Three Missense Mutations in the Protein C Heavy Chain Causing Type I and Type II Protein C Deficiency

 

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Summary

We have studied the molecular basis of protein C deficiency in three families with a history of thromboembolic disease. An approximately 50% reduction in both functional and immunologic levels of protein C was detected in the plasma from two unrelated patients, designated protein C Osaka 1 and protein C Osaka 2. An approximately 50% reduction in functional level but normal immunologic level of protein C was detected in plasma from a third patient, designated protein C Osaka 3. DNA sequencing of the amplified DNA revealed one missense mutation in each case. Additional mutations in the coding sequence were excluded by DNA sequencing of all protein C exons. We identified a C-to-T change at nucleotide number 6,218 of the protein C gene in protein C Osaka 1. This results in the amino acid substitution of Arg-169 by Trp at the a-thrombin cleavage site. In protein C Osaka 2, a G-to-A change at nucleotide number 8,807 was identified leading to the amino acid substitution of Met-364 by lie in the protease domain. This substitution may impair the synthesis or stability of protein C Osaka 2. In protein C Osaka 3, a G-to-C change at nucleotide number 8,868 was identified. This results in substitution of Gly-385 by Arg in the protease domain. Based on these, it was concluded that Arg-169-to-Trp mutation and Met-364-to-Ile mutation cause type I protein C deficiency and Gly-385-to-Arg mutation causes type II deficiency.

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