A deep intronic mutation in CDKN2A is associated with disease in a subset of melanoma pedigrees.

Germline mutations of CDKN2A at 9p21 have been shown to predispose to disease in melanoma pedigrees worldwide. However, there remains a significant proportion of melanoma pedigrees with evidence of linkage to 9p21 in which mutations in CDKN2A have not been detected. Investigation of other potential tumour suppressor genes at 9p21 and the promotor of CDKN2A has been unable to explain genetic predisposition to melanoma in these pedigrees. Here we describe a mutation, IVS2-105 A/G, deep in intron 2 of CDKN2A, detected in six English melanoma pedigrees. The mutation creates a false GT splice donor site 105 bases 5' of exon 3 and has been demonstrated to result in aberrant splicing of the mRNA. This is the most common mutation identified in English families to date. The presence of this deep intronic mutation in a relatively large number of kindreds, indicates that it may account for a significant proportion of 9p21-linked melanoma pedigrees with no detectable mutations in the coding region of CDKN2A. In addition, the identification of one deep intronic mutation in CDKN2A indicates the possibility of the existence of other similar splicing mutations located elsewhere in the CDKN2A introns.     

Genetic diagnostics of pathogenic splicing abnormalities in the clinical laboratory--pitfalls and screening approaches

In recent years, genetic diagnostics of pathogenic splicing abnormalities are increasingly recognized as critically important in the clinical genetic diagnostics. It is reported that approximately 10% of pathogenic mutations causing human inherited diseases are splicing mutations. Nonetheless, it is still difficult to identify splicing abnormalities in routine genetic diagnostic settings. Here, we studied two different kinds of cases with splicing abnormalities. The first case is a protein S deficiency. Nucleotide analyses revealed that the proband had a previously reported G to C substitution in the invariant AG dinucleotide at the splicing acceptor site of intronl/exon2, which produces multiple splicing abnormalities resulting in protein S deficiency. The second case is an antithrombin (AT) deficiency. This proband had a previously reported G to A substitution, at nucleotide position 9788 in intron 4, 14 bp in front of exon 5, which created a de novo exon 5 splice site and resulted in AT deficiency. From a practical standpoint, we discussed the pitfalls, attentions, and screening approaches in genetic diagnostics of pathogenic splicing abnormalities. Due to the difficulty with full-length sequence analysis of introns, and the lack of RNA samples, splicing mutations may escape identification. Although current genetic testing remains to be improved, to screen for splicing abnormalities more efficiently, it is significant to use an appropriate combination of various approaches such as DNA and/or RNA samples, splicing mutation databases, bioinformatic tools to detect splice sites and cis-regulatory elements, and in vitro and/or in vivo experimentally methods as needed.     

A point mutation in the lariat branch point of intron 6 of NPC1 as the cause of abnormal pre-mRNA splicing in Niemann-Pick type C disease

The lariat branch point sequence (BPS) is crucial for splicing pre-mRNA even if BPS mutations have infrequently been reported in human disease. In two siblings with Niemann-Pick type C (NPC) disease we identified two mutations of the NPC1 gene: i) one in exon 20 (c.2932C>T) (p.R978C) previously reported in NPC patients; ii) the other (c.882-28A>G) unreported, in the highly conserved adenosine of a putative lariat BPS of intron 6. Using RT-PCR we found that, besides the normally spliced mRNA, patients' fibroblasts contained minute amounts of an mRNA devoid of exon 7. The exon 6--exon 8 junction in this mRNA causes a frameshift and a premature stop codon, predicted to result in a truncated protein. To assess the effect of c.882-28A>G mutation we constructed two minigenes (wild type and mutant), spanning from intron 5 to intron 8, which were inserted into a pTarget vector and transfected in COS1 cells. The wild type minigene generated an mRNA of the expected size and sequence; the mutant minigene generated only an mRNA devoid of exon 7. This is the first example of a splicing defect due to a mutation in the lariat BPS in an intron of NPC1 found in NPC patients.     

The role of branchpoint and 3'-exon sequences in the control of balanced splicing of avian retrovirus RNA.

We previously described an avian sarcoma-leukosis virus (ASLV) insertion mutation that causes a decrease in the ratio of unspliced to spliced RNA in vivo, resulting in a replication defect. Pseudorevertant viruses containing cis-acting suppressor mutations that restored the normal ratio were isolated. One class of the suppressor mutations consists of single-base changes or small deletions near the 3' splice site, while another consists of deletions in the 3' exon. In this paper we report results from an in vitro analysis of wild-type, mutant, and pseudorevertant pre-mRNA splicing. We find that wild-type RNA is spliced inefficiently in vitro, and that the insertion mutation and suppressors act directly at the level of splicing. Characterization of splicing intermediates reveals that the insertion mutation and suppressor mutations located within the intron alter the pattern of lariat formation. In contrast, suppressor mutations consisting of 3' exon deletions act at an earlier step in the splicing pathway. Thus, the efficiency of splicing at the env 3' splice site can be affected at the level of spliceosome assembly, lariat formation, or cleavage at the 3' splice site and exon ligation.     

Homonucleotide expansion and contraction mutations of PAX2 and inclusion of Chiari 1 malformation as part of renal-coloboma syndrome.

Renal-Coloboma syndrome, an autosomal dominant disorder characterized by colobomatous eye defects, vesicoureteral reflux, and abnormal kidneys, results from mutations in PAX2. The purpose of this study was to identify mutations in PAX2 and understand the associated patient phenotypes. We report a severely affected girl and a mildly affected mother and daughter, all of whom have PAX2 homoguanine tract (7 G) missense mutations. The mother and daughter have optic nerve colobomas and the daughter has vesicoureteral reflux. The severely affected girl developed renal failure and has bilateral colobomatous eye defects. Additionally, this girl developed hydrocephalus associated with platybasia and a Chiari 1 malformation. We examined genomic DNA from these individuals by SSCP and sequencing. The mother and daughter had a novel mutation: a contraction in a string of 7 G's to 6 G's in one allele of PAX2, leading to a premature stop codon two amino acids downstream. The severely affected girl had an expansion to 8 G's, leading to a premature stop codon 27 amino acids downstream. The 8 G expansion has been found in other patients without brain anomalies and has occurred spontaneously in a mouse model, PAX2(1Neu). We expand the known phenotype associated with mutations in PAX2 to include brain malformations. The homoguanine tract in PAX2 is a hot spot for spontaneous expansion or contraction mutations and demonstrates the importance of homonucleotide tract mutations in human malformation syndromes.     

mRNA-type introns in U6 small nuclear RNA genes: implications for the catalysis in pre-mRNA splicing

U6 small nuclear RNA is one of the spliceosomal RNAs involved in pre-mRNA splicing. In the fission yeast Schizosaccharomyces pombe, the U6 RNA gene was found to have an intron similar to a nuclear pre-mRNA intron, and it was proposed that the U6 intron might be inserted erroneously during pre-mRNA splicing. Using the polymerase chain reaction, we analyzed the U6 RNA genes of 52 organisms. In addition to the five species of Schizosaccharomyces, we found that the yeast species Rhodotorula hasegawae and Rhodosporidium dacryoidum also have mRNA-type introns in their U6 genes; however, in all the other organisms tested, we found no intron within the region of the U6 gene examined. Four introns and one intron are present in the R. hasegawae and R. dacryoidum U6 genes, respectively; and these introns are located at sites differing from the location of the Schizosaccharomyces U6 intron. Most of the U6 introns locate within the conserved domain, which is strikingly similar in structure to the catalytic center of the negative strand of the satellite RNA of tobacco ring spot virus. The introns of the S. pombe and R. dacryoidum U6 genes are located immediately adjacent to the nucleotides that were shown to be essential for the second step of the splicing reaction. These results support the notion that U6 RNA has a catalytic role in pre-mRNA splicing and that U6 introns originated from insertion of an excised intron during pre-mRNA splicing.     

Genetic variation at a splicing branch point in intron 9 of the low density lipoprotein (LDL)-receptor gene: a rare mutation that disrupts mRNA splicing in a patient with familial hypercholesterolaemia and a common polymorphism

Mutations in the coding sequence, splice junctions or promoter of the gene for the low density lipoprotein (LDL) receptor are known to be the underlying cause of familial hypercholesterolaemia (FH), but mutations of this type cannot be identified in all patients with a clinical diagnosis of FH. We show here that minor sequence changes elsewhere in introns can be deleterious. A minor rearrangement 30 bp upstream from the junction of intron 9 with exon 10 was detected as a heteroduplex in amplified genomic DNA from one out of 300 heterozygous FH patients. The mutation destroys the only consensus sequence for a splicing branch point in intron 9 and analysis of mRNA from cells from the patient showed that it causes retention of intron 9 or, more rarely, in the use of cryptic splice sites in exon 10. The effect of the mutation on mRNA splicing was confirmed by analysis of mRNA in cells transfected with LDL-receptor mini-gene constructs expressing exons 9 and 10, together with the normal or mutant intron 9. A common C/T polymorphism within this branch point in intron 9 of the LDL-receptor gene does not affect mRNA splicing in vitro and is not associated with significant differences in mean plasma cholesterol concentration in a healthy population.      

Glucose-6-phosphatase gene (727G→T) splicing mutation is prevalent in Hong Kong Chinese patients with glycogen storage disease type la

Glycogen storage disease type la (GSD1a) is an autosomal recessive metabolic disorder caused by a deficiency in glucose-6-phosphatase (GóPase). We analyzed the GóPase genes of two unrelated Chinese families with GSD1a. DNA sequencing of all five exons and the exonintron boundaries revealed a G → T transversion at nucleotide 727 (727G→T) in exon 5, which has previously been reported to cause abnormal splicing. In one family, the subject and her affected sister were confirmed to be homozygous for this mutation and their parents to be heterozygotes. In the other family, the proband was identified to be heterozygous for this mutation, and a novel mutation, the 341delG in exon 2, was identified. This mutation alters the reading frame and creates a stop codon TAA 15 codons downstream from the mutation, resulting in a truncated protein. Family studies revealed that the father was heterozygous for the 727G → T mutation and that the mother was heterozygous for the 341delG mutation. This is the first time that the 727G→T mutation has been found in Chinese patients or outside Japan. Since we only tested two GSDla families and found 727G→T in both, we believe that this mutation may also be prevalent in our local Chinese population. To investigate allele frequencies, we screened 385 Chinese healthy volunteers and found two asymptomatic carriers. Our findings suggest that the 727G → T mutation is indeed prevalent in Hong Kong.     

Functional analysis of cis-acting elements regulating the alternative splicing of human CFTR exon 9.

The rate of exon 9 exclusion from the cystic fibrosis transmembrane conductance regulator (CFTR) mRNA is associated with monosymptomatic forms of cystic fibrosis. Exon 9 alternative splicing is modulated by a polymorphic polythymidine tract within its 3' splice site. We have generated a minigene carrying human CFTR exon 9 with its flanking intronic sequences and set up an in vivo model to study the cis-acting DNA elements which modulate its splicing. Transfections into human cell lines showed that T5, but not T9 or T7 alleles, significantly increases the alternative splicing of exon 9. Moreover, we found that another polymorphic locus juxtaposed upstream of the T tract, and constituted by (TG)(n)repeats, can further modulate exon 9 skipping but only when activated by the T5 allele. Then, we extended our studies to the mouse CFTR exon 9 which does not show alternative splicing. Comparison of human and mouse introns 8 and 9 revealed a low homology between the two sequences and the absence of the human polymorphic loci within the mouse intron 3' splice site. We have tested a series of constructs where the whole human exon 9 with its flanking intronic sequences was replaced partially or completely by the murine counterpart. The transfections of these constructs in human and murine cell lines reveal that also sequences of the downstream intron 9 affect exon 9 definition and co-modulate, with the UG/U 3' splice site sequences, the extent of exon 9 skipping in CFTR mRNA.     

Late infantile neuronal ceroid lipofuscinosis is due to splicing mutations in the CLN2 gene.

Late infantile neuronal ceroid lipofuscinosis, LINCL, is one of the most common pediatric neurodegenerative disorders. It is caused by mutations in the CLN2 gene, which encodes a lysosomal pepstatin-insensitive peptidase (LPIP). We have identified a novel mutation, T523-1G --> A, by molecular analyses of three unrelated LINCL cases. The mutation was found to affect a 3' intronic splicing acceptor site, resulting in an aberrant mRNA with an insertion of 146 bp of intronic sequence. This causes a frame shift, produces a nonfunctional truncated protein, and results in LINCL.     

Candidate gene approach in association studies: would the factor V Leiden mutation have been found by this approach?

A re-emerging strategy in the search for disease susceptibility genes is the evaluation of candidate genes, which are thought to play a role in disease pathogenesis. Candidate genes are screened for single nucleotide polymorphisms (SNPs) in a case-control study. The factor V Leiden (FVL) mutation (1691G --> A in the F5 gene) is an important risk factor for venous thrombosis. We asked ourselves whether the FVL mutation would have been found using the candidate gene approach in the absence of prior knowledge of the haplotype structure of the F5 gene. We typed four SNPs in the F5 gene in the Leiden Thrombophilia study, that is, promoter (99930G --> A), exon 13 (55907A --> G), exon 16 (42855A --> G), and intron 19 (37833T --> G). These SNPs were known to have different population frequencies, making their presence in distinct haplotypes likely. None of these SNPs has previously been associated with venous thrombotic risk. Subsequently we derived haplotypes. One haplotype was clearly more frequent in patients than controls (GAAT; 20 versus 9%), suggesting that a polymorphism in or near the F5 gene in this haplotype is associated with an increased thrombotic risk. If we had sequenced the F5 gene in patients homozygous for this haplotype, in order to locate the possible causal polymorphism, we would have found that 16 (76%) patients were homozygous or heterozygous for a missense mutation in exon 10 (1691G --> A), which predicts the replacement of Arg506 by Gln in one of the cleavage sites for activated protein C, a mutation that we now know as the FVL mutation.     

Mutation of the AAUAAA polyadenylation signal depresses in vitro splicing of proximal but not distal introns.

To investigate the relationship between splicing and polyadenylation during the production of vertebrate mRNAs, we examined the effect of mutation of a poly(A) site on splicing of upstream introns. Mutation of the AAUAAA polyadenylation consensus sequence inhibited in vitro splicing of an upstream intron. The magnitude of the depression depended on the magnesium concentration. Dependence of splicing on polyadenylation signals suggests the existence of interaction between polyadenylation and splicing factors. In multi-intron precursor RNAs containing duplicated splice sites, mutation of the poly(A) site inhibited removal of the last intron, but not the removal of introns farther upstream. Inhibition of removal of only the last intron suggests segmental recognition of multi-exon precursor RNAs and is consistent with previous suggestions that signals at both ends of an exon are required for effective splicing of an upstream intron.