The Alu-rich genomic architecture of SPAST predisposes to diverse and functionally distinct disease-associated CNV alleles
Boone, P. M.; Yuan, B.; Campbell, I. M.; Scull, J. C.; Withers, M. A.; Baggett, B. C.; Beck, C. R.; Shaw, C. J.; Stankiewicz, P.; Moretti, P.; Goodwin, W. E.; Hein, N.; Fink, J. K.; Seong, M. W.; Seo, S. H.; Park, S. S.; Karbassi, I. D.; Batish, S. D.; Ordóñez‐Ugalde, Andrés; Quintans Castro, Beatriz; Sobrido Gómez, María Jesús; Stemmler, S.; Lupski, J. R.
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Fecha de publicación
2014Título de revista
AMERICAN JOURNAL OF HUMAN GENETICS
Tipo de contenido
Artigo
MeSH
Adenosine Triphosphatases | Alu Elements | Base Sequence | Cation Transport Proteins | Cell Line, Transformed | DNA Copy Number Variations | Genotype | Humans | Protein Isoforms | Recombinant Fusion Proteins | Sequence Analysis, DNA | Sequence Deletion | Spastic Paraplegia, Hereditary | SpastinResumen
Intragenic copy-number variants (CNVs) contribute to the allelic spectrum of both Mendelian and complex disorders. Although pathogenic deletions and duplications in SPAST (mutations in which cause autosomal-dominant spastic paraplegia 4 [SPG4]) have been described, their origins and molecular consequences remain obscure. We mapped breakpoint junctions of 54 SPAST CNVs at nucleotide resolution. Diverse combinations of exons are deleted or duplicated, highlighting the importance of particular exons for spastin function. Of the 54 CNVs, 38 (70%) appear to be mediated by an Alu-based mechanism, suggesting that the Alu-rich genomic architecture of SPAST renders this locus susceptible to various genome rearrangements. Analysis of breakpoint Alus further informs a model of Alu-mediated CNV formation characterized by small CNV size and potential involvement of mechanisms other than homologous recombination. Twelve deletions (22%) overlap part of SPAST and a portion of a nearby, directly oriented gene, predicting novel chimeric genes in these subjects' genomes. cDNA from a subject with a SPAST final exon deletion contained multiple SPAST:SLC30A6 fusion transcripts, indicating that SPAST CNVs can have transcriptional effects beyond the gene itself. SLC30A6 has been implicated in Alzheimer disease, so these fusion gene data could explain a report of spastic paraplegia and dementia cosegregating in a family with deletion of the final exon of SPAST. Our findings provide evidence that the Alu genomic architecture of SPAST predisposes to diverse CNV alleles with distinct transcriptional--and possibly phenotypic--consequences. Moreover, we provide further mechanistic insights into Alu-mediated copy-number change that are extendable to other loci.