Ruth Bargal

Identification of the gene causing mucolipidosis type IV.

Mucolipidosis type IV (MLIV) is an autosomal recessive, neurodegenerative, lysosomal storage disorder characterized by psychomotor retardation and ophthalmological abnormalities including corneal opacities, retinal degeneration and strabismus. Most patients reach a maximal developmental level of 12–15 months. The disease was classified as a mucolipidosis following observations by electron microscopy indicating the lysosomal storage of lipids together with water-soluble, granulated substances. Over 80% of the MLIV patients diagnosed are Ashkenazi Jews, including severely affected and mildly affected patients. The gene causing MLIV was previously mapped to human chromosome 19p13.2–13.3 in a region of approximately 1 cM (ref. 7). Haplotype analysis in the MLIV gene region of over 70 MLIV Ashkenazi chromosomes indicated the existence of two founder chromosomes among 95% of the Ashkenazi MLIV families: a major haplotype in 72% and a minor haplotype in 23% of the MLIV chromosomes (ref. 7, and G.B., unpublished data). The remaining 5% are distinct haplotypes found only in single patients. The basic metabolic defect causing the lysosomal storage in MLIV has not yet been identified. Thus, positional cloning was an alternative to identify the MLIV gene. We report here the identification of a new gene in this human chromosomal region in which MLIV-specific mutations were identified.

Mucolipidosis II is caused by mutations in GNPTA encoding the alpha/beta GlcNAc-1-phosphotransferase

Mucolipidosis II (ML II) is a fatal lysosomal storage disorder resulting from defects in the multimeric GlcNAc-1-phosphotransferase responsible for the initial step in the generation of the mannose 6-phosphate (M6P) recognition marker. M6P residues on oligosaccharides of newly synthesized lysosomal enzymes are essential for efficient receptor-mediated transport to lysosomes. We used the recombinant GlcNAc-1-phosphotransferase γ subunit as an affinity matrix to purify an unknown protein identified as the product of GNPTA (encoding GNPTA, previously known as MGC4170). The cDNA encodes a protein of 1,256 amino acids with two putative transmembrane domains and a complex preserved modular structure comprising at least six domains. The N-terminal domain of GNPTA, interrupted by a long insertion, shows similarities to bacterial capsule biosynthesis proteins. We identified seven mutations in GNPTA that lead to premature translational termination in six individuals with ML II. Retroviral transduction of fibroblasts from an individual with ML II resulted in the expression and localization of GNPTA in the Golgi apparatus, accompanied by the correction of hypersecretion of lysosomal enzymes. Our results provide evidence that GNPTA encodes a subunit of GlcNAc-1-phosphotransferase defective in individuals with ML II.

I-cell disease: Deficiency of extracellular hydrolase phosphorylation

The content of 32P-phosphorylated residues of purified extracellular N-acetyl-β-hexosaminidase obtained from the fibroblasts of I-cell disease patients was compared to that of control cells hydrolase. The analyses indicated a 60-fold decrease of the radioactivity per unit enzyme activity in the hydrolase synthesized by the patients fibroblasts compared to the normal enzyme. Electrofocusing demonstrated again a marked decrease in the 32P-content of the I-cell hydrolase while the control enzyme showed the presence of radioactivity in both isozymes, namely hexosaminidase A and hexosaminidase B. Most of the radioactivity could be removed from the hydrolase following incubation with alkaline phosphatase, thus indicating its phosphoester linkage. Since phosphorylated sugar residues on lysosomal enzymes function as recognition marker for their transport to the lysosomal compartment and for their specific uptake by fibroblasts, the deficiency of phosphorylated residues on the I-cell hydrolase explains the low intracellular and high extracellular lysosomal enzyme levels observed in this disease.

The clinical spectrum of fetal Niemann-Pick type C.

Niemann–Pick type C (NPC) disease is a lysosomal neurovisceral storage disease. The spectrum of the clinical presentation as well as the severity of the disease and the age of presentation may be highly variable. Fetal presentation is rarely described in the literature. Here, we report on seven new cases of fetal onset NPC of whom two were diagnosed in utero and five postnatally. The fetal clinical presentation, included, in utero splenomegaly (6/7), in utero hepatomegaly (5/7), in utero ascites (4/7), intra uterine growth retardation (IUGR) (2/7), and oligohydramnios (2/7). Placentomegaly was present in two of the three pregnancies examined. Congenital thrombocytopenia (4/4), congenital anemia (2/4), and petechial rash (2/5) were diagnosed immediately after birth. Three patients were born preterm. Pregnancy and postnatal outcome were remarkably poor with one case of intrauterine fetal death, one elective termination of pregnancy, and four patients who died within the first months of life from a rapidly fatal neonatal cholestatic disease. NPC1 gene mutation analysis identified all of the mutant alleles including three novel mutations. Splenomegaly, hepatomegaly, and ascites were the most consistent prenatal ultrasonographic findings of the NPC fetuses. We suggest that once identified these findings, should raise the suspicion of fetal NPC. Our study further expands the antenatal clinical spectrum of NPC and provides clues to its prenatal diagnosis.

P35S mutation in the NOG gene associated with Teunissen-Cremers syndrome and features of multiple NOG joint-fusion syndromes

We report on a new family with Teunissen-Cremers syndrome. The proband presented with congenital conductive hearing loss due to stapes ankylosis and incus short process fixation with skeletal anomalies including symphalangism, broad thumbs and broad first toes, syndactyly, brachydactyly, contractures of the elbows and knees, hyperopia and lens opacities. This constellation of symptoms is compatible with the diagnosis of one of the joint-fusion syndromes namely the Teunissen-Cremers syndrome (TCS), which was first reported in 1990. Mutations in the NOG gene which encodes the noggin protein, a bone morphogenetic protein antagonist, have been identified in TCS as well as in four other autosomal dominant disorders including proximal symphalangism (SYM1), multiple synostosis (SYNS1), Tarsal-Carpal coalition syndrome and brachydactyly type B (BDB). Interestingly, we found that the mutation P35S described in this family has already been reported in patients affected with SYM1 as well as with BDB syndromes.

Clinical-biochemical correlation in molecularly characterized patients with Niemann-Pick type C

Purpose: Niemann-Pick disease type C (NP-C) is an autosomal recessive lipid storage disease manifested by an impairment in cellular cholesterol homeostasis. The clinical phenotype of NP-C is extremely variable, ranging from an acute neonatal form to an adult late-onset presentation. To facilitate phenotype-genotype studies, we have analyzed multiple Israeli NP-C families.Methods: The severity of the disease was assessed by the age at onset, hepatic involvement, neurological deterioration, and cholesterol esterification studies. Screening of the entire NPC1 coding sequence allowed for molecular characterization and identification of disease causing mutations.Results: A total of nine NP-C index cases with mainly neurovisceral involvement were characterized. We demonstrated a possible link between the severity of the clinical phenotype and the cholesterol esterification levels in fibroblast cultures following 24 hours of in vitro cholesterol loading. In addition, we identified eight novel mutations in the NPC1 gene.Conclusions: Our results further support the clinical and allelic heterogeneity of NP-C and point to possible association between the clinical and the biochemical phenotype in distinct affected Israeli families.

Phosphatidylcholine storage in mucolipidosis IV

The accumulation of phosphatidylcholine (PC) in cultured fibroblasts of mucolipidosis IV (MLIV) patients was studied by subcellular fractionation on percoll gradients. Labelled PC accumulated in secondary lysosomes of the MLIV cells in significantly higher rates when compared to normal controls incubated with the precursors [32P]phosphate or [14C]choline. This accumulation was noted after 4 days of pulse and became more profound after 7 days of chase resulting in a 30-fold increase of this substance in the lysosomal fraction of MLIV compared to normal controls. On the other hand, no significant increase of radioactive PC was demonstrated in the buoyant fraction of the affected cells, and similarly the rate of disappearance of labeled PC from this fraction was identical in MLIV and controls. The retention of PC in lysosomes of MLIV could also be demonstrated following incubation of cultured fibroblasts with the radioactive phospholipid itself. In these experiments increased labelled PC in MLIV was also noted in endosomes, which are involved in the uptake process of PC enroute to the lysosomes. The metabolic defect leading to this storage in MLIV has not yet been identified, but these data indicate impairment in the lysosomal catabolism of phospholipids in MLIV.

Mucolipidosis type IV: the origin of the disease in the Ashkenazi Jewish population

Mucolipidosis type IV (MLIV) is a neurodegenerative lysosomal storage disease in which most of the patients diagnosed hitherto are Ashkenazi Jews. The basic metabolic defect causing this disease is still unknown and the relevant gene has not yet been mapped or cloned. Seventeen Israel Ashkenazi families with MLIV patients had been interviewed to study their family origin. Although the families immigrated to Israel from various European countries they all could trace their roots three to four generations back to northern Poland or the immediate neighbouring country, Lithuania. Furthermore, there are only one or two ultraorthodox families among the 70–80 Ashkenazi families with MLIV patients worldwide, a marked under-representation of this group which constitutes at least 10% of the Ashkenazi population. This data indicate that MLIV mutation occurred only around the 18th and 19th centuries, after the major expansion of this population, in a founder in this defined European region belonging to a more modern, secular family.

Niemann Pick disease type A in Israeli Arabs: 677delT, a common novel single mutation

A novel single base pair deletion in the acid sphingomyelinase (ASM) gene ( 677delT in the cDNA) was identified in 12 Israeli Arab families with Niemann‐Pick disease (NPD) type A. This deletion creates a premature stop codon which explains the complete deficiency of ASM activity in these patients and the severe clinical manifestation. A single mutation in 12 families living in a relatively small geographical region suggests a founder effect and explains the high frequency of this disease in this population. This is in contrast to multiple mutations found in two other lysosomal storage disorders prevalent in this population, namely, Hurler disease (MPSI) and metachromatic leukodystrophy. Mutation analysis is therefore an important tool in characterizing the grounds for the high frequency of inherited diseases as well as a basis for prevention programs for prevalent diseases through carrier identification and the ascertainment of high risk families. Hum Mutat 12:136, 1998.

Genetic screening for Krabbe disease: learning from the past and looking to the future.

In Israel, Krabbe disease is frequent in two Moslem Arab villages in the Jerusalem area. In this paper we present our experience of almost four decades with diagnosis of Krabbe disease, carrier screening and prenatal diagnosis. The screening program is well accepted by the community, and there is a clear trend towards premarital testing. The screening program and prenatal diagnosis have led to a decrease in the incidence of Krabbe disease from 1.6 per 1,000 live births to 0.82 per 1,000.