Analysis of a 43.6 kb deletion in a patient with Hunter syndrome (MPSII): identification of a fusion transcript including sequences from the gene W and the IDS gene.

Mucopolysaccharidosis type II (Hunter syndrome) is an X-linked lysosomal storage disorder. A novel mutation is described in an MPS II patient in whom the disorder is caused by a 43.6 kb deletion. Southern blot analysis, PCR analysis and subsequent sequencing of the deletion junction revealed that the deletion spans exons 1-7 of the iduronate-2-sulfatase (IDS) gene, the IDS-2 locus and exons 3-5 of the recently identified gene W. Short direct repeats of 12 bp were identified at both deletion breakpoints, suggesting that the deletion is the result of an illegitimate recombination event. A sequence motif (TGAGGA) which is identical to a consensus sequence frequently associated with deletions in man was identified at both breakpoints. This further supports the notion that this motif is a hot spot for recombination. Gene expression studies by RT-PCR analysis of total RNA derived from fibroblasts of the patient revealed the presence of a novel fusion transcript. DNA sequence analysis of the cDNA demonstrated that it consists of exons derived from both the gene W and the IDS gene. A similar but longer fusion transcript containing exons 2-4 of the gene W and exons 4-9 of the IDS gene could also be detected in RNA of normal cell lines originating from different tissues. This result further demonstrates the complex gene expression profile of the IDS region, which may contribute to the observed genomic instability of this region.

Identification of 9 novel IDS gene mutations in 19 unrelated Hunter syndrome (mucopolysaccharidosis Type II) patients. Mutations in brief no. 202. Online.

Hunter syndrome is an X-linked lysosomal storage disorder caused by a deficiency of the lysosomal enzyme iduronate-2-sulfatase (IDS). The IDS deficiency can be caused by several different types of mutations in the IDS gene. We have performed a molecular and mutation analysis of a total 19 unrelated MPS II patients of different ethnic origin and identified 19 different IDS mutations, 9 of which were novel and unique. SSCP analysis followed by DNA sequencing revealed four novel missense mutations: S143F, associated with the 562C-->T polymorphism, C184W, D269V and Y348H. Two novel nonsense mutations were found: Y103X (433C-->A) and Y234X (826C-->G). In two patients two novel minor insertions (42linsA and 499insA) were identified. In one patient a complete IDS deletion was found, extending from locus DXS1185 to locus DXS466).

Two distinct deletions in the IDS gene and the gene W: a novel type of mutation associated with the Hunter syndrome.

A novel mutation has been identified in a patient with the Hunter syndrome (mucopolysaccharidosis type II), in whom the disorder is associated with two distinct deletions separated by 30 kb. The deletions were characterized by Southern blot and PCR analyses, and the nucleotide sequences at both junctions were determined. The first deletion, corresponding to a loss of 3152 bp of DNA, included exons 5 and 6 of the iduronate-2-sulfatase (IDS) gene. The second deletion was 3603 bp long and included exons 3 and 4 of gene W, which is located in the DXS466 locus telomeric of the IDS gene. Both deletions are the result of nonhomologous (illegitimate) recombination events between short direct repeats at the deletion breakpoints. An interesting finding was the presence of the heptamer sequence 5'-TACTCTA-3' present at both deletion junctions, suggesting that this motif might be a hot spot for recombination. We propose that the double deletion is the result of homology-associated nonhomologous recombinations caused by the presence of large duplicated regions in Xq27.3-q28.

Double-strand breaks may initiate the inversion mutation causing the Hunter syndrome.

We have previously shown that patients with the Hunter syndrome frequently have suffered from a recombination event between the IDS gene and its putative pseudogene, IDS-2, resulting in an inversion of the intervening DNA. The inversion, which might be the consequence of an intrachromosomal mispairing, is caused by homologous recombination between sequences located in intron 7 of the IDS gene and sequences located distal of exon 3 in IDS-2. In order to gain insight into the mechanisms causing the inversion, we have isolated both inversion junctions in six unrelated patients. DNA sequence analysis of the junctions showed that all recombinations have taken place within a 1 kb region where the sequence identity is >98%. An interesting finding was the identification of regions with alternating IDS gene and IDS-2 sequences present at one inversion junction, suggesting that the recombination event has been initiated by a double-strand break in intron 7 of the IDS gene. The results from this study suggest that homologous recombination in man could be explained by mechanisms similar to those described for Saccharomyces cerevisiae. The results also have practical implications for diagnosis of patients with the Hunter syndrome.

Identification of an alternative transcript from the human iduronate-2-sulfatase (IDS) gene.

Iduronate-2-sulfatase (IDS) is involved in the degradation of heparan sulfate and dermatan sulfate in the lysosomes, and a deficiency in this enzyme results in Hunter syndrome. A 2.3-kb cDNA clone that contains the entire coding sequence of IDS has previously been reported. Here we describe the identification of a 1.4-kb transcript that may encode an IDS-like enzyme. The predicted protein is identical to the previously described enzyme, except for the absence of the 207-amino-acid COOH-terminal domain, which is replaced by 7 amino-acids. Our data suggest that there might exist an additional form of the IDS enzyme in humans. The results from this study may have implications for the pathogenesis of the Hunter syndrome.

Inversion of the IDS gene resulting from recombination with IDS-related sequences is a common cause of the Hunter syndrome.

We have recently described the identification of a second IDS locus (IDS-2) located within 90 kb telomeric of the IDS gene (Bondeson et al. submitted). Here, we show that this region is involved in a recombination event with the IDS gene in about 13% of patients with the Hunter syndrome. Analysis of the resulting rearrangement at the molecular level showed that these patients have suffered a recombination event that results in a disruption of the IDS gene in intron 7 with an inversion of the intervening DNA. Interestingly, all of the six cases with a similar type of rearrangement showed recombination between intron 7 of the IDS gene and sequences close to exon 3 at the IDS-2 locus implying that these regions are hot spots for recombination. Analysis by nucleotide sequencing showed that the inversion is caused by recombination between homologous sequences present in the IDS gene and the IDS-2 locus. No detectable deletions or insertions were observed as a result of the recombination event. The results in this study have practical implications for diagnosis of the Hunter syndrome.

Presence of an IDS-related locus (IDS2) in Xq28 complicates the mutational analysis of Hunter syndrome.

A deficiency of the enzyme iduronate-2-sulfatase (IDS) is the cause of Hunter syndrome (mucopolysaccharidosis type II). Here, we report a study of the human IDS locus at Xq28. An unexpected finding was an IDS-related region (IDS2) which is located on the telomeric side of the IDS gene within 80 kb. We have identified sequences in this locus that are homologous to exons 2 and 3 as well as sequences homologous to introns 2, 3 and 7 of the IDS gene. The exon 3 sequences in the IDS gene and in the IDS2 locus showed 100% identity. The overall identities of the other identified regions were 96%. A locus for DXS466 was also found to be located close to IDS2. The existence of the IDS2 locus complicates the diagnosis of mutations in genomic DNA from patients with Hunter syndrome. However, information about the IDS2 locus makes it possible to analyze the IDS gene and the IDS2 locus separately after PCR amplification.