Characterization of two novel single-stranded DNA-specific autonomously replicating sequence-binding proteins from Saccharomyces cerevisiae, one of which is adenylosuccinate synthetase

Adenylosuccinate synthetase genes: molecular cloning and phylogenetic analysis of a highly conserved archaeal gene

Adenylosuccinate synthetase (PurA) catalyzes the first step in the de novo AMP synthesis and has been extensively studied in both Bacteria and Eukarya. We cloned the purA gene from the hyperthermophilic archaeon, Pyrococcus furiosus. The gene appears to be individually transcribed and encodes a protein of 339 amino acids. The amino acid sequence comparison with other archael PurAs found from recent genome analyses indicated that two deletions, one central and the other C-terminal, are a common feature of archaeal PurAs. None of the 21 PurA homologues analyzed from Eukarya and Bacteria exhibited this feature. Amino acid sequences of PurAs in Archaea showed 64% average identities which were significantly higher than the 50% and 55% calculated for Bacteria and Eukarya, respectively. Several residues conserved in PurAs of both Eukarya and Bacteria and shown to be of catalytic importance are missing in the archaeal PurAs. Phylogenetic analysis using PurA as the marker grouped life into 3 domains, hence it was consistent with results derived from 16-18S ribosomal RNA sequences. The topology within the three domains, in general, portrayed the hitherto accepted evolutionary relationship among the organisms utilized. PurA can, thus, serve as an additional marker to evaluate phylogenetic inferences drawn from sequence data from rRNA and other conserved genes. The presence of two unique deletions in both euryarchaeal and crenarchaeal PurAs, but not in those of Bacteria and Eukarya, is a strong evidence confirming the common lineage of these two subdomains of Archaea.

Ambiguities in mapping the active site of a conformationally dynamic enzyme by directed mutation. Role of dynamics in structure-function correlations in Escherichia coli adenylosuccinate synthetase

On the basis of ligated crystal structures, Asn21, Asn38, Thr42, and Arg419 are not involved in the chemical mechanism of adenylosuccinate synthetase from Escherichia coli, yet these residues are well conserved across species. Purified mutants (Asp21 --> Ala, Asn38 --> Ala, Asn38 --> Asp, Asn38 --> Glu, Thr42 --> Ala, and Arg419 --> Leu) were studied by kinetics, circular dichroism spectroscopy, and equilibrium ultracentrifugation. Asp21 and Arg419 are not part of the active site, yet mutations at positions 21 and 419 lower kcat 20- and 10-fold, respectively. Thr42 interacts only through its backbone amide with the guanine nucleotide, yet its mutation to alanine significantly increases Km for all substrates. Asn38 hydrogen-bonds directly to the 5'-phosphoryl group of IMP, yet its mutation to alanine and glutamate has no effect on Km values, but reduces kcat by 100-fold. The mutation Asn38 --> Asp causes 10-57-fold increases in Km for all substrates along with a 30-fold decrease in kcat. At pH 5.6, however, the Asn38 --> Asp mutant is more active, yet binds IMP 100-fold more weakly, than the wild-type enzyme. Proposed mechanisms of ligand-induced conformational change and subunit aggregation can account for the properties of mutant enzymes reported here. The results underscore the difficulty of using directed mutations alone as a means of mapping the active site of an enzyme.

Relationship of conserved residues in the IMP binding site to substrate recognition and catalysis in Escherichia coli adenylosuccinate synthetase

Gln34, Gln224, Leu228, and Ser240 are conserved residues in the vicinity of bound IMP in the crystal structure of Escherichia coli adenylosuccinate synthetase. Directed mutations were carried out, and wild-type and mutant enzymes were purified to homogeneity. Circular dichroism spectroscopy indicated no difference in secondary structure between the mutants and the wild-type enzyme in the absence of substrates. Mutants L228A and S240A exhibited modest changes in their initial rate kinetics relative to the wild-type enzyme, suggesting that neither Leu228 nor Ser240 play essential roles in substrate binding or catalysis. The mutants Q224M and Q224E exhibited no significant change in KmGTP and KmASP and modest changes in KmIMP relative to the wild-type enzyme. However, kcat decreased 13-fold for the Q224M mutant and 10(4)-fold for the Q224E mutant relative to the wild-type enzyme. Furthermore, the Q224E mutant showed an optimum pH at 6.2, which is 1.5 pH units lower than that of the wild-type enzyme. Tryptophan emission fluorescence spectra of Q224M, Q224E, and wild-type proteins under denaturing conditions indicate comparable stabilities. Mutant Q34E exhibits a 60-fold decrease in kcat compared with that of the wild-type enzyme, which is attributed to the disruption of the Gln34 to Gln224 hydrogen bond observed in crystal structures. Presented here is a mechanism for the synthetase, whereby Gln224 works in concert with Asp13 to stabilize the 6-oxyanion of IMP.

Homology modeling of adenylosuccinate synthetase from Saccharomyces cerevisiae reveals a possible binding region for single-stranded ARS sequences

Adenylosuccinate synthetase from Saccharomyces cerevisiae was investigated in order to find a structural explanation for its ability to bind specifically to single-stranded ARS elements (autonomously replicating sequences). Using the E. coli enzyme as template, a model for the structure of adenylosuccinate synthetase from S. cerevisiae was generated and subsequently refined by molecular dynamics techniques. The resulting three-dimensional structure offers an explanation for the DNA binding activity of the yeast enzyme by revealing a distinct basic region that is not present in the homologous enzymes from other organisms. The model is also in good agreement with biochemical data available for a mutant protein in which Glycine 252 is replaced by Aspartate. On the basis of the model a significant structural distortion near the catalytic center was predicted for this mutant, corresponding well to the enzymatic inactivity observed. The mutant enzyme shows larger structural fluctuations than the wild-type protein according to the results of two independent molecular dynamics simulations.

A study of Escherichia coli adenylosuccinate synthetase association states and the interface residues of the homodimer

The state of aggregation of adenylosuccinate synthetase from Escherichia coli is a point of controversy, with crystal structures indicating a dimer and some solution studies indicating a monomer. Crystal structures implicate Arg143 and Asp231 in stabilizing the dimer, with Arg143 interacting directly with bound IMP of the 2-fold related subunit. Residue Arg143 was changed to Lys and Leu, and residue Asp231 was changed to Ala. Matrix-assisted laser desorption ionization mass spectroscopy and analytical ultracentrifugation of the wild-type and the mutant enzymes indicate a mixture of monomers and dimers, with a majority of the enzyme in the monomeric state. In the presence of active site ligands, the wild-type enzyme exists almost exclusively as a dimer, whereas the mutant enzymes show only slightly decreased dissociation constants for the dimerization. Initial rate kinetic studies of the wild-type and mutant enzymes show similar kcat and Km values for aspartate. However, increases in the Km values of GTP and IMP are observed for the mutant. Changes in dissociation constants for IMP are comparable with changes in Km values. Our results suggest that IMP binding induces enzyme dimerization and that two residues in the interface region, Arg143 and Asp231, play significant roles in IMP and GTP binding.

Subunit complementation of Escherichia coli adenylosuccinate synthetase

Data are presented, based upon subunit complementation experiments, that suggest that Escherichia coli adenylosuccinate synthetase contains two shared active sites between its dimeric interface. This conclusion was alluded to by use of mutant forms of adenylosuccinate synthetase previously prepared by site-directed mutagenesis. The experiments indicate that, although the R143L and D13A mutants have low or no activity independently, when they are mixed, a significant amount of activity was obtained. These results indicate that the subunits exchange with each other to form heterodimers with a single viable wild-type active site. The kcat value for the active hybrid active site in the R143L-D13A heterodimer is virtually identical to that observed with the wild-type enzyme, and the other kinetic parameters are very similar to those found for the wild-type enzyme. An analysis of the restoration of the activity in the presence of substrates suggests that GTP and IMP stabilize the dimeric structure of the protein. A comparison of the restoration of the activity using different combinations of mutants provides evidence indicating that some of the GTP binding elements, including the P-loop, in the protein are important for subunit integrity. Also, for the first time, a comprehensive analysis of subunit complementation is performed for the two inactive mutants (R143L and D13A) where the dissociation constants for the R143L-D13A heterodimer and the D13A homodimer were determined to be 21 and 2.9 microM, respectively. A concentration dependence of the specific activity of the wild-type protein in this study shows that the Kd for dimer dissociation is approximately 1 microM.

Enzymatic properties and inhibition by single-stranded autonomously replicating sequences of adenylosuccinate synthase from Saccharomyces cerevisiae

Adenylosuccinate synthase (ASS) from Saccharomyces cerevisiae has been shown to bind specifically to the T-rich side of the autonomously replicating sequence (ARS) core consensus sequence [Zeidler, R., Hobert, O., Johannes, L., Faulhammer, H. & Krauss, G. (1993) J. Biol. Chem. 268, 20191-20197]. We have cloned and sequenced the gene for ASS and have studied in detail the enzymatic properties and DNA-binding activity of ASS. The deduced amino acid sequence of the yeast ASS is highly similar to the same enzymes from other sources from which it is however distinguished by its more basic nature. We show that the enzymatic activity of ASS is inhibited in a highly specific manner by the binding of a 44-base DNA oligonucleotide carrying the ARS core consensus sequence. Other nucleic acids, rNTP and dNTP are not able to mimic the specific inhibitory effect. Single-base substitutions in the ARS core sequence lead to a tenfold reduction in inhibition. The inhibition data corroborate the earlier report on the DNA-binding specificity of this enzyme. The homologous enzymes from Escherichia coli and Dictyostelium discoideum do not show specific binding to single-stranded ARS sequences and their enzymatic activity is not influenced by the presence of a 44-base DNA oligonucleotide carrying the ARS core consensus sequence. Treatment of ASS with alkaline phosphatase leads to a loss of DNA binding and to a loss of the inhibition by DNA of the enzymatic activity which suggests that the DNA-binding activity but not the enzymatic activity may be regulated by the phosphorylation status of the protein.

Refined crystal structures of guanine nucleotide complexes of adenylosuccinate synthetase from Escherichia coli

Structures of adenylosuccinate synthetase from Escherichia coli complexed with guanosine-5'-(beta,gamma-imido) triphosphate and guanosine-5'-(beta,gamma-methylene)triphosphate in the presence and the absence of Mg2+ have been refined to R-factors below 0.2 against data to a nominal resolution of 2.7 A. Asp333 of the synthetase hydrogen bonds to the exocyclic 2-amino and endocyclic N1 groups of the guanine nucleotide base, whereas the hydroxyl of Ser414 and the backbone amide of Lys331 hydrogen bond to the 6-oxo position. The side chains of Lys331 and Pro417 pack against opposite faces of the guanine nucleotide base. The synthetase recognizes neither the N7 position of guanine nucleotides nor the ribose group. Electron density for the guanine-5'-(beta,gamma-imido) triphosphate complex is consistent with a mixture of the triphosphate nucleoside and its hydrolyzed diphosphate nucleoside bound to the active site. The base, ribose, and alpha-phosphate positions overlap, but the beta-phosphates occupy different binding sites. The binding of guanosine-5'-(beta,gamma-methylene)triphosphate to the active site is comparable with that of guanosine-5'-(beta, gamma-imido)triphosphate. No electron density, however, for the corresponding diphosphate nucleoside is observed. In addition, electron density for bound Mg2+ is absent in these nucleotide complexes. The guanine nucleotide complexes of the synthetase are compared with complexes of other GTP-binding proteins and to a preliminary structure of the complex of GDP, IMP, Mg2+, and succinate with the synthetase. The enzyme, under conditions reported here, does not undergo a conformational change in response to the binding of guanine nucleotides, and minimally IMP and/or Mg2+ must be present in order to facilitate the complete recognition of the guanine nucleotide by the synthetase.

CTBP1/RBP1, a Saccharomyces cerevisiae protein which binds to T-rich single-stranded DNA containing the 11-bp core sequence of autonomously replicating sequence, is a poly(deoxypyrimidine)-binding protein

South-Western screening of a glutathione-S-transferase fusion protein library constructed from the yeast Saccharomyces cerevisiae genomic DNA lead to isolation of core T-rich-strand-binding protein (CTBP) clones that bound to single-stranded DNA containing the T-rich-strand of the 11-bp core sequence of autonomously replicating sequences. One of these clones, CTBP1, contains a portion of previously described RBP1 which is an RNA-binding and single-stranded DNA-binding protein of S. cerevisiae. GST-CTBP1 as well as the full-length fusion protein with RBP1 (GST-RBP1) bind exclusively to the T-rich strand of the core sequence with an apparent dissociation constant of 5 nM, but not to the A-rich strand or double strand of the same sequence. Mutations within the core which reduce the number of T or C residues decrease the affinity of this protein. In keeping with this, binding of GST-CTBP1 to the core sequence is efficiently completed by poly(dT), poly(dT-dC) or poly(dC), but not by poly(dA) or poly(dG) to significant extents. Among polyribonucleic acids, GST-CTBP1 binds to poly(U) and poly(I) with greatest affinity, whereas GST-RBP1 binds to RNA in a rather non-specific manner. In no cases was affinity for RNA greater than that for DNA. Our results indicate that CTBP1/RBP1 is a polydeoxypyrimidine-binding protein of S. cerevisiae. CTBP1 contains two sets of an RNA-recognition motif (RRM) and a glutamine stretch. The binding affinity of the N-terminal or C-terminal set containing one RRM and one glutamine stretch is nearly two orders of magnitude lower than that of the wild-type CTBP1 containing both sets. The isolated N-terminal or C-terminal RRM alone (RRM1 and RRM2, respectively) is sufficient for binding nucleic acids with the binding specificity similar to that of the wild-type RRM, although the binding affinity of the isolated RRM2 is nearly two orders of magnitude lower than that of RRM1. Our results indicate that the two RRMs present in CTBP1/RBP1 have differential binding affinities and that the high affinity of RRM for polydeoxypyrimidine results from synergy between two lower-affinity RRMs.