Glycogen storage disease type IIIa: first report of a causative missense mutation (G1448R) of the glycogen debranching enzyme gene found in a homozygous patient.

Several different mutations in the glycogen-debranching enzyme gene AGL have been found in patients with glycogen storage disease type III (GSD III) to date, but no missense mutations have been reported for GSD III, only nonsense, splicing, and deletion/insertion lesions. Here we describe a novel G1448R missense mutation in a Japanese GSD IIIa patient from a consanguineous family. Sequence analysis of cDNA from the patient' liver specimen revealed two separate nucleotide changes: a G-to-A transition at nucleotide 3737 in exon 26 (3737G>A) and a G-to-C transversion at nucleotide 4742 in exon 33 (4742G>C), both of which result in substitution of glycine by arginine (G1115R and G1448R). Because homo-zygotes for G1115R were found in healthy controls, G1115R seems to be a polymorphism. Restriction fragment length polymorphism analysis with Bsa JI showed that the patient was homozygous for G1448R and that none of the normal controls had the mutation. This missense mutation is located at a putative glycogen-binding site that is indispensable for enzyme activity. Thus, G1448R is likely to be the causative mutation in this patient. This is the first report of a missense mutation associated with GSD III.

No evidence of accelerated atherosclerosis in a 66-yr-old chylomicronemia patient homozygous for the nonsense mutation (Tyr61-->stop) in the lipoprotein lipase gene.

Whether chylomicronemia is atherogenic or not has yet to be determined in humans. We investigated a 66-yr-old female with severe chylomicronemia resulting from a lipoprotein lipase (LPL) deficiency. The patient's plasma triglyceride level was approximately 2000 mg/dl. Both LPL activity and the mass of postheparin plasma in this patient were virtually absent. A nonsense mutation in exon 3 (Tyr61-->Stop) was identified in the patient's LPL gene, and a restriction fragment length polymorphism analysis established that the patient was homozygous for this mutation. The patient was neither a diabetic nor a smoker. Clinically, the patient had never experienced pancreatitis or angia pectoris. An examination of her carotid, femoral and coronary arteries by ultrasonogram and electrocardiogram after exercise-tolerance testing showed no accelerated atherosclerosis. This case suggests that atherosclerosis may not occur despite massive hyperlipidemia, when LPL bridging was not present due to the absence of LPL secretion and circulating mass.

Compound heterozygous patient with glycogen storage disease type III: identification of two novel AGL mutations, a donor splice site mutation of Chinese origin and a 1-bp deletion of Japanese origin.

Glycogen storage disease type III (GSD III) is an autosomal recessive disorder caused by deficiency of glycogen-debranching enzyme (AGL). We studied a 2-year-old GSD III patient whose parents were from different ethnic groups. Nucleotide sequence analysis of the patient showed two novel mutations: a single cytosine deletion at nucleotide 2399 (2399delC) in exon 16, and a G-to-A transition at the +5 position at the donor splice site of intron 33 (IVS33+5G>A). Analysis of the mRNA produced by IVS33+5G>A showed aberrant splicing: skipping of exon 33 and activation of a cryptic splice site in exon 34. Mutational analysis of the family revealed that the 2399delC was inherited from her father, who is of Japanese origin, and the IVS33+5G>A from her mother, who is of Chinese descent, establishing that the patient was a compound heterozygote. To our knowledge, this is the first report of a mutation identified in a GSD III patient from the Chinese population.

A novel point mutation in an acceptor splice site of intron 32 (IVS32 A-12-->G) but no exon 3 mutations in the glycogen debranching enzyme gene in a homozygous patient with glycogen storage disease type IIIb.

Genetic deficiency of the glycogen-debranching enzyme (debrancher) causes glycogen storage disease type III (GSD III), which is divided into two subtypes: IIIa and IIIb. In GSD IIIb, glycogen accumulates only in the liver, whereas both liver and muscles are involved in GSD IIIa. The molecular basis for the differences between the two subtypes has not been fully elucidated. Recently, mutations in exon 3 of the debrancher gene were reported to be specifically associated with GSD IIIb. However, we describe a homozygous GSD IIIb patient without mutations in exon 3. Analysis of the patient's debrancher cDNA revealed an 11-bp insertion in the normal sequence. An A to G transition at position -12 upstream of the 3' splice site of intron 32 (IVS 32 A-12-->G) was identified in the patient's debrancher gene. No mutations were found in exon 3. Mutational analysis of the family showed the patient to be homozygous for this novel mutation as well as three polymorphic markers. Furthermore, the mother was heterozygous and the parents were first cousins. The acceptor splice site mutation created a new 3' splice site and resulted in insertion of an 11-bp intron sequence between exon 32 and exon 33 in the patient's debrancher mRNA. The predicted mutant enzyme was truncated by 112 amino acids as a result of premature termination. These findings suggested that a novel IVS 32 A-12-->G mutation caused GSD IIIb in this patient.

Heterogeneous mutations in the glycogen-debranching enzyme gene are responsible for glycogen storage disease type IIIa in Japan.

Glycogen storage disease type IIIa (GSD IIIa) is an autosomal recessive disorder caused by deficiency of the glycogen-debranching enzyme (AGL). Recent studies of the AGL gene have revealed the prevalent mutations in North African Jewish and Caucasian populations, but whether these common mutations are present in other ethnic groups remains unclear. We have investigated eight Japanese GSD IIIa patients from seven families and identified seven mutations, including one splicing mutation (IVS 14+1G-->T) previously reported by us, together with six novel ones: a nonsense mutation (L124X), a splice site mutation (IVS29-1G-->C), a 1-bp deletion (587delC), a 2-bp deletion (4216-4217delAG), a 1-bp insertion (2072-2073insA), and a 3-bp insertion (4735-4736insTAT). The last mutation results in insertion of a tyrosine residue at a putative glycogen-binding site, and the rest are predicted to cause synthesis of truncated proteins lacking the glycogen-binding site at the carboxyl terminal. Thirteen novel polymorphisms have also been revealed in this study: three amino acid substitutions (R387Q, G1115R, and E1343 K), one silent point mutation (L298L), one nucleotide change in the 5'-noncoding region, and eight nucleotide changes in introns. Haplotype analysis with combinations of these polymorphic markers showed L124X, IVS14+1G-->T, and 4216-4217delAG to be on different haplotypes. These results demonstrate the importance of the integrity of the carboxy terminal domain in the AGL protein and the molecular heterogeneity of GSD IIIa in Japan.