WITHDRAWN: Novel missense mutation (Y24H) in the G6PT1 gene causing glycogen storage disease type 1b.

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Missense mutation Leu72Pro located on the carboxyl terminal amphipathic helix of apolipoprotein C-II causes familial chylomicronemia syndrome.

BACKGROUND: Chylomicronemia syndrome can be caused by 2 autosomal recessive disorders - lipoprotein lipase (LPL) deficiency and apolipoprotein C-II (apo C-II) deficiency. METHODS: We described 2 siblings with chylomicronemia syndrome of a consanguineous family. To determine the molecular basis of chylomicronemia syndrome in this family, we performed direct DNA sequencing of the LPL and APOC2 genes of the proband. RESULTS: A novel homozygous mutation, Leu72Pro, in the APOC2 gene was found in both siblings whereas their parents were carriers. No LPL mutations were detected in the siblings. Apo C-II contains 3 amphipathic alpha helices; the C-terminal alpha helix is composed of residues 64 to 74. Substitution of residue 72 from a helix former leucine to a helix breaker, proline, is predicted to change the secondary structure of the C-terminal helix and subsequently alter the interaction between apo C-II and LPL. CONCLUSIONS: To our knowledge, Leu72Pro is the first missense mutation identified in the C-terminal of apo C-II. The result is consistent with the current biochemical and structural findings that the C-terminal helix of apo C-II is important for activation of LPL.

Novel missense mutation (Y24H) in the G6PT1 gene causing glycogen storage disease type 1b.

We describe a Chinese patient with glycogen storage disease type 1b presenting with failure to thrive and protuberant abdomen. The neutropenia was mild and the patient did not have fasting hypoglycemia. Direct DNA sequencing of the G6PT1 gene revealed the patient to be a compound heterozygote of a novel missense mutation, Y24H, and another missense mutation, P191L, which we had described previously. The mother is heterozygous for the Y24H mutation and the father is heterozygous for the P191L mutation. Y24H and P191L may be ethnic-specific mutations as they have not been reported in other populations. The DNA-based diagnosis of GSD 1b will enable us to make an accurate determination of carrier status and to perform prenatal diagnosis of this disease.