Age-related changes of glucose-6-phosphate dehydrogenase activity in mouse oocytes

Summary Glucose-6-phosphate dehydrogenase (G6PDH) activity was measured in follicular oocytes and in ovulated eggs of prepubertal, adult and aged mice. G6PDH activity in ovulated eggs was 60% of the activity in follicular oocytes in all age groups. The mean G6PDH activity was significantly higher in follicular oocytes of adult mice than in oocytes of both prepubertal and aged mice. In aged mice, the decreased mean activity in follicular oocytes as well as in ovulated eggs was mainly due to a high percentage of cells with extremely low activity (25 and 18%, respectively). The percentage of preovulatory oocytes with low activity in prepubertal mice was 9% and in adult mice 0.3%. For ovulated eggs these percentages were 0% for both prepubertal and adult mice. In every age group, all ovulated eggs showed a normal morphology. When ovulated eggs with extremely low G6PDH activity can still be fertilized, it can be questioned whether this loss of activity could cause disturbances in development of (preimplantation) embryos. Our findings emphasize the potentialities of investigating intact single oocytes for changes in enzyme activities, which could be applied as parameters for quality control of these cells.     

Insulin secretion in patients deficient in glucose-6-phosphate dehydrogenase

Intravenous (IVGTT) and oral glucose tolerance tests (OGTT) were carried out in 12 men with glucose-6-phosphate dehydrogenase (G-6-PD) deficiency and in 11 normal men. The race, the mean age and body mass index were similar in the G-6-PD deficient and in the normal men. No significant differences were demonstrated between mean plasma glucose levels in the G-6-PD deficient subjects and those in the normal men during IVGTT and OGTT. In contrast the insulin levels were significantly lower for the G-6-PD deficient subjects as compared to the controls at 30 minutes (P less than 0.04) in the OGTT and at 1 min (P less than 0.001), 3 min (P less than 0.001), 5 min (P less than 0.001) and 10 minutes (P less than 0.002) in the IVGTT. All indexes of first phase insulin release were also significantly (P less than 0.001) lower in G-6-PD deficient men. These results emphasize the metabolic importance of G-6-PD in the process of glucose induced insulin release.     

Isoenzymes of glucose-6-phosphate dehydrogenase from tobacco cells

Two anodic isoenzymes of glucose-6-phosphate dehydrogenase (G6PDH) were isolated from tobacco suspension culture WR-132, utilizing fractional ammonium sulfate precipitation and DEAE-cellulose chromatography. The pH optimum was 9.0 for isoenzyme G6PDH I and 8.0–8.3 for G6PDH IV. Isoenzyme G6PDH I exhibited Michaelis-Menten kinetics for both substrates, G6P and NADP⁺, with K_m's of 0.22 mM and 0.06 mM, respectively. G6PDH IV exhibited Michaelis-Menten kinetics for G6P with a K_m of 0.31 mM. The NADP⁺ double reciprocal plot showed an abrupt transition between two linear sections. This transition corresponds to an abrupt increase in the apparent K_m and V_max values with increasing NADP⁺, denoting negative cooperativity. The two K_m's for high and low NADP⁺ concentrations were 0.06 mM and 0.015 mM, respectively. MWs of the isoenzymes as determined by SDS disc gel electrophoresis were 85 000–91 000 for G6PDH I and 54 000–59 000 for G6PDH IV. Gel filtration chromatography on Sephadex G-150 showed MW's of 91 000 for G6PDH I and 115 000 for G6PDH IV. A probable dimeric structure for IV is suggested, with two NADP⁺ binding sites.     

Purification,characterization and kinetic mechanism of glucose-6-phosphate dehydrogenase from mouse liver

• 1.1. Glucose-6-phosphate dehydrogenase (G6PDH EC 1.1.1.49) from mouse liver has been purified 1100-fold by extraction, ion-exchange chromatography on DE-52, absorption chromatography on Bio-Gel HTP and gel filtration through sepharose 6 HR 10/30. The purified enzyme showed a single band in silver stained SDS-PAGE.
• 2.2. The native and subunit molecular weight were 117 and 31 kDa respectively.
• 3.3. The kinetic studies and the patterns obtained from the inhibition by-products suggest that the enzyme follows an ordered sequential kinetic mechanism.
• 4.4. The reduced K_m values for the substrates favour the operativity of the enzyme. The “fine control” of the enzymatic activity was exerted by the NADPH, whose K_i is several fold lower than the in vivo concentration.

     

Characterization of glucose-6-phosphate dehydrogenase in Thailand

Summary Characterization of partially purified eryrhrocyte G-6-PD from 50 enzymedeficient males in 45 unrelated Thai families revealed 6 enzyme variants. Thirty-five subjects in 31 families had G-6-PD variant with normal electrophoretic mobility, slightly low Km G-6-P, normal substrate-analog utilization, normal pH-optimum curve, and slightly increased heat stability. This enzyme variant is called G-6-PD Mahidol.Six subjects had enzyme with fast electrophoretic mobility (106–108% of normal), low Km G-6-P, slightly increased substrate-analog utilization, biphasic pH-optimum curve, and slightly low to normal heat stability. This variant was identical to G-6-PD Canton.Five subjects had G-6-PD with fast electrophoretic mobility (103–106% of normal), low Km G-6-P, very high substrate-analog utilization except for DPN which it did not use as cofactor, markedly biphasic pH-optimum curve and very low heat stability. This variant is called G-6-PD Union (Thai).Two brothers had G-6-PD with normal electrophoretic mobility, low Km G-6-P, slightly increased substrate-analog utilization, biphasic pH-optimum curve and low heat stability. This variant is designated G-6-PD Siriraj.G-6-PD from one patient had slightly fast electrophoretic mobility, increased substrateanalog utilization, especially of DPN, and very low thermal stability. It is called G-6-PD Kan.One subject had G-6-PD with normal electrophoretic mobility, Km G-6-P, pH-optimum curve and heat stability, and increased substrate-analog utilization. This G-6-PD variant is named G-6-PD Anant.G-6-PD Mahidol is far more common than any other known variants in Thailand.

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Zusammenfassung Eine Charakterisierung von teilweise gereinigtem Erythrocyten-G-6-PD von 50 Männern mit Enzym-Defekt aus 45 nicht miteinander verwandten Thai-Familien ergab 6 Enzym-Varianten. 35 Personen in 31 Familien hatten eine G-6-PD-Variante mit normaler elektrophoretischer Wanderungsgeschwindigkeit, einen leicht verminderten G-6-P-Km-Wert, einer normalen Substratanalog-Verwertung, einer normalen pH-Optimum-Kurve und einer leicht erhöhten Hitze-Stabilität. Diese Enzym-Variante wurde G-6-PD Mahidol genannt.Sechs Personen hatten ein Enzym mit rascher elektrophoretischer Wanderung (106–108% der Norm), niedrigem Km für G-6-P, leicht erhöhter Substrat-Verwertung, einer biphasischen pH-Optimum-Kurve und normaler bis leicht erniedrigter Hitzestabilität. Diese Variante ist identisch mit G-6-PD Canton.Fünt Personen hatten G-6-PD mit rascher elektrophoretischer Wanderung (103–106%), niedrigem Km G-6-P, sehr hoher Substratanalog-Verwertung—mit Ausnahme von DPN, das nicht als Cofactor wirkte—, einer stark biphasischen pH-Optimum-Kurve und sehr geringer Hitze-Stabilität. Diese Variante wurde als G-6-PD Union (Thai) bezeichnet.Zwei Brüder hatten ein G-6-PD mit normaler elektrophoretischer Wanderung, niedrigem Km G-6-P, leicht erhöhter Substratanalog-Verwertung, einer biphasischen pH-Optimum-Kurve und geringer Hitze-Stabilität. Diese Variante erhielt den Namen G-6-PD Siriraj.G-6-PD eines Patienten hatte eine leicht erhöhte elektrophoretische Wanderungsgeschwindigkeit, eine erhöhte Substratanalog-Verwertung, besonders für DPN, und eine sehr geringe Hitze-Stabilität (G-6-PD Kan).Eine Person zeigte ein G-6-PD mit normaler elektrophoretischer Wanderungsgeschwindigkeit, Km G-6-P pH-Optimum-Kurve und Hitze-Stabilität. Nur die Substratanalog-Verwertung war erhöht. Diese Variante wurde G-6-PD Anant gennant.G-6-PD Mahidol ist die bei weitem häufigste Variante in Thailand.

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This investigation received financial support from the World Health Organization.     

Specific activities of 6-phosphogluconate dehydrogenase,glucose-6-phosphate dehydrogenase and glucose-6-phosphate isomerase during Bufo bufo development

It has been suggested by some authors that during amphibian development, due to the higher glucose-6-phosphate dehydrogenase (EC 1.1.1.49) activity compared to that of 6-phosphogluconate dehydrogenase (EC 1.1.1.43), 6-phosphogluconate could accumulate in the embryo tissues and regulate the channelling of glucose-6-phosphate into glycolysis. Here, on the base of the specific activities of glucose-6-phosphate dehydrogenase, 6-phosphogluconate dehydrogenase and glucose-6-phosphate isomerase (EC 5.3.1.9) found in the embryos of Bufo bufo during development, it is discussed whether 6-phosphogluconate can accumulate and play a regulative role on glucose-6-phosphate metabolism in the anuran embryo.     

Characterization of glucose-6-phosphate dehydrogenase and 6-phosphogluconic acid dehydrogenase from hazel cotyledons

NADP reduction was shown to occur in a crude cytosolic extract from the cotyledonary material of hazel seed prior to the addition of erogenous dehydrogenase substrate. This activity interfered with the assay of glucose-6-phosphate dehydrogenase and 6-phosphogluconic acid dehydrogenase activities. The inherent NADP reduction was removed by ammonium sulphate fractionation. Subsequent de-salting of the resulting partially-purified fraction permitted assay of G6PDH and 6PGDH. Both enzymes were shown to be NADP specific. Typical Michaelis-Menten kinetics were shown for each enzyme, towards NADP and their respective substrate.     

Rapid purification of glucose-6-phosphate dehydrogenase from mammal's erythrocytes

A procedure for rapid purification to homogeneity of glucose-6-phosphate dehydrogenase (G6PD) is herein presented. Our method is not new, but represents a simplification of the method of De Flora et al. (Arch. Biochem. Biophys. 169, 362-3, 1975) which consisted of three steps: DEAE-Sephadex, phosphocellulose (P11) and affinity chromatography on 2'5' ADP-Sepharose. These authors eluted the enzyme from the P11 with phosphate and from 2'5' ADP-Sepharose with KC1 and NADP. By our method, the DEAE-Sephadex step is omitted, the G6PD is eluted from P11 with citrate and NADP, and from 2'5' ADP-Sepharose with KC1, NADP and EDTA. The elution of the enzyme from the phosphocellulose was studied in detail and the temperature effect has been described. We report here an application of this method to a rapid microscale purification starting from 3.5-4 ml of rabbit blood, which can be performed in about 8 hours and a macroscale purification starting from 180-200 ml of human blood, which takes a day and a half.