.

Published

2002