Genetic and other influences on red-cell flavin enzymes, pyridoxine phosphate oxidase and glutathione reductase in families with beta-thalassaemia.

In 18 beta-thalassaemia families from the Ferrara area the incidence of an inherited low flavin mononucleotide (FMN)-dependent pyridoxine phosphate (PNP) oxidase activity, a sensitive indicator of red-cell FMN deficiency, is higher in related members in these families than in the unrelated spouses and controls subjects without family history of thalassaemia. This suggests slower red-cell riboflavin metabolism in thalassaemia families, which may have resulted from selection in combination with thalassaemia by malaria. However, there was a markedly higher incidence of red-cell flavin adenine dinucleotide (FAD) deficiency in thalassaemia heterozygotes than in their normal relatives. This was indicated by higher stimulation of FAD-dependent glutathione reductase (GR) activity by FAD and lower GR activity per red cell, and suggests a marked additive effect by thalassaemia on the red cell FAD deficiency that results from the inherited slow riboflavin metabolism. There is evidence that diversion of FAD to other FAD-dependent enzymes might be an important factor.

Glutathione reductase activity and its relationship to pyridoxine phosphate activity in G6PD deficiency.

Per cent stimulation of GR activity by FAD in vitro and PNP oxidase activity were measured in G6PD deficiency, heterozygous beta-thalassaemia and controls. It is confirmed that, in contrast to the high stimulation of GR by FAD commonly found in in thalassaemia indicating red-cell deficiency of FAD, and shown here to be greater in the Italian subjects, GR is usually saturated with FAD in G6PD deficiency, leading to high in vitro activity. Unexpectedly, on the other hand, low FMN-dependent PNP oxidase activity due to red-cell deficiency of FMN, confirmed by response to oral riboflavin, was found in the majority of subjects with G6PD deficiency, similar to that found in heterozygous beta-thalassaemia. Whereas this is explained in thalassaemia by an inherited slow red-cell metabolism of riboflavin to FMN, it is suggested that in G6PD deficiency an increased rate of red-cell metabolism of FMN to FAD leads to the low FMN and high FAD. When G6PD deficiency occurs with heterozygous beta-thalassaemia, GR is usually saturated with FAD as in G6PD deficiency alone, unless there is an inherited, very slow red-cell metabolism of riboflavin to FMN. The part played by GR in haemolytic crises in G6PD deficiency is discussed.