Abstract
Eukaryotic class I ribonucleotide reductases (RRs) generate deoxyribonucleotides for DNA synthesis. Binding of dNTP effectors is coupled to the formation of active dimers and induces conformational changes in a short loop (loop 2) to regulate RR specificity among its nucleoside diphosphate substrates. Moreover, ATP and dATP bind at an additional allosteric site 40 Å away from loop 2 and thereby drive formation of activated or inactive hexamers, respectively. To better understand how dNTP binding influences specificity, activity, and oligomerization of human RR, we aligned >300 eukaryotic RR sequences to examine natural sequence variation in loop 2. We found that most amino acids in eukaryotic loop 2 were nearly invariant in this sample; however, two positions co-varied as nonconservative substitutions (N291G and P294K; human numbering). We also found that the individual N291G and P294K substitutions in human RR additively affect substrate specificity. The P294K substitution significantly impaired effector-induced oligomerization required for enzyme activity, and oligomerization was rescued in the N291G/P294K enzyme. None of the other mutants exhibited altered ATP-mediated hexamerization; however, certain combinations of loop 2 mutations and dNTP effectors perturbed ATP's role as an allosteric activator. Our results demonstrate that the observed compensatory covariation of amino acids in eukaryotic loop 2 is essential for its role in dNTP-induced dimerization. In contrast, defects in substrate specificity are not rescued in the double mutant, implying that functional sequence variation elsewhere in the protein is necessary. These findings yield insight into loop 2's roles in regulating RR specificity, allostery, and oligomerization.
Highlights
This work was supported, in whole or in part, by National Institutes of Health Grants R01 GM096000 and T32 GM008056
Structural models of ribonucleotide reductases (RRs) bound to different substrate/effector pairs show that binding of a dNTP effector in the specificity site (S-site) directs C-site specificity by changing the conformation of loop 2
In contrast to the results in the presence of 1 mM ATP alone (Fig. 5E), results from the present set of experiments were best explained by a mechanism in which long-range communication between the activity site (A-site) and the active site was disrupted by mutations in loop 2
Summary
Activity is, essential both to our basic understanding of RR function and to development of further therapeutics. Structural models of RRs bound to different substrate/effector pairs show that binding of a dNTP effector in the S-site directs C-site specificity by changing the conformation of loop 2. Conserved residues in loop 2 are clearly important for function, but additional information is needed to further our understanding of how conserved and variable residues in loop 2 work together to transmit allosteric information between the S-site and C-site To further this goal, we systematically investigated patterns of phylogenetic sequence variation in eukaryotic RR enzymes and used this information to guide structure-function studies of loop 2 function in vitro. A sequence alignment of 310 R1 subunits from Eukarya reveals two amino acids in loop 2 that consistently covary (N291G and P294K, human numbering) Individual mutations at these positions in hRR affect NDP discrimination, consistent with the canonical role of loop 2 in directing substrate specificity. The results reveal that these positions are essential for dNTP-induced RR dimerization and suggest a surprising new role for loop 2 in mediating the long-range effects of ATP on activity
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