Mutational analysis of 85 mucopolysaccharidosis type I families: frequency of known mutations, identification of 17 novel mutations and in vitro expression of missense mutations

The lysosomal storage disorder, mucopolysaccharidosis type I (MPS I), is caused by a deficiency of the enzyme alpha-L-iduronidase, which is involved in the breakdown of dermatan and heparan sulphates. There are three clinical phenotypes, ranging from the Hurler form characterised by skeletal abnormalities, hepatosplenomegaly and severe mental retardation, to the milder Scheie phenotype where there is aortic valve disease, corneal clouding, limited skeletal problems, but no mental retardation. In this study, 85 MPS I families (73 Hurler, 5 Hurler/Scheie, 7 Scheie) were screened for 9 known mutations (Q70X, A75T, 474-2a>g, L218P, A327P, W402X, P533R, R89Q, 678-7g>a). W402X was the most frequent mutation in our population (45.3%) and Q70X was the second most frequent (15.9%). In 30 families, either one or both of the mutations were not identified, which accounted for 25.9% of the total alleles. Therefore, all 14 exons of the alpha-L-iduronidase gene were screened in these patients and 23 different sequence changes were found, 17 of which were previously unknown. The novel sequence changes include 4 deletions (153delC, 628del5, 740delC, 747delG), 5 nonsense mutations (Q60X, Y167X, Q400X, R619X, R628X), 6 missense mutations (C205Y, G208V, H240R, A319V, P496R, S633L), a splice site mutation (IVS12+5g>a), and a rare polymorphism (A591T). The polymorphism and novel missense mutations were transiently expressed in COS-7 cells and all of them except the polymorphism showed complete loss of enzyme activity. In total, 165 of the 170 mutant alleles were identified in this study and despite the high frequency of W402X and Q70X, the identification of many novel mutations unique to individual families further highlights the genetic heterogeneity of MPS I.     

The alpha-L-iduronidase mutations R89Q and R89W result in an attenuated mucopolysaccharidosis type I clinical presentation

Mucopolysaccharidosis type I (MPS I; McKusick 25280; Hurler syndrome, Hurler-Scheie syndrome and Scheie syndrome) is caused by a deficiency in the lysosomal hydrolase, alpha-L-iduronidase (EC 3.2.1.76). MPS I patients present within a clinical spectrum bounded by the extremes of Hurler and Scheie syndromes. The alpha-L-iduronidase missense mutations R89Q and R89W were investigated and altered an important arginine residue proposed to be a nucleophile activator in the catalytic mechanism of alpha-L-iduronidase. The R89Q alpha-L-iduronidase mutation was shown to result in a reduced level of alpha-L-iduronidase protein (< or =10% of normal control) compared to a normal control level of alpha-L-iduronidase protein that was detected for the R89W alpha-L-iduronidase mutation. When taking into account alpha-L-iduronidase specific activity, the R89W mutation had a greater effect on alpha-L-iduronidase activity than the R89Q mutation. However, overall the R89W mutation produced more residual alpha-L-iduronidase activity than the R89Q mutation. This was consistent with MPS I patients, with an R89W allele, having a less severe clinical presentation compared to MPS I patients with either a double or single allelic R89Q mutation. The effects of the R89Q and R89W mutations on enzyme activity supported the proposed role of R89 as a nucleophile activator in the catalytic mechanism of alpha-L-iduronidase.     

Three novel α-L-iduronidase mutations in 10 unrelated Chinese mucopolysaccharidosis type I families

Mucopolysaccharidosis type I (MPS I) arises from a deficiency in the α-L-iduronidase (IDUA) enzyme. Although the clinical spectrum in MPS I patients is continuous, it was possible to recognize 3 phenotypes reflecting the severity of symptoms, viz., the Hurler, Scheie and Hurler/Scheie syndromes. In this study, 10 unrelated Chinese MPS I families (nine Hurler and one Hurler/Scheie) were investigated, and 16 mutant alleles were identified. Three novel mutations in IDUA genes, one missense p.R363H (c.1088G > A) and two splice-site mutations (c.1190-1G > A and c.792+1G > T), were found. Notably, 45% (nine out of 20) and 30% (six out of 20) of the mutant alleles in the 10 families studied were c.1190-1G > A and c.792+1G > T, respectively. The novel missense mutation p.R363H was transiently expressed in CHO cells, and showed retention of 2.3% IDUA activity. Neither p.W402X nor p.Q70X associated with the Hurler phenotype, or even p.R89Q associated with the Scheie phenotype, was found in this group. Finally, it was noted that the Chinese MPS I patients proved to be characterized with a unique set of IDUA gene mutations, not only entirely different from those encountered among Europeans and Americans, but also apparently not even the same as those found in other Asian countries.     

Autosomal recessive phosphorylase kinase deficiency in liver, caused by mutations in the gene encoding the beta subunit (PHKB).

The association of autosomal recessive phosphorylase kinase deficiency in liver of a 3 1/2-year-old female child with mutations in the gene encoding the common part of the beta subunit of phosphorylase kinase is reported. The proband had a severe deficiency of phosphorylase kinase in liver, while the phosphorylase kinase activity in erythrocytes was only slightly diminished. She had no symptoms of muscle involvement. The complete coding sequences of the liver gamma subunit and of the beta subunit of phosphorylase kinase of the proband were analyzed for the presence of mutations, by either reverse-transcribed PCR or SSCP analysis. Three deviations from the normal sequence were found in the region encoding the common part of the beta subunit of phosphorylase kinase-namely, a 1827G-->A (W609X) transition, a 2309A-->G (Y770C) transition, and a deletion of nucleotides 2896-2911-whereas no mutations were detected in the sequence encoding the liver gamma subunit of phosphorylase kinase. The 1827G-->A mutation and the deletion both result in the formation of early stop codons. Investigation of DNA showed that the deletion is caused by a splice-acceptor site mutation (IVS30(-1),g-->t). Family analysis revealed that the 1827G-->A and IVS30(-1),g-->t substitutions are located on different parental chromosomes and that compound heterozygosity for these mutations segregates with the disease. The 2309A-->G mutation was detected in 2%-3% of the normal population. Thus, it is concluded that the deficiency of phosphorylase kinase in this proband is caused by compound heterozygosity for the 1827G-->A and the IVS30(-1),g-->t mutations and that the 2309A-->G mutation is a polymorphism. This implies that a defect in the sequence encoding the common part of the beta subunit of phosphorylase kinase may present as liver phosphorylase kinase deficiency.     

Molecular diagnosis of mucopolysaccharidosis type II (Hunter syndrome) by automated sequencing and computer-assisted interpretation: toward mutation mapping of the iduronate-2-sulfatase gene.

Virtually all mutations causing Hunter syndrome (mucopolysaccharidosis type II) are expected to be new mutations. Therefore, as a means of molecular diagnosis, we developed a rapid method to sequence the entire iduronate-2-sulfatase (IDS) coding region. PCR amplicons representing the IDS cDNA were sequenced with an automatic instrument, and output was analyzed by computer-assisted interpretation of tracings, using Staden programs on a Sun computer. Mutations were found in 10 of 11 patients studied. Unique missense mutations were identified in five patients: H229Y (685C-->T, severe phenotype); P358R (1073C-->G, severe); R468W (1402C-->T, mild); P469H (1406C-->A, mild); and Y523C (1568A-->G, mild). Non-sense mutations were identified in two patients: R172X (514C-->T, severe) and Q389X (1165C-->T, severe). Two other patients with severe disease had insertions of 1 and 14 bp, in exons 3 and 6, respectively. In another patient with severe disease, the predominant (> 95%) IDS message resulted from aberrant splicing, which skipped exon 3. In this last case, consensus sequences for splice sites in exon 3 were intact, but a 395 C-->G mutation was identified 24 bp upstream from the 3' splice site of exon 3. This mutation created a cryptic 5' splice site with a better consensus sequence for 5' splice sites than the natural 5' splice site of intron 3. A minor population of the IDS message was processed by using this cryptic splice site; however, no correctly spliced message was detected in leukocytes from this patient. The mutational topology of the IDS gene is presented.     

Development of a mutation hotspot detection kit for the phenylalanine hydroxylase gene by ARMS-PCR combined with fluorescent probe technology

To develop a screening kit for detecting mutation hotspots of the phenylalanine hydroxylase (PAH) gene. Thirteen exons of the PAH gene were sequenced in 84 cases with phenylketonuria (PKU) diagnosed during neonatal genetic and metabolic disease screening in Shaanxi province, and their mutations were analyzed. We designed and developed a screening kit to detect nine mutation sites covering more than 50% of the PAH mutations found in Shaanxi province (c.728G>A, c.1197A>T, c.331C>T, c.1068C>A, c.611A>G, c.1238G>C, c.721C>T, c.442-1G>A, and c.158G>A) by using amplification refractory mutation system-polymerase chain reaction (ARMS-PCR) combined with fluorescent probe technology. Peripheral blood and dried blood samples from PKU families were used for clinical verification of the newly developed kit. PAH gene mutations were detected in 84 children diagnosed with PKU. A total of 159 mutant alleles were identified, consisting of 100 missense mutations, 28 shear mutations, 24 nonsense mutations, and 7 deletion mutations. Exon 7 had the highest mutation frequency (32.08%). Among them, the mutation frequency of p.R243Q was the highest, accounting for 20.13% of all mutations, followed by p.R111X, IVS4-1G>A, EX6-96A>G, and p.R413P; these five loci accounted for 47.17% (75/159) of all mutations. In addition, we identified three previously unreported PAH gene mutations (p.C334X, p.G46D, and p.G256D). Fifteen mutation sites were identified in the 47 PAH carriers identified by next-generation sequencing (NGS), which were verified by the newly developed kit, with an agreement rate of 100%. This newly developed kit based on ARMS-PCR combined with fluorescent probe technology can be used to detect common PAH gene mutations.     

Mutation analysis of the Fanconi anemia gene FACC.

Fanconi anemia (FA) is a genetically heterogeneous autosomal recessive disorder characterized by a unique hypersensitivity of cells to DNA cross-linking agents; a gene for complementation group C (FACC) has recently been cloned. We have amplified FACC exons with their flanking intron sequences from genomic DNA from 174 racially and ethnically diverse families in the International Fanconi Anemia Registry and have screened for mutations by using SSCP analysis. We identified eight different variants in 32 families; three were detected in exon 1, one in exon 4, one in intron 4, two in exon 6, and one in exon 14. Two of the eight variants, in seven families, did not segregate with the disease allele in multiplex families, suggesting that these variants represented benign polymorphisms. Disease-associated mutations in FACC were detected in a total of 25 (14.4%) of 174 families screened. The most frequent mutations were IVS4 + 4 A-->T (intron 4; 12 families) and 322delG (exon 1; 9 families). Other, less common mutations include Q13X in exon 1, R185X and D195V in exon 6, and L554P in exon 14. The polymorphisms were S26F in exon 1 and G139E in exon 4. All patients in our study with 322delG, Q13X, R185X, and D195V are of northern or eastern European or southern Italian ancestry, and 18 of 19 have a mild form of the disease, while the 2 patients with L554P, both from the same family, have a severe phenotype. All 19 patients with IVS4 + 4 A-->T have Jewish ancestry and have a severe phenotype.     

Mutations of the phenylalanine hydroxylase gene in patients with phenylketonuria in Shanxi,China

The variation in mutations in exons 3, 6, 7, 11 and 12 of the phenylalanine hydroxylase (PAH) gene was investigated in 59 children with phenylketonuria (PKU) and 100 normal children. Three single nucleotide polymorphisms were detected by sequence analysis. The mutational frequencies of cDNA 696, cDNA 735 and cDNA 1155 in patients were 96.2%, 76.1% and 7.6%, respectively, whereas in healthy children the corresponding frequencies were 97.0%, 77.3% and 8.3%. In addition, 81 mutations accounted for 61.0% of the mutant alleles. R111X, H64 > TfsX9 and S70 del accounted for 5.1%, 0.8% and 0.8% mutation of alleles in exon 3, whereas EX6-96A > G accounted for 10.2% mutation of alleles in exon 6. R243Q had the highest incidence in exon 7 (12.7%), followed by Ivs7 + 2 T > A (5.1%) and T278I (2.5%). G247V, R252Q, L255S, R261Q and E280K accounted for 0.8% while Y356X and V399V accounted for 5.9% and 5.1%, respectively, in exon 11. R413P and A434D accounted for 5.9% and 2.5%, respectively, in exon 12. Seventy-two variant alleles accounted for the 16 mutations observed here. The mutation characteristics and distributions demonstrated that EX6-96A > G and R243Q were the hot regions for mutations in the PAH gene in Shanxi patients with PKU.     

alpha-L-iduronidase premature stop codons and potential read-through in mucopolysaccharidosis type I patients

alpha-L-Iduronidase is a glycosyl hydrolase involved in the sequential degradation of the glycosaminoglycans heparan sulphate and dermatan sulphate. A deficiency in alpha-L-iduronidase results in the lysosomal accumulation and urinary secretion of partially degraded glycosaminoglycans and is the cause of the lysosomal storage disorder mucopolysaccharidosis type I (MPS I; Hurler and Scheie syndromes; McKusick 25280). The premature stop codons Q70X and W402X are two of the most common alpha-l-iduronidase gene (IDUA) mutations accounting for up to 70% of MPS I disease alleles in some populations. Here, we have reported a new mutation, making a total of 15 different mutations that can cause premature IDUA stop codons and have investigated the biochemistry of these mutations. Natural stop codon read-through was dependent on the fidelity of the codon when evaluated at Q70X and W402X in CHO-K1 cells, but the three possible stop codons TAA, TAG and TGA, had different effects on mRNA stability and this effect was context dependent. In CHO-K1 cells expressing the Q70X and W402X mutations, the level of gentamicin-enhanced stop codon read-through was slightly less than the increment in activity caused by a lower fidelity stop codon. In this system, gentamicin had more effect on read-through for the TAA and TGA stop codons when compared to the TAG stop codon. In an MPS I patient study, premature TGA stop codons were associated with a slightly attenuated clinical phenotype, when compared to classical Hurler syndrome (e.g. W402X/W402X and Q70X/Q70X genotypes with TAG stop codons). Natural read-through of premature stop codons is a potential explanation for variable clinical phenotype in MPS I patients. Enhanced stop codon read-through is a potential treatment strategy for a large sub-group of MPS I patients.     

Molecular characterization of the Enterobacter aerogenes tonB gene: identification of a novel type of tonB box suppressor mutant.

The tonB gene of Enterobacter aerogenes was cloned, sequenced, and expressed in Escherichia coli. It complemented an E. coli tonB mutant as efficiently as E. coli tonB, except for colicin B and D sensitivities. However, colicin B and D sensitivities were complemented by a derivative in which the aspartate at position 165 was replaced by a glutamine (TonBD-165-->Q) by site-directed mutagenesis. In E. coli, the corresponding amino acid is a glutamine (Q-160) which is known to be altered in most mutants showing suppression of the btuB451 mutation. Fourteen independent btuB451 suppressor mutations in E. aerogenes tonB which all had suffered the same point mutation resulting in a change from glycine to valine at position 239 (G-239-->V) of the C-terminal end of the protein were isolated. The mutation was located within a region which is nonessential for function of E. aerogenes TonB as well as E. coli TonB. A constructed double mutation, expressing a D-165-->Q/G-239-->V derivative, no longer acted as a btuB451 suppressor. However, it restored colicin B and D sensitivities even more efficiently than the D-165-->Q derivative. Corresponding mutations constructed in E. coli tonB, giving rise to Q-160-->D, G-234-->V, and Q-160-->D/G-234-->V derivatives, showed phenotypes comparable to the E. aerogenes mutations. We take this as evidence that at least a functional interaction between the D-165 (Q-160 in E. coli) and the G-239 (G-234 in E. coli) region is necessary for TonB function. The implications of this interaction for functional instability of TonB are discussed.     

Analysis of the phenylalanine hydroxylase gene in the Spanish population: mutation profile and association with intragenic polymorphic markers.

The aim of this study was to characterize the phenylketonuria (PKU) alleles in the Spanish population, by both identifying the causative mutations and analyzing the RFLP haplotypes and the VNTR and short-tandem-repeat alleles associated with the phenylalanine hydroxylase (PAH) gene. We have investigated 129 independent mutant chromosomes, using denaturing gradient gel electrophoresis (DGGE) and direct sequencing. Ninety percent of the alleles were identified, and a total of 40 different mutations were detected. The mutational spectrum includes seven previously unreported mutations: P122Q, D129G, P147S, D151G, A165T, S196fs, and P407S. Seven mutations represent 43% of the Spanish PKU alleles, the most common being IVS10nt-11g-->a (14.7%), I65T (8.5%), and V388M (6.2%). The remaining 33 mutations are rare. The mutation profile and relative frequencies are markedly different from those in northern Europe, also showing unique features compared with those in other, southern European populations. The association analysis with polymorphic markers in the PAH gene provides valuable information for population-genetic studies and investigation of the origins of the mutations. This study may serve as reference in the analysis of the contemporary distributions and frequencies of the PKU mutations in related populations, with particular relevance in Latin American countries.     

Mutations of SCN4A gene cause different diseases: 2 case reports and literature review

SCN4A encodes the Nav1.4 channel and mutations in SCN4A lead to different ionic channelopathies. In this study, one sporadic individual of periodic paralysis, one paramyotonia family and 200 normal healthy controls are enrolled. Genomic DNA was extracted from peripheral blood leukocytes, followed by polymerase chain reaction and DNA sequencing of candidate genes, including SCN4A and CACNA1S. As a result, heterozygous mutations c.2024G>A (R675Q) and c.1333G>A (V445M) of gene SCN4A were identified in the hypokalemic periodic paralysis patient and the paramyotonia congenita family respectively. Both mutations were not detected in healthy controls. Compared with reported cases, patients with mutation R675Q usually do not present hypokalemic periodic paralysis but hyperkalemic or normokalemic periodic paralysis. The mutation V445M was first reported in Chinese patients with nondystrophic myotonias. In addition, we carried out literature review by summarizing clinical features of the 2 mutations and establish the genotype–phenotype correlations to provide guidance for diagnosis.     

High frequency of GJB2 gene mutations in Polish patients with prelingual nonsyndromic deafness

We report an analysis of 102 unrelated Polish patients with profound prelingual deafness for mutations in the GJB2 gene (OMIM #220290). Mutations were found in 41/102 (40%) subjects. Among mutated alleles, 35delG was prevalent and present in 88%. In nine alleles, different mutations were found: M34T, Q47X, R184P, and 313del14 (found in 6 patients). The results prove mutations in the GJB2 gene are responsible for much hereditary nonsyndromic deafness in Poland, with a strong prevalence of the 35delG mutation. We have also found a high carrier frequency (1/50) for the 35delG mutation in the Polish population.     

Mutational Analysis of the TYR and OCA2 Genes in Four Chinese Families with Oculocutaneous Albinism

Background

Oculocutaneous albinism (OCA) is an autosomal recessive disorder. The most common type OCA1 and OCA2 are caused by homozygous or compound heterozygous mutations in the tyrosinase gene (TYR) and OCA2 gene, respectively.

Objective

The purpose of this study was to evaluate the molecular basis of oculocutaneous albinism in four Chinese families.

Patients and Methods

Four non-consanguineous OCA families were included in the study. The TYR and OCA2 genes of all individuals were amplified by polymerase chain reaction (PCR), sequenced and compared with a reference database.

Results

Four patients with a diagnosis of oculocutaneous albinism, presented with milky skin, white or light brown hair and nystagmus. Genetic analyses demonstrated that patient A was compound heterozygous for c.1037-7T.A, c.1037-10_11delTT and c.1114delG mutations in the TYR gene; patient B was heterozygous for c.593C>T and c.1426A>G mutations in the OCA2 gene, patients C and D were compound heterozygous mutations in the TYR gene (c.549_550delGT and c.896G>A, c.832C>T and c.985T>C, respectively). The heterozygous c.549_550delGT and c.1114delG alleles in the TYR gene were two novel mutations. Interestingly, heterozygous members in these pedigrees who carried c.1114delG mutations in the TYR gene or c.1426A>G mutations in the OCA2 gene presented with blond or brown hair and pale skin, but no ocular disorders when they were born; the skin of these patients accumulated pigment over time and with sun exposure.

Conclusion

This study expands the mutation spectrum of oculocutaneous albinism. It is the first time, to the best of our knowledge, to report that c.549_550delGT and c.1114delG mutations in the TYR gene were associated with OCA. The two mutations (c.1114delG in the TYR gene and c.1426A>G in the OCA2 gene) may be responsible for partial clinical manifestations of OCA.     

Mutation Screening of Retinal Dystrophy Patients by Targeted Capture from Tagged Pooled DNAs and Next Generation Sequencing

Purpose

Retinal dystrophies are genetically heterogeneous, resulting from mutations in over 200 genes. Prior to the development of massively parallel sequencing, comprehensive genetic screening was unobtainable for most patients. Identifying the causative genetic mutation facilitates genetic counselling, carrier testing and prenatal/pre-implantation diagnosis, and often leads to a clearer prognosis. In addition, in a proportion of cases, when the mutation is known treatment can be optimised and patients are eligible for enrolment into clinical trials for gene-specific therapies.

Methods

Patient genomic DNA was sheared, tagged and pooled in batches of four samples, prior to targeted capture and next generation sequencing. The enrichment reagent was designed against genes listed on the RetNet database (July 2010). Sequence data were aligned to the human genome and variants were filtered to identify potential pathogenic mutations. These were confirmed by Sanger sequencing.

Results

Molecular analysis of 20 DNAs from retinal dystrophy patients identified likely pathogenic mutations in 12 cases, many of them known and/or confirmed by segregation. These included previously described mutations in ABCA4 (c.6088C>T,p.R2030*; c.5882G>A,p.G1961E), BBS2 (c.1895G>C,p.R632P), GUCY2D (c.2512C>T,p.R838C), PROM1 (c.1117C>T,p.R373C), RDH12 (c.601T>C,p.C201R; c.506G>A,p.R169Q), RPGRIP1 (c.3565C>T,p.R1189*) and SPATA7 (c.253C>T,p.R85*) and new mutations in ABCA4 (c.3328+1G>C), CRB1 (c.2832_2842+23del), RP2 (c.884-1G>T) and USH2A (c.12874A>G,p.N4292D).

Conclusions

Tagging and pooling DNA prior to targeted capture of known retinal dystrophy genes identified mutations in 60% of cases. This relatively high success rate may reflect enrichment for consanguineous cases in the local Yorkshire population, and the use of multiplex families. Nevertheless this is a promising high throughput approach to retinal dystrophy diagnostics.     

Expression and molecular analysis of mutations in prolidase deficiency.

Prolidase (E.C.3.4.13.9) cleaves iminodipeptides. Prolidase deficiency (PD; McKusick 170100) is an autosomal recessive disorder with highly variable penetrance. We have identified two novel alleles in the prolidase gene (PEPD) by direct sequencing of PCR-amplified cDNA from a PD individual asymptomatic at age 11 years: a 551G-->A transition in exon 8 (R184Q) and a 833G-->A transition in exon 12 (G278D). To assess the biochemical phenotypes of these and two previously identified PEPD mutations (G448R and delE452), we have designed a transient-expression system for prolidase in COS-1 cells. The enzyme was expressed as a fusion protein carrying an N-terminal tag, the HA1 epitope of influenza hemagglutinin, allowing its immunological discrimination from the endogenous enzyme with a monoclonal antibody. Expression of the R184Q mutation produced 7.4% of control enzymatic activity whereas the expression of the G278D, G448R, and delE452 mutations produced inactive enzymes. Western analysis of the R184Q, G278D, and G448R prolidases revealed stable immunoreactive material whereas the delE452 prolidase was not detectable. Pulse-chase metabolic labeling of cells followed by immunoprecipitation revealed that the delE452 mutant protein was synthesized but had an increased rate of degradation.     

Molecular genetic defect underlying alpha-L-iduronidase pseudodeficiency.

Mucopolysaccharidosis type I (i.e., Hurler, Hurler-Scheie, and Scheie syndromes) and type II (i.e., Hunter syndrome) are lysosomal storage disorders resulting from alpha-L-iduronidase (IDUA) deficiency and iduronate-2-sulfatase (IDS) deficiency, respectively. The a priori probability that both disorders would occur in a single individual is approximately 1 in 5 billion. Nevertheless, such a proband was referred for whom clinical findings (i.e., a male with characteristic facies, dysostosis multiplex, and mental retardation) and biochemical tests indicated these concomitant diagnoses. In repeated studies, leukocyte 4 methylumbelliferyl-alpha-L-iduronidase activities in this kindred were as follows: <1.0 nmol/mg protein/h in the proband and proband's clinically normal sister; 45.3 in mother; and 45.7 in father (normal range 65.0-140). Leukocyte L-O-(alpha-iduronate-2-sulfate)-(1->4)-D-O-2,5-anhydro[1-3H]mannitol-6- sulfate activities were as follows: 0.0 U/mg protein/h in the proband; 5.7 in his sister; 4.9 in mother; and 15.0 in father (normal range 11.0-18.4). Multiple techniques, including automated sequencing of the entire IDS and IDUA coding regions, were employed to unravel the molecular genetic basis of these intriguing observations. The common IDS mutation R468W was identified in the proband, his mother, and his sister, thus explaining their biochemical phenotypes. Additionally, the proband, his sister, and his father were found to be heterozygous for a common IDUA mutation, W402X. Notably, a new IDUA mutation A300T was also identified in the proband, his sister, and his mother, accounting for reduced IDUA activity in these individuals; the asymptomatic sister, whose cells demonstrated normal glycosaminoglycan metabolism, is thus a compound heterozygote for W402X and the new allele. This A300T mutation is the first IDUA pseudodeficiency gene to be elucidated at the molecular level.     

Mapping of mutations contributing to the temperature sensitivity of the Sabin 1 vaccine strain of poliovirus.

The temperature-sensitive and attenuated phenotypes of the Sabin type 1 vaccine strain of poliovirus result from numerous point mutations which occurred in the virulent Mahoney virus parent. One of these mutations is located in a 3D polymerase (3Dpol) codon (U-6203-->C, Tyr-73-->His) and is involved in attenuation in common mice (M. Tardy-Panit, B. Blondel, A. Martin, F. Tekaia, F. Horaud, and F. Delpeyroux, J. Virol. 67:4630-4638, 1993). This mutation also appears to contribute to temperature sensitivity, in association with at least 1 other of the 10 mutations of the 3'-terminal part of the genome including the 3Dpol coding and 3' noncoding regions. To map the other mutation(s), we constructed poliovirus mutants by mutagenesis and recombination of Mahoney and Sabin 1 cDNAs. Characterization of these poliovirus mutants showed that a second mutation in a 3Dpol codon (C-7071-->U, Thr-362-->Ile) contributes to temperature sensitivity. A mutation in the 3' noncoding region of the genome (A-7441-->G), alone or linked to another mutation (U-7410-->C), also appeared to be involved in this phenotype. The temperature-sensitive effect associated with the 3'-terminal part of the Sabin 1 genome results from the cumulative and/or synergistic effects of at least three genetic determinants, i.e., the His-73 and Ile-362 codons of 3Dpol and nucleotide G-7441. Sequence analysis of strains isolated from patients with vaccine-associated paralytic poliomyelitis showed that these genetic determinants are selected against in vivo, although the Ile-362 codon appeared to be more stable than either the His-73 codon or G-7441. These genetic determinants may contribute to the safety of Sabin 1 in vaccines.     

Novel mutations in the connexin 26 gene (GJB2) that cause autosomal recessive (DFNB1) hearing loss.

Mutations in the connexin 26 (Cx26) gene (GJB2) are associated with the type of autosomal recessive nonsyndromic neurosensory deafness known as "DFNB1." Studies indicate that DFNB1 (13q11-12) causes 20% of all childhood deafness and may have a carrier rate as high as 2. 8%. This study describes the analysis of 58 multiplex families each having at least two affected children diagnosed with autosomal recessive nonsyndromic deafness. Twenty of the 58 families were observed to have mutations in both alleles of Cx26. Thirty-three of 116 chromosomes contained a 30delG allele, for a frequency of .284. This mutation was observed in 2 of 192 control chromosomes, for an estimated gene frequency of .01+/-.007. The homozygous frequency of the 30delG allele is then estimated at .0001, or 1/10,000. Given that the frequency of all childhood hearing impairment is 1/1,000 and that half of that is genetic, the specific mutation 30delG is responsible for 10% of all childhood hearing loss and for 20% of all childhood hereditary hearing loss. Six novel mutations were also observed in the affected population. The deletions detected cause frameshifts that would severely disrupt the protein structure. Three novel missense mutations, Val84Met, Val95Met, and Ser113Pro, were observed. The missense mutation 101T-->C has been reported to be a dominant allele of DFNA3, a dominant nonsyndromic hearing loss. Data further supporting the finding that this mutation does not cause dominant hearing loss are presented. This allele was found in a recessive family segregating independently from the hearing-loss phenotype and in 3 of 192 control chromosomes. These results indicate that 101T-->C is not sufficient to cause hearing loss.     

Hybridization studies of fibroblasts from Hurler,Scheie, and Hurler/Scheie compound patients: Support for the hypothesis of allelic mutants

Summary Heterokaryons were made by fusion of -l-iduronidase-deficient fibroblasts from patients with the Hurler, Scheie, or Hurler/Scheie compound syndrome. The fused cell populations remained -l-iduronidase deficient and accumulated ³⁵S-labeled glycosaminoglycans (³⁵S-GAG) to the same extent as the parental cell strains. Also, when ³⁵S-GAG accumulation was studied by autoradiography at the level of single bi-and multinuclear hybrid cells, no evidence was found for genetic complementation.The results support the hypothesis that the mutations in the Hurler and Scheie syndromes are allelic, and they are compatible with the view that patients with intermediate phenotypes represent genetic compounds.