Abstract
Aerobic ribonucleotide reductase from Escherichia coli regulates its level of activity by binding of effectors to an allosteric site in R1, located to the proposed interaction area of the two proteins that comprise the class I enzyme. Activity is increased by ATP binding and decreased by dATP binding. To study the mechanism governing this regulation, we have constructed three R1 proteins with mutations at His-59 in the activity site and one R1 protein with a mutation at His-88 close to the activity site and compared their allosteric behavior to that of the wild type R1 protein. All mutant proteins retained about 70% of wild type enzymatic activity. We found that if residue His-59 was replaced with alanine or asparagine, the enzyme lost its normal response to the inhibitory effect of dATP, whereas the enzyme with a glutamine still managed to elicit a normal response. We saw a similar result if residue His-88, which is proposed to hydrogen-bond to His-59, was replaced with alanine. Nucleotide binding experiments ruled out the possibility that the effect is due to an inability of the mutant proteins to bind effector since little difference in binding constants was observed for wild type and mutant proteins. Instead, the interaction between proteins R1 and R2 was perturbed in the mutant proteins. We propose that His-59 is important in the allosteric effect triggered by dATP binding, that the conserved hydrogen bond between His-59 and His-88 is important for the communication of the allosteric effect, and that this effect is exerted on the R1/R2 interaction.
Highlights
A key enzyme of nucleic acid metabolism in the cell is ribonucleotide reductase
We investigated the responses of the wild type and the mutant proteins toward the allosteric effectors dATP (Fig. 2) and ATP
As described in the introduction, dATP acts as a positive effector at low concentrations when it binds to the specificity site and as an inhibitor upon binding to the overall activity site
Summary
Bacterial Strains—E. coli CJ236 dutϪ, ungϪ, thi-, relA1/pCJ105, and MV1190 ⌬(lac-proAB), thi, supE, ⌬(srl-recA)306::Tn10, both obtained from Bio-Rad, were used for mutagenesis. Expression of Mutant Protein—The MC1009/pGP1-2 strain containing any of pTB1-H59A, -H59D, -H59N, -H59Q, or -H88A was grown for several hours at 30 °C in 10 ml of LB supplemented with carbenicillin and kanamycin at a concentration of 50 g/ml of each. Assay of Enzymatic Activity—Assays of enzymatic activity of mutant and wild type protein were performed and analyzed as described for the 3H-CDP assay [16]. Assay of Effector Concentration on Enzymatic Activity—The effects of the allosteric effectors ATP, dATP, and dTTP on the activity of the R1 proteins were measured individually. From a direct plot of activity versus concentration of effector, the KL values for binding of effectors were calculated in KaleidaGraph using the following equations: binding of dTTP and ATP to one allosteric site, v ϭvmax ϫ [dNTP]/(KL ϩ [dNTP]) and binding of dATP to the two independent sites,. The KD (i.e. Km of R2) of the complex was calculated [18] from a plot of enzyme activity versus total concentration of R2
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