RESUMO
gamma-Glultamylcysteine synthetase (gamma-GCS) catalyzes the first step in the de novo biosynthesis of glutathione. In trypanosomes, glutathione is conjugated to spermidine to form a unique cofactor termed trypanothione, an essential cofactor for the maintenance of redox balance in the cell. Using extensive similarity searches and sequence motif analysis we detected homology between gamma-GCS and glutamine synthetase (GS), allowing these proteins to be unified into a superfamily of carboxylate-amine/ammonia ligases. The structure of gamma-GCS, which was previously poorly understood, was modeled using the known structure of GS. Two metal-binding sites, each ligated by three conserved active site residues (n1: Glu-55, Glu-93, Glu-100; and n2: Glu-53, Gln-321, and Glu-489), are predicted to form the catalytic center of the active site, where the n1 site is expected to bind free metal and the n2 site to interact with MgATP. To elucidate the roles of the metals and their ligands in catalysis, these six residues were mutated to alanine in the Trypanosoma brucei enzyme. All mutations caused a substantial loss of activity. Most notably, E93A was able to catalyze the l-Glu-dependent ATP hydrolysis but not the peptide bond ligation, suggesting that the n1 metal plays an important role in positioning l-Glu for the reaction chemistry. The apparent K(m) values for ATP were increased for both the E489A and Q321A mutant enzymes, consistent with a role for the n2 metal in ATP binding and phosphoryl transfer. Furthermore, the apparent K(d) values for activation of E489A and Q321A by free Mg(2+) increased. Finally, substitution of Mn(2+) for Mg(2+) in the reaction rescued the catalytic deficits caused by both mutations, demonstrating that the nature of the metal ligands plays an important role in metal specificity.
Assuntos
Glutamato-Cisteína Ligase/química , Magnésio/farmacologia , Manganês/farmacologia , Sequência de Aminoácidos , Sítios de Ligação , Glutamato-Amônia Ligase/química , Cinética , Dados de Sequência MolecularRESUMO
Ornithine decarboxylase (ODC) is a pyridoxal-5'-phosphate-dependent (PLP) enzyme that catalyzes the biosynthesis of the polyamine putrescine. Similar to other PLP-dependent enzymes, an active site Lys residue forms a Schiff base with PLP in the absence of substrate. The mechanistic role of this residue (Lys-69) in catalysis by Trypanosoma brucei ODC has been studied by analysis of the mutant enzymes, in which Lys-69 has been replaced by Arg (K69R ODC) and Ala (K69A ODC). Analysis of K69A ODC demonstrated that the enzyme copurified with amines (e.g. putrescine) that were tightly bound to the active site through a Schiff base with PLP. In contrast, on the basis of an absorption spectrum of K69R ODC, PLP is likely to be bound to this mutant enzyme in the aldehyde form. Pre-steady-state kinetic analysis of the reaction of K69R ODC with L-Orn and putrescine demonstrated that the rates of both the product release (k(off.Put) = 0.0041 s(-)(1)) and the decarboxylation (k(decarb) = 0.016 s(-)(1)) steps were decreased by10(4)-fold in comparison to wild-type ODC. Further, the rates of Schiff base formation between K69R ODC and either substrate or product have decreased by at least 10(3)-fold. Product release remains as the dominant rate-limiting step in the reaction (the steady-state parameters for K69R ODC are k(cat) = 0.0031 s(-)(1) and K(m) = 0.18 mM). The effect of mutating Lys-69 on the decarboxylation step suggests that Lys-69 may play a role in the proper positioning of the alpha-carboxylate for efficient decarboxylation. K69R ODC binds diamines and amino acids with higher affinity than the wild-type enzyme; however, Lys-69 does not mediate substrate specificity. Wild-type and K69R ODC have similar ligand specificity preferring to bind putrescine over longer and shorter diamines. Kinetic analysis of the binding of a series of diamines and amino acids to K69R ODC suggests that noncovalent interactions in the active site of K69R ODC promote selective ligand binding during Schiff base formation.