Genetic Profiles of Korean Patients With Glucose-6-Phosphate Dehydrogenase Deficiency

BACKGROUND: We describe the genetic profiles of Korean patients with glucose-6-phosphate dehydrogenase (G6PD) deficiencies and the effects of G6PD mutations on protein stability and enzyme activity on the basis of in silico analysis. METHODS: In parallel with a genetic analysis, the pathogenicity of G6PD mutations detected in Korean patients was predicted in silico. The simulated effects of G6PD mutations were compared to the WHO classes based on G6PD enzyme activity. Four previously reported mutations and three newly diagnosed patients with missense mutations were estimated. RESULTS: One novel mutation (p.Cys385Gly, labeled G6PD Kangnam) and two known mutations [p.Ile220Met (G6PD São Paulo) and p.Glu416Lys (G6PD Tokyo)] were identified in this study. G6PD mutations identified in Koreans were also found in Brazil (G6PD São Paulo), Poland (G6PD Seoul), United States of America (G6PD Riley), Mexico (G6PD Guadalajara), and Japan (G6PD Tokyo). Several mutations occurred at the same nucleotide, but resulted in different amino acid residue changes in different ethnic populations (p.Ile380 variant, G6PD Calvo Mackenna; p.Cys385 variants, Tomah, Madrid, Lynwood; p.Arg387 variant, Beverly Hills; p.Pro396 variant, Bari; and p.Pro396Ala in India). On the basis of the in silico analysis, Class I or II mutations were predicted to be highly deleterious, and the effects of one Class IV mutation were equivocal. CONCLUSIONS: The genetic profiles of Korean individuals with G6PD mutations indicated that the same mutations may have arisen by independent mutational events, and were not derived from shared ancestral mutations. The in silico analysis provided insight into the role of G6PD mutations in enzyme function and stability.

Enzyme kinetics and molecular modeling studies of G6PDMahidol associated with acute hemolytic anemia.

G6PDMahidol enzyme is the most common variant in the Achang Chinese ethnic group and clinically manifests as class II. In this study, G6PDMahidol enzyme was characterized by molecular modeling to understand its kinetics. G6PDMahidol, G6PDG487A and G6PDWT proteins were heterologously expressed in the G6PD-deficient DF213 E. coli strain, purified and their steady-state kinetic parameters were determined. Compared with G6PDWT, the Km and Vmax of NADP+ with G6PDG487A were about 28-fold and 12-fold lower, respectively. The Ki values of dehydroepiandrosterone (DHEA), NADPH and ATP with G6PDG487A showed 29.5-fold, 2.36-fold reduction and 1.83-fold increase, respectively. A molecular modeling of G6PDG487A was performed based on the X-ray structure of human G6PD (PDB: 2BH9). It is suggested that Ser-163 might affect the stability of G6PDG487A -helix d and -strand E, besides the conformation of -strand D. In conclusion, the biochemical and structural properties of G6PDG487A and G6PDWT enzymes are significantly different, which may be responsible for clinical diversity of G6PD deficiencies.

effect of aluminum on human erythrocyte glucose 6-phosphate dehydrogenase

Glucose 6-phosphate dehydrogenase [G6PD], the first enzyme in initiating the pentose phosphate shunt, is an important component in generation of NADPH. Although innumerable studies have been performed on human erythrocyte G6PD, however, the effect of trace elements on the enzyme activity requires further investigations. To study the effect of aluminum on human erythrocyte G6PD. In this experimental research, following the purification of G6PD using chromatographic methods, the effect of different concentrations of Al[3+] [up to 100 micro-molar] on G6PD activity was studied. The enzyme activity was measured at different concentrations of glucose 6-phosphate and NADP[+] to determine the type of inhibitory action. Aluminum at the concentration of 100 microM showed a considerable inhibitory effect on G6PD activity [60%]. The type of inhibitory action, depending on the use of glucose-6-phosphate or NADP[+], was competitive and noncompetitive, respectively. Aluminum exerts an inhibitory action on human erythrocyte G6PD activity