Stac3 is a component of the excitation-contraction coupling machinery and mutated in Native American myopathy.

Excitation-contraction coupling, the process that regulates contractions by skeletal muscles, transduces changes in membrane voltage by activating release of Ca(2+) from internal stores to initiate muscle contraction. Defects in excitation-contraction coupling are associated with muscle diseases. Here we identify Stac3 as a novel component of the excitation-contraction coupling machinery. Using a zebrafish genetic screen, we generate a locomotor mutation that is mapped to stac3. We provide electrophysiological, Ca(2+) imaging, immunocytochemical and biochemical evidence that Stac3 participates in excitation-contraction coupling in muscles. Furthermore, we reveal that a mutation in human STAC3 is the genetic basis of the debilitating Native American myopathy (NAM). Analysis of NAM stac3 in zebrafish shows that the NAM mutation decreases excitation-contraction coupling. These findings enhance our understanding of both excitation-contraction coupling and the pathology of myopathies.

Native American myopathy: congenital myopathy with cleft palate, skeletal anomalies, and susceptibility to malignant hyperthermia.

Native American myopathy (NAM) [OMIM 255995], a putative autosomal recessive disorder, was first reported in the Lumbee Indians of North Carolina. NAM features include congenital weakness and arthrogryposis, cleft palate, ptosis, short stature, kyphoscoliosis, talipes deformities, and susceptibility to malignant hyperthermia (MH) provoked by anesthesia. This report documents the phenotypic complexity and natural history of this rare congenital disorder in fourteen individuals with NAM. Findings include a previously unreported 36% mortality by age 18. Based on this study, our conservative estimate for prevalence of NAM within the Lumbee population is approximately 2:10,000; however, birth incidence remains unknown.

Refinement of 2q and 7p loci in a large multiplex NTD family.

BACKGROUND: NTDs are considered complex disorders that arise from an interaction between genetic and environmental factors. NTD family 8776 is a large multigenerational Caucasian family that provides a unique resource for the genetic analysis of NTDs. Previous linkage analysis using a genome-wide SNP screen in family 8776 with multipoint nonparametric mapping methods identified maximum LOD* scores of approximately 3.0 mapping to 2q33.1-q35 and 7p21.1-pter. METHODS: We ascertained an additional nuclear branch of 8776 and conducted additional linkage analysis, fine mapping, and haplotyping. Expression data from lymphoblast cell lines were used to prioritize candidate genes within the minimum candidate intervals. Genomic copy number changes were evaluated using BAC tiling arrays and subtelomeric fluorescent in situ hybridization probes. RESULTS: Increased evidence for linkage was observed with LOD* scores of approximately 3.3 for both regions. Haplotype analyses narrowed the minimum candidate intervals to a 20.3 Mb region in 2q33.1-q35 between markers rs1050347 and D2S434, and an 8.3 Mb region in 7p21.1-21.3 between a novel marker 7M0547 and rs28177. Within these candidate regions, 16 genes were screened for mutations; however, no obvious causative NTD mutation was identified. Evaluation of chromosomal aberrations using comparative genomic hybridization arrays, subtelomeric fluorescent in situ hybridization, and copy number variant detection techniques within the 2q and 7p regions did not detect any chromosomal abnormalities. CONCLUSIONS: This large NTD family has identified two genomic regions that may harbor NTD susceptibility genes. Ascertainment of another branch of family 8776 and additional fine mapping permitted a 9.1 Mb reduction of the NTD candidate interval on chromosome 7 and 37.3 Mb on chromosome 2 from previously published data. Identification of one or more NTD susceptibility genes in this family could provide insight into genes that may affect other NTD families.

High-density single nucleotide polymorphism screen in a large multiplex neural tube defect family refines linkage to loci at 7p21.1-pter and 2q33.1-q35.

BACKGROUND: Neural tube defects (NTDs) are considered complex, with both genetic and environmental factors implicated. To date, no major causative genes have been identified in humans despite several investigations. The first genomewide screen in NTDs demonstrated evidence of linkage to chromosomes 7 and 10. This screen included 44 multiplex families and consisted of 402 microsatellite markers spaced approximately 10 cM apart. Further investigation of the genomic screen data identified a single large multiplex family, pedigree 8776, as primarily driving the linkage results on chromosome 7. METHODS: To investigate this family more thoroughly, a high-density single nucleotide polymorphism (SNP) screen was performed. Two-point and multipoint linkage analyses were performed using both parametric and nonparametric methods. RESULTS: For both the microsatellite and SNP markers, linkage analysis suggested the involvement of a locus or loci proximal to the telomeric regions of chromosomes 2q and 7p, with both regions generating a LOD* score of 3.0 using a nonparametric identity by descent relative sharing method. CONCLUSIONS: The regions with the strongest evidence for linkage map proximal to the telomeres on these two chromosomes. In addition to mutations and/or variants in a major gene, these loci may harbor a microdeletion and/or translocation; potentially, polygenic factors may also be involved. This single family may be promising for narrowing the search for NTD susceptibility genes.

Age and diet act through distinct isoforms of the class II transactivator gene in mouse intestinal epithelium.

BACKGROUND & AIMS: Normal weaning induces class II major histocompatibility complex (Ia) and invariant chain (Ii) expression in the mouse intestinal epithelium. Because the class II transactivator protein (CIITA) induces Ia and Ii in most cell types, we hypothesized that diet-induced expression of these genes was through CIITA. METHODS: Mouse litters were split and weaned onto an elemental diet or a normal (complex) chow diet. On days 24, 31, and 45, epithelial cells were isolated from small intestine with EDTA, and the RNA was extracted from both wild-type and interferon (IFN)-gamma receptor knockout mice. Messenger RNA (mRNA) was measured by Northern blotting, RNase protection assay, and real-time polymerase chain reaction and Ia localized by immunohistochemistry. RESULTS: By day 31, CIITA mRNA was induced in the intestinal epithelium of normally weaned wild-type mice, and this mirrored the expression of Ii chain mRNA. Mice weaned onto an elemental diet did not exhibit Ii mRNA or increased CIITA mRNA in the intestinal epithelium by day 31, but low levels of Ii mRNA were detectable by day 45. Of the 3 isoforms of CIITA, weaning onto a complex diet induced only CIITA IV by day 31. Mice deficient in the IFN-gamma receptor expressed Ia in the epithelium and they also accumulated Ii mRNA (at low levels) by day 45, irrespective of diet. CIITA III mRNA accumulation mirrored the dietary-independent changes of Ii mRNA. CONCLUSIONS: Two mechanisms regulate Ii in the mouse intestinal epithelium: a rapid one, which is diet-induced acting through CIITA IV; and a slower, dietary-independent pathway, acting through CIITA III.