Monique M.P. Hermans

Identification of a point mutation in the human lysosomal α-glucosidase gene causing infantile glycogenosis type II

Two patients in a consanguineous Indian family with infantile glycogenosis type II were found to have a G to A transition in exon 11 of the human lysosomal alpha-glucosidase gene. Both patients were homozygous and both parents were heterozygous for the mutant allele. The mutation causes a Glu to Lys substitution at amino acid position 521, just three amino acids downstream from the catalytic site at Asp-518. The mutation was introduced in wild type lysosomal alpha-glucosidase cDNA and the mutant construct was expressed in vitro and in vivo. The Glu to Lys substitution is proven to account for the abnormal physical properties of the patients lysosomal alpha-glucosidase precursor and to prevent the formation of catalytically active enzyme. In homozygous form it leads to the severe infantile phenotype of glycogenosis type II.

Glycogen storage disease type II: Genetic and biochemical analysis of novel mutations in infantile patients from Turkish ancestry

Glycogen Storage Disease type II (GSDII) is caused by the deficiency of lysosomal α‐glucosidase (acid maltase). This paper reports on the characterization of the molecular defects in 6 infantile patients from Turkish ancestry. Five of the 6 patients had reduced levels of the lysosomal α‐glucosidase precursor. Conversion to mature enzyme was impaired in all cases, and the lysosomal α‐glucosidase activity in all patients fibroblasts was less than 0.5% of control. DNA sequence analysis revealed 3 new mutations. One mutation, found in 3 patients in homozygous form, was a double insertion in exon 19 (2471AG→CAGG) leading to a frameshift after Pro 913. It is the first insertion mutation described in the lysosomal α‐glucosidase gene. Two patients were homozygous for missense mutations leading to the substitution of Ser to Pro at amino acid 566 (S566P) in one case and of Pro to Arg at amino acid 768 (P768R) in the other. One patient was found to have a Gly to Arg missense mutation at amino acid 643 (G643R), previously identified in an adult patient (Hermans et al., 1993), combined with a silent second allele. The latter 3 mutations were introduced in the wild type lysosomal α‐glucosidase cDNA and expressed in COS cells to analyze their effect. Precursor species of 110 kD were formed but the maturation was impaired. As a result there was an overall deficiency of catalytic activity, which is in accordance with the findings in the patients fibroblasts and with the clinical phenotype. Hum Mutat 11:209–215, 1998.

l-alanine supplementation in late infantile glycogen storage disease type II

We report a male with late infantile glycogen storage disease type II (Pompes disease) who presented at 12 months of age with muscular hypotonia and developmental delay. Oral supplementation with L-alanine has been administered for 5 years. Progression of skeletal myopathy was slow, and cardiomyopathy resolved almost completely. L-alanine may be a valuable supplement for infants with glycogen storage disease type II.

A case of childhood Pompe disease demonstrating phenotypic variability of p.Asp645Asn

A six-year-old child presented at 8 months of age with proximal muscle weakness and mild cardiac hypertrophy. Some alpha-glucosidase activity was detected in muscle but not in fibroblasts. As none of the two pathogenic mutations, [c.1933G>A]+[c.2702T>A] (Asp645Asn/Leu901Gln), led to detectable alpha-glucosidase activity upon expression in COS cells, the phenotype of the patient remained unexplained. A functionally comparable set of mutations, Asp645Asn/insGnt2243, was reported previously to cause classic infantile Pompe disease [Biochem Biophys Res Commun 244 (1998) 921]. We conclude that secondary genetic or environmental factors can be decisive for the phenotypic outcome of classic infantile versus childhood Pompe disease, when the acid alpha-glucosidase activity is extremely low.