Electron transfer in nitrogenase involves a gating process initiated by MgATP (magnesium adenosine triphosphate) binding to Fe-protein. The redox site, an 4Fe:4S cluster, is structurally separated from the MgATP binding site. For MgATP hydrolysis to be coupled to electron transfer, a signal transduction mechanism is proposed that is similar to that in guanosine triphosphatase proteins. Based on the three-dimensional structure of Fe-protein, Asp125 is likely to be part of a putative transduction path. Altered Fe-protein with Glu replacing Asp has been prepared and retains the ability for the initial nucleotide-dependent conformational change. However, either MgADP or MgATP can induce the shift and Mg binding to the nucleotide is no longer essential.
De novo purine nucleotide synthesis is regulated, at least in part, by end-product inhibition of glutamine PRPP amidotransferase. An important feature of this inhibition is the fact that certain synergistic nucleotide pairs give more than additive inhibition. The physiological importance of synergism is in amplifying regulation by the adenine and guanine nucleotide end products of de novo synthesis. Using a new method to quantitate synergism, ADP plus GMP were confirmed [Meyer, E., and Switzer, R. L. (1978) J. Biol. Chem. 254, 5397-5402] to give strong synergistic inhibition of Bacillus subtilis glutamine PRPP amidotransferase. An X-ray structure of the ternary enzyme.ADP.GMP complex established that ADP binds to the allosteric A site and GMP to the catalytic C site. GMP increased the binding affinity of ADP for the A site by approximately 20-fold. Synergism results from a specific nucleotide-nucleotide interaction that is dependent upon a nucleoside diphosphate in the A site and a nucleoside monophosphate in the C site. Furthermore, synergism is enhanced by the competition between nucleotide inhibitor and PRPP substrate for the C site. Purine base specificity results from a backbone carbonyl interaction of Lys305' with the 6-NH2 group of adenine in the A site and a Ser347 Ogamma interaction with the 2-NH2 group of guanine in the C site. Steric considerations favor binding of the nucleoside diphosphate to the A site. Site-directed replacements of key residues increased the nucleotide concentrations needed for 50% inhibition and in some cases perturbed synergism. Mutations in either of the nucleotide sites perturbed function at both sites, supporting the important role of synergism.
Glutamine phosphoribosylpyrophosphate (PRPP) amidotransferase catalysis and regulation were studied using a new stable carbocyclic analog of PRPP, 1-alpha-pyrophosphoryl-2-alpha, 3-alpha-dihydroxy-4-beta-cyclopentane-methanol-5-phosphate (cPRPP). Although cPRPP competes with PRPP for binding to the catalytic C site of the Escherichia coli enzyme, two lines of evidence demonstrate that cPRPP, unlike PRPP, does not promote an active enzyme conformation. First, cPRPP was not able to "activate" Cys1 for reaction with glutamine or a glutamine affinity analog. The ring oxygen of PRPP may thus be necessary for the conformation change that activates Cys1 for catalysis. Second, binding of cPRPP to the C site blocks binding of AMP and GMP, nucleotide end product inhibitors, to this site. However, the binding of nucleotide to the allosteric site was essentially unaffected by cPRPP in the C site. Since it is expected that nucleotide inhibitors would bind with low affinity to the active enzyme conformation, the nucleotide binding data support the conclusion that cPRPP does not activate the enzyme.
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