Efficient detection of alport syndrome COL4a5 mutations with multiplex genomic PCR‐SSCP

We have performed effective mutation screening of COL4A5 with a new method of direct, multiplex genomic amplification that employs a single buffer condition and PCR profile. Application of the method to a consecutive series of 46 United States patients with diverse indications of Alport syndrome resulted in detection of mutations in 31 cases and of five previously unreported polymorphisms. With a correction for the presence of cases that are not likely to be due to changes at the COL4A5 locus, the mutation detection sensitivity is greater than 79%. The test examines 52 segments, including the COL4A6/COL4A5 intergenic promoter region, all 51 of the previously recognized exons and two newly detected exons between exons 41 and 42 that encode an alternatively spliced mRNA segment. New genomic sequence information was generated and used to design primer pairs that span substantial intron sequences on each side of all 53 exons. For SSCP screening, 16 multiplex PCR combinations (15 4‐plex and 1 3‐plex) were used to provide complete, partially redundant coverage of the gene. The selected combinations allow clear resolution of products from each segment using various SSCP gel formulations. One of the 29 different mutations detected initially seemed to be a missense change in exon 32 but was found to cause exon skipping. Another missense variant may mark a novel functional site located in the collagenous domain. © 2001 Wiley‐Liss, Inc.     

A stop codon mutation in COL11A2 induces exon skipping and leads to non-ocular Stickler syndrome

Mutations in COL11A2 cause a spectrum of phenotypes affecting chondrogenic tissues. We analyzed this gene by conformation sensitive gel electrophoresis (CSGE) and sequencing in a family with non-ocular Stickler syndrome, and found a heterozygous C --> T mutation in exon 57 + 13 in affected members, resulting in Arg893Stop codon. Since heterozygous nonsense mutations in COL11A2 do not usually lead to any obvious phenotype, all exons and exon boundaries of COL11A2 in the sample of the propositus were sequenced. Because no disease-associated alterations were found, we performed RT-PCR analysis on the RNA. Analysis showed skipping of exon 57 in one allele, resulting in an inframe deletion of 54 bp or 18 amino acids, which would explain the phenotype observed in the family. Thus, the exon skipping resulted from a nonsense-associated altered splicing (NAS). This article contains supplementary material, which may be viewed at the American Journal of Medical Genetics website at http://www.interscience.wiley.com/jpages/0148-7299/suppmat/index.html.     

Missense and nonsense mutations in the alternatively-spliced exon 2 of COL2A1 cause the ocular variant of Stickler syndrome

Stickler syndrome type I (STL1) is a phenotypically heterogeneous disorder characterized by ocular and extraocular features. It is caused by null-allele mutations in the COL2A1 gene that codes for procollagen II. COL2A1 precursor mRNA undergoes alternative splicing, resulting in two isoforms, a long form including exon 2 (type IIA isoform) and a short form excluding exon 2 (type IIB isoform). The short form is predominantly expressed by differentiated chondrocytes in adult cartilage, and the long form in chondroprogenitor cells during early development and in the vitreous of the eye, which is the only adult tissue containing procollagen IIA. Recent evidence indicates that due to the tissue-specific expression of these two isoforms, premature termination codon mutations in exon 2 cause Stickler syndrome with minimal or no extraocular manifestations. We describe here two mutations in exon 2 of COL2A1 in three patients with predominantly ocular Stickler syndrome: Cys64Stop in two patients, and a novel structural mutation, Cys57Tyr, in one patient. RT-PCR of total lymphoblast RNA from one patient with the Cys64Stop mutation revealed that only the normal allele of the IIA form was present, indicating that the mutation resulted either in complete loss of the allele by nonsense-mediated mRNA decay or by skipping of exon 2 via nonsense-mediated altered splicing, resulting in production of the type IIB isoform. The results of COL2A1 minigene expression studies suggest that both Cys64Stop and Cys57Tyr alter positive cis regulatory elements for splicing, resulting in a lower IIA:IIB ratio.     

Efficient detection of Alport syndrome COL4A5 mutations with multiplex genomic PCR-SSCP

We have performed effective mutation screening of COL4A5 with a new method of direct, multiplex genomic amplification that employs a single buffer condition and PCR profile. Application of the method to a consecutive series of 46 United States patients with diverse indications of Alport syndrome resulted in detection of mutations in 31 cases and of five previously unreported polymorphisms. With a correction for the presence of cases that are not likely to be due to changes at the COL4A5 locus, the mutation detection sensitivity is greater than 79%. The test examines 52 segments, including the COL4A6/COL4A5 intergenic promoter region, all 51 of the previously recognized exons and two newly detected exons between exons 41 and 42 that encode an alternatively spliced mRNA segment. New genomic sequence information was generated and used to design primer pairs that span substantial intron sequences on each side of all 53 exons. For SSCP screening, 16 multiplex PCR combinations (15 4-plex and 1 3-plex) were used to provide complete, partially redundant coverage of the gene. The selected combinations allow clear resolution of products from each segment using various SSCP gel formulations. One of the 29 different mutations detected initially seemed to be a missense change in exon 32 but was found to cause exon skipping. Another missense variant may mark a novel functional site located in the collagenous domain.     

High efficiency of mutation detection in type 1 stickler syndrome using a two-stage approach: vitreoretinal assessment coupled with exon sequencing for screening COL2A1

Stickler syndrome is a genetically heterogeneous disorder that affects the ocular, skeletal, and auditory systems. To date three genes, COL2A1, COL11A1, and COL11A2, encoding the heterotypic type II/XI collagen fibrils present in vitreous and cartilage have been shown to have mutations that result in Stickler syndrome. As systemic features in this disorder are variable we have used an ophthalmic examination to differentiate those patients with a membranous vitreous phenotype associated with mutations in COL2A1, from other patients who may have mutations in other genes. Gene amplification and exon sequencing was used to screen 50 families or sporadic cases with this membranous phenotype, for mutations in COL2A1. Mutations were detected in 47 (94%) cases consisting of 166 affected and 78 unaffected individuals. We also demonstrate that the predominantly ocular form of type 1 Stickler syndrome is not confined to mutations in the alternatively spliced exon 2. Using splicing reporter constructs we demonstrate that a mutant GC donor splice site in intron 51 can be spliced normally; this contributed to the predominantly ocular phenotype in the family in which it occurred.     

Therapeutic potential and mechanism of kinetin as a treatment for the human splicing disease familial dysautonomia

Mutations that affect the splicing of pre-mRNA are a major cause of human disease. Familial dysautonomia (FD) is a recessive neurodegenerative disease caused by a T to C transition at base pair 6 of IKBKAP intron 20. This mutation results in variable tissue-specific skipping of exon 20. Previously, we reported that the plant cytokinin kinetin dramatically increases exon 20 inclusion in RNA isolated from cultured FD cells. The goal of the current study was to investigate the nature of the FD splicing defect and the mechanism by which kinetin improves exon inclusion, as such knowledge will facilitate the development of future therapeutics aimed at regulating mRNA splicing. In this study, we demonstrate that treatment of FD lymphoblast cell lines with kinetin increases IKBKAP mRNA and IKAP protein to normal levels. Using a series of minigene constructs, we show that deletion of a region at the end of IKBKAP exon 20 disrupts the ability of kinetin to improve exon inclusion, pinpointing a kinetin responsive sequence element. We next performed a screen of endogenously expressed genes with multiple isoforms resulting from exon skipping events and show that kinetin's ability to improve exon inclusion is not limited to IKBKAP. Lastly, we highlight the potential of kinetin for the treatment of other human splicing disorders by showing correction of a splicing defect in neurofibromatosis.