The nucleoside triphosphate pools of two cytidine auxotrophic mutants of Salmonella typhimurium LT-2 were studied under different conditions of pyrimidine starvation. Both mutants, DP-45 and DP-55, are defective in cytidine deaminase and cytidine triphosphate (CTP) synthase. In addition, DP-55 has a requirement for uracil (uridine). Cytidine starvation of the mutants results in accumulation of high concentrations of uridine triphosphate (UTP) in the cells, while the pools of CTP and deoxy-CTP drop to undetectable levels within a few minutes. Addition of deoxycytidine to such cells does not restore the dCTP pool, indicating that S. typhimurium has no deoxycytidine kinase. From the kinetics of UTP accumulation during cytidine starvation, it is concluded that only cytidine nucleotides participate in the feedback regulation of de novo synthesis of UTP; both uridine and cytidine nucleotides participate in the regulation of UTP synthesis from exogenously supplied uracil or uridine. Uracil starvation of DP-55 in presence of cytidine results in extensive accumulation of CTP, suggesting that CTP does not regulate its own synthesis from exogenous cytidine. Analysis of the thymidine triphosphate (dTTP) pool of DP-55 labeled for several generations with 32 P-orthophosphate and 3 H-uracil in presence of 12 C-cytidine shows that only 20% of the dTTP pool is derived from uracil (via the methylation of deoxyuridine monophosphate); 80% is apparently synthesized from a cytidine nucleotide.
dCTP deaminase (EC 3.5.4.13) catalyzes the deamination of dCTP forming dUTP that via dUTPase is the main pathway providing substrate for thymidylate synthase in Escherichia coli and Salmonella typhimurium. dCTP deaminase is unique among nucleoside and nucleotide deaminases as it functions without aid from a catalytic metal ion that facilitates preparation of a water molecule for nucleophilic attack on the substrate. Two active site amino acid residues, Arg115 and Glu138, were identified by mutational analysis as important for activity in E. coli dCTP deaminase. None of the mutant enzymes R115A, E138A, or E138Q had any detectable activity but circular dichroism spectra for all mutant enzymes were similar to wild type suggesting that the overall structure was not changed. The crystal structures of wild-type E. coli dCTP deaminase and the E138A mutant enzyme have been determined in complex with dUTP and Mg2+, and the mutant enzyme also with the substrate dCTP and Mg2+. The enzyme is a third member of the family of the structurally related trimeric dUTPases and the bifunctional dCTP deaminase-dUTPase from Methanocaldococcus jannaschii. However, the C-terminal fold is completely different from dUTPases resulting in an active site built from residues from two of the trimer subunits, and not from three subunits as in dUTPases. The nucleotides are well defined as well as Mg2+ that is tridentately coordinated to the nucleotide phosphate chains. We suggest a catalytic mechanism for the dCTP deaminase and identify structural differences to dUTPases that prevent hydrolysis of the dCTP triphosphate.
Deletion of the Escherichia coli K-12 chromosome associated with P2 mediated education extend through the structural gene for uridine kinase, udk, and the dcd gene encoding 2'-deoxycytidine 5'-triphosphate deaminase. The lack of uridine kinase makes a positive selection possible for these strains. Due to the dcd mutation, P2 eductants show large alterations in their deoxyribonucleoside triphosphate pools.
ABSTRACT Salmonella enterica , in contrast to Escherichia coli K12, can use 2-deoxy- d -ribose as the sole carbon source. The genetic determinants for this capacity in S. enterica serovar Typhimurium include four genes, of which three, deoK , deoP , and deoX , constitute an operon. The fourth, deoQ , is transcribed in the opposite direction. The deoK gene encodes deoxyribokinase. In silico analyses indicated that deoP encodes a permease and deoQ encodes a regulatory protein of the deoR family. The deoX gene product showed no match to known proteins in the databases. Deletion analyses showed that both a functional deoP gene and a functional deoX gene were required for optimal utilization of deoxyribose. Using gene fusion technology, we observed that deoQ and the deoKPX operon were transcribed from divergent promoters located in the 324-bp intercistronic region between deoQ and deoK . The deoKPX promoter was 10-fold stronger than the deoQ promoter, and expression was negatively regulated by DeoQ as well as by DeoR, the repressor of the deoxynucleoside catabolism operon. Transcription of deoKPX but not of deoQ was regulated by catabolite repression. Primer extension analysis identified the transcriptional start points of both promoters and showed that induction by deoxyribose occurred at the level of transcription initiation. Gel retardation experiments with purified DeoQ illustrated that it binds independently to tandem operator sites within the deoQ and deoK promoter regions with K d values of 54 and 2.4 nM, respectively.
Xanthine phosphoribosyltransferase (XPRTase) from Bacillus subtilis is a representative of the highly xanthine specific XPRTases found in Gram-positive bacteria. These XPRTases constitute a distinct subclass of 6-oxopurine PRTases, which deviate strongly from the major class of H(X)GPRTases with respect to sequence, PRPP binding motif, and oligomeric structure. They are more related with the PurR repressor of Gram-positive bacteria, the adenine PRTase, and orotate PRTase. The catalytic function and high specificity for xanthine of B. subtilis XPRTase were investigated by ligand binding studies and reaction kinetics as a function of pH with xanthine, hypoxanthine, and guanine as substrates. The crystal structure of the dimeric XPRTase−GMP complex was determined to 2.05 Å resolution. In a sequential reaction mechanism XPRTase binds first PRPP, stabilizing its active dimeric form, and subsequently xanthine. The XPRTase is able also to react with guanine and hypoxanthine albeit at much lower (10-4-fold) catalytic efficiency. Different pKa values for the bases and variations in their electrostatic potential can account for these catalytic differences. The unique base specificity of XPRTase has been related to a few key residues in the active site. Asn27 can in different orientations form hydrogen bonds to an amino group or an oxo group at the 2-position of the purine base, and Lys156 is positioned to make a hydrogen bond with N7. This and the absence of a catalytic carboxylate group near the N7-position require the purine base to dissociate a proton spontaneously in order to undergo catalysis.
dCMP deaminase from Bacillus subtilis has been purified 700-fold. In addition to the substrate, dCMP, the enzyme requires dCTP, Zn2+, and 2-mercaptoethanol, Mg2+ cannot substitute for Zn2+. The dCMP saturation curve is hyperbolic in the presence of saturating concentrations of dCTP and Zn2+. The dCTP saturation curve is sigmoidal, the sigmoidicity being dependent on the Zn2+ and dCMP concentrations. The molecular weight as determined by gel filtration is 170,000 both in the presence and in the absence of dCTP and Zn2+. In the absence of thiols, the enzyme is highly unstable. At 0 degrees, the half-life of the enzyme activity is 30 min. Addition of Zn2+ and dCTP protects against this inactivation. In the presence of a thiol, dCTP and Zn2+ protect the enzyme against heat inactivation at 50 degrees. A mutant lacking dCMP deaminase (dcd) was isolated. Labeling of the pyrimidine nucleotide pools reveals that in the parent strain, 45% of the dTTP pool is derived via dCMP deamination, the residual 55% being derived via reduction of a uridine nucleotide. Since the dcd mutant grows with the same doubling time as the parent strain, we conclude that uridine nucleotide reduction alone is capable of supplying sufficient dUMP for normalthymidine nucleotide synthesis.
ABSTRACT During translation of the Bacillus subtilis cdd gene, encoding cytidine deaminase (CDA), a ribosomal −1 frameshift occurs near the stop codon, resulting in a CDA subunit extended by 13 amino acids. The frequency of the frameshift is approximately 16%, and it occurs both when the cdd gene is expressed from a multicopy plasmid in Escherichia coli and when it is expressed from the chromosomal copy in B. subtilis . As a result, heterotetrameric forms of the enzyme are formed in vivo along with the dominant homotetrameric species. The different forms have approximately the same specific activity. The cdd gene was cloned in pUC19 such that the lacZ ′ gene of the vector followed the cdd gene in the −1 reading frame immediately after the cdd stop codon. By using site-directed mutagenesis of the cdd-lacZ ′ fusion, it was shown that frameshifting occurred at the sequence CGA AAG, 9 bp upstream of the in-frame cdd stop codon, and that it was stimulated by a Shine-Dalgarno-like sequence located 14 bp upstream of the shift site. The possible function of this frameshift in gene expression is discussed.
A lambda-specialized transducing phage carrying the pyrE gene from Salmonella typhimurium LT2 was constructed and used as the source of DNA for subcloning the pyrE gene into pBR322. The pyrE gene product was identified as a 23-kDa polypeptide using a minicell system for analysis of plasmid-encoded proteins. Studies utilizing a promoter-cloning vehicle provided evidence for the existence of two promoter regions, one located close to the start of the structural gene and the other positioned more than 300 base pairs upstream. Transcription from the more distal promotor was the only situation in which significant regulation by pyrimidines was observed. Additional studies served to localize sites involved in the regulation of pyrE expression and led to the inference that regulation does not occur at the level of initiation of transcription. A procedure was developed for the construction of plasmids through recombination in vivo, whereby pyrE::Mud1 (Ap lac) fusions were transferred to a recipient pyrE+ plasmid by bacteriophage P22-mediated transduction. This enabled the identification of the integration sites of Mud within pyrE and also verified the deduced orientation of the pyrE gene in the parental plasmid. The nucleotide sequence of the 5' end of the pyrE gene was determined, including 150 nucleotide residues encoding the first 50 N-terminal amino acids of orotate phosphoribosyltransferase, and 400 nucleotides upstream from the start of the coding region. The leader region contains sequences characteristic of a rho-independent transcriptional terminator preceded by a cluster of thymidylate residues. In addition, the leader RNA contains an open reading frame with a UGA stop codon immediately preceding the putative transcriptional terminator. The nucleotide sequence suggests that pyrE expression is regulated by modulated attenuation, as has been proposed to be the case for both pyrB and pyrE expression in Escherichia coli.
Purine-requiring mutants of Salmonella typhimurium LT2 containing additional mutations in either adenosine deaminase or purine nucleoside phosphorylase have been constructed. From studies of the ability of these mutants to utilize different purine compounds as the sole source of purines, the following conclusions may be drawn. (i) S. typhimurium does not contain physiologically significant amounts of adenine deaminase and adenosine kinase activities. (ii) The presence of inosine and guanosine kinase activities in vivo was established, although the former activity appears to be of minor significance for inosine metabolism. (iii) The utilization of exogenous purine deoxyribonucleosides is entirely dependent on a functional purine nucleoside phosphorylase. (iv) The pathway by which exogenous adenine is converted to guanine nucleotides in the presence of histidine requires a functional purine nucleoside phosphorylase. Evidence is presented that this pathway involves the conversion of adenine to adenosine, followed by deamination to inosine and subsequent phosphorolysis to hypoxanthine. Hypoxanthine is then converted to inosine monophosphate by inosine monophosphate pyrophosphorylase. The rate-limiting step in this pathway is the synthesis of adenosine from adenine due to lack of endogenous ribose-l-phosphate.
