Functional Recovery of a GCDH Variant Associated to Severe Deflavinylation-Molecular Insights into Potential Beneficial Effects of Riboflavin Supplementation in Glutaric Aciduria-Type I Patients.

Riboflavin is the biological precursor of two important flavin cofactors-flavin adenine dinucleotide (FAD) and flavin mononucleotide (FMN)-that are critical prosthetic groups in several redox enzymes. While dietary supplementation with riboflavin is a recognized support therapy in several inborn errors of metabolism, it has yet unproven benefits in several other pathologies affecting flavoproteins. This is the case for glutaric aciduria type I (GA-I), a rare neurometabolic disorder associated with mutations in the GCDH gene, which encodes for glutaryl-coenzyme A (CoA) dehydrogenase (GCDH). Although there are a few reported clinical cases that have responded to riboflavin intake, there is still not enough molecular evidence supporting therapeutic recommendation. Hence, it is necessary to elucidate the molecular basis in favor of riboflavin supplementation in GA-I patients. Here, using a combination of biochemical and biophysical methodologies, we investigate the clinical variant GCDH-p.Val400Met as a model for a phenotype associated with severe deflavinylation. Through a systematic analysis, we establish that recombinant human GCDH-p.Val400Met is expressed in a nonfunctional apo form, which is mainly monomeric rather than tetrameric. However, we show that exogenous FAD is a driver for structural reorganization of the mutant enzyme with concomitant functional recovery, improved thermolability, and resistance to trypsin digestion. Overall, these results establish proof of principle for the beneficial effects of riboflavin supplementation in GA-I patients.

Potential complementation effects of two disease-associated mutations in tetrameric glutaryl-CoA dehydrogenase is due to inter subunit stability-activity counterbalance.

Glutaric Aciduria Type I (GA-I), is an autosomal recessive neurometabolic disease caused by mutations in the GCDH gene that encodes for glutaryl-CoA dehydrogenase (GCDH), a flavoprotein involved in the metabolism of tryptophan, lysine and hydroxylysine. Although over 200 disease mutations have been reported a clear correlation between genotype and phenotype has been difficult to establish. To contribute to a better molecular understanding of GA-I we undertook a detailed molecular study on two GCDH disease-related variants, GCDH-p.Arg227Pro and GCDH-p.Val400Met. Heterozygous patients harbouring these two mutations have increased residual enzymatic activity in relation to homozygous patients with only one of the mutations, suggesting a complementation effect between the two. Combining biochemical, biophysical and structural methods we here establish the effects of these mutations on protein folding, stability and catalytic activity. We show that both variants retain the overall protein fold, but with compromised enzymatic activities. Detailed enzyme kinetic studies reveal that GCDH-p.Arg227Pro has impaired function due to deficient substrate affinity as evidenced by its higher Km, and that the lower activity in GCDH-p.Val400Met results from weaker interactions with its physiological redox partner (electron transfer flavoprotein). Moreover, the GCDH-p.Val400Met variant has a significantly lower thermal stability (ΔTm ≈ 9 °C), and impaired binding of the FAD cofactor in relation to wild-type protein. On these grounds, we provide a rational for the possible interallelic complementation observed in heterozygous patients based on the fact that in GCDH, the low active p.Arg227Pro variant contributes to stabilize the tetramer while the structurally unstable p.Val400Met variant compensates for enzyme activity.