This work describes major features and specificities of glutathione (GSH) biosynthesis in the cold-adapted Pseudoalteromonas haloplanktis. Two steps of ATP hydrolysis, catalysed by gamma-glutamyl-cysteine ligase (PhGshA) and glutathione synthetase (PhGshB), drive GSH formation; however, differently from other sources, this psychrophile contains two redundant PhGshAs. The biochemical properties of recombinant rPhGshB and rPhGshA II were previously reported; here we report the characterization of rPhGshA I, together with a structural comparison with rPhGshA II. The availability of the three enzymes involved in GSH biosynthesis allowed the reconstitution of two systems producing this thiol in P. haloplanktis. Both systems were active, although with different reaction rates; in particular, rPhGshB worked more efficiently with rPhGshA I compared to rPhGshA II, also because of the different expression of the corresponding genes. However, the lower K-M of rPhGshA II for cysteine compared to rPhGshA I could permit an effective GSH production even under conditions of low cysteine content. Coupling of the kinetics of GSH production with that of ATP hydrolysis was realised for the first time and proved the rigorous stoichiometry of GSH biosynthesis, resulting in two moles of ATP hydrolysed per one mole of GSH formed. Furthermore, after dissecting the reaction rates for GSH biosynthesis, we demonstrated that synthesis of this thiol was rate-limited by the step catalysed by rPhGshB, at least in the cold-adapted source. Therefore, the GshA rate-limited step postulated in other sources could be revised or restricted to conditions of limiting substrate amounts.
The cold way for glutathione biosynthesis in the psychrophile Pseudoalteromonas haloplanktis. Redundancy and reaction rates
Rullo Rosario;
2016
Abstract
This work describes major features and specificities of glutathione (GSH) biosynthesis in the cold-adapted Pseudoalteromonas haloplanktis. Two steps of ATP hydrolysis, catalysed by gamma-glutamyl-cysteine ligase (PhGshA) and glutathione synthetase (PhGshB), drive GSH formation; however, differently from other sources, this psychrophile contains two redundant PhGshAs. The biochemical properties of recombinant rPhGshB and rPhGshA II were previously reported; here we report the characterization of rPhGshA I, together with a structural comparison with rPhGshA II. The availability of the three enzymes involved in GSH biosynthesis allowed the reconstitution of two systems producing this thiol in P. haloplanktis. Both systems were active, although with different reaction rates; in particular, rPhGshB worked more efficiently with rPhGshA I compared to rPhGshA II, also because of the different expression of the corresponding genes. However, the lower K-M of rPhGshA II for cysteine compared to rPhGshA I could permit an effective GSH production even under conditions of low cysteine content. Coupling of the kinetics of GSH production with that of ATP hydrolysis was realised for the first time and proved the rigorous stoichiometry of GSH biosynthesis, resulting in two moles of ATP hydrolysed per one mole of GSH formed. Furthermore, after dissecting the reaction rates for GSH biosynthesis, we demonstrated that synthesis of this thiol was rate-limited by the step catalysed by rPhGshB, at least in the cold-adapted source. Therefore, the GshA rate-limited step postulated in other sources could be revised or restricted to conditions of limiting substrate amounts.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.