Hereditary tyrosinaemia type I in Norway: incidence and three novel small deletions in the fumarylacetoacetase gene.

A total of 28 Norwegians have been diagnosed with hereditary tyrosinaemia type I (HT1) over the last 30 years. In this study, 19 of these patients were investigated. Three novel small deletions were found (NM_000137.1(FAH): c.615delT, p.Phe205LeufsX2, NM_000137.1(FAH): c.744delG, p.Pro249HisfsX55 and NM_000137.1(FAH):c835delC) pGln279ArgfsX25, all of them leading to a change in the reading frame and a premature stop codon. We hereby genetically characterized 51 of the 56 disease-causing alleles, identifying nine different disease-causing mutations in the Norwegian population. We found that 65% of the Norwegian HT1 patients are compound heterozygous for different mutations. Thus, the relatively high incidence of HT1 in Norway of 1 in 74,800 live births is not due to single founder effects or high incidence of parental consanguinity.

A novel mucopolysaccharidosis type I associated splice site mutation and IDUA splice variants.

Mucopolysaccharidosis type I is an autosomal recessive disorder caused by deficiency of α-l-iduronidase, encoded by the IDUA gene. More than 100 disease causing mutations have been reported in the gene, resulting in a wide range of phenotypes. Here we describe a previously unreported IDUA splice site mutation (NG_008103.1:g.21632G>C; NM_000203.3:c.1727+3G>C) causing a Hurler phenotype in a patient heterozygous for the common p.Q70X (NG_008103.1:g.5862C>T) mutation. Sequence analysis of IDUA transcripts demonstrated that the g.21632G>C mutation results in aberrant splicing of intron 12 (NM_000203.3:c.1727_1728insGTCC), introducing a frame shift and premature termination codon (NP_000194.2:p.Cys577SerfsX15). Gene expression studies suggest that the deleterious effect of the mutation is primarily due to a C-terminal truncation of the encoded polypeptide. Furthermore, we observed that both normal and mutant IDUA alleles give rise to alternatively spliced transcripts in leukocytes. Exclusion of exon 4 appeared to be the predominant alternative splicing event, probably resulting in polypeptides lacking iduronidase activity. The Hurler patient demonstrated exon 4 skipping in 5.6% of IDUA transcripts, while exon 4 skipping ranged 25-34% of transcripts among healthy individuals (n=5). Alternative splicing might represent a mechanism for regulation of this enzyme, and the lower level of exon 4 skipping in the patient might be a response to intracellular accumulation of iduronidase substrates. Molecular characterization of IDUA mutations and splicing may assist early prediction of mucopolysaccharidosis type I phenotypes and increase the understanding of disease mechanisms. This is important considering the choice of current treatment options and for the development of future therapies.

Four novel mutations identified in Norwegian patients result in intermittent maple syrup urine disease when combined with the R301C mutation.

Maple syrup urine disease (MSUD) is caused by a defect in branched chain alpha-ketoacid dehydrogenase complex (BCKD), an essential metabolon for the catabolism of the branched chain amino acids. Here, we report four novel mutations in the DBT gene, encoding the transacylase subunit (E2) of BCKD, resulting in intermittent MSUD in seven Norwegian patients. The patients had episodes with neurological symptoms including lethargy and/or ataxia during childhood infections. All seven patients were heterozygous for the annotated R301C mutation. The second allelic mutations were identified in five patients; one nonsense mutation (G62X), two missense mutations (W84C and R376C) and a mutation in the 3' untranslated region (UTR; c. *358A>C) in two patients. These four novel mutations result in near depletion of E2 protein, and the common R301C protein contributes predominantly to the residual (14%) cellular BCKD activity. Structural analyses of the mutations implied that the W84C and R376C mutations affect stability of intramolecular domains in E2, while the R301C mutation likely disturbs E2 trimer assembly as previously reported. The UTR mutated allele coincided with a strong reduction in mRNA levels, as did the non-R301C specific allele in two patients where the second mutation could not be identified. In summary, the pathogenic effect of the novel mutations is depletion of cellular protein, and the intermittent form of MSUD appears to be attributed to the residual R301C mutant protein in these patients.

Novel Deletion Mutation Identified in a Patient with Late-Onset Combined Methylmalonic Acidemia and Homocystinuria, cblC Type.

Combined methylmalonic aciduria and homocystinuria, cblC type (MMACHC), is the most common inborn error of cellular vitamin B12 metabolism and is caused by mutations in the MMACHC gene. This metabolic disease results in impaired intracellular synthesis of adenosylcobalamin and methylcobalamin, coenzymes for the methylmalonyl-CoA mutase and methionine synthase enzymes, respectively. The inability to produce normal levels of these two coenzymes leads to increased concentrations of methylmalonic acid and homocysteine in plasma and urine, together with normal or decreased concentration of methionine in plasma. Here, we report a novel homozygous deletion mutation (NM_015506.2:c.392_394del) resulting in an in-frame deletion of amino acid Gln131 and late-onset disease in a 23-year-old male. The patient presented with sensory and motoric disabilities, urine and fecal incontinence, and light cognitive impairment. There was an excessive urinary excretion of methylmalonic acid and greatly elevated plasma homocysteine. The clinical symptoms and the laboratory abnormalities responded partly to treatment with hydroxycobalamin, folinic acid, methionine, and betaine. Studies on patient fibroblasts together with spectroscopic activity assays on recombinant MMACHC protein reveal that Gln131 is crucial in order to maintain enzyme activity. Furthermore, structural analyses show that Gln131 is one of only two residues making hydrogen bonds to the tail of cobalamin. Circular dichroism spectroscopy indicates that the 3D structure of the deletion mutant is folded but perturbed compared to the wild-type protein.