Interactions between T4 phage-coded deoxycytidylate hydroxymethylase and thymidylate synthase as revealed with an anti-idiotypic antibody.

Anti-idiotypic antibodies were used to mimic the binding surface of the T4 bacteriophage deoxycytidylate hydroxymethylase enzyme, providing an immunological probe for protein-protein interactions involving this enzyme. Polyclonal dCMP hydroxymethylase antibodies were affinity-purified and used to generate anti-idiotypic antibodies. The anti-idiotypic serum immunoprecipitated two native viral proteins, deoxycytidylate hydroxymethylase (EC 2.1.2.8) and thymidylate synthase (EC 2.1.1.45), from a sonicated detergent-treated extract of T4-infected Escherichia coli. The anti-anti-dCMP hydroxymethylase antibody was found to be specific in binding to the T4 dTMP synthase, with no detectable affinity for the host dTMP synthase. Previous work in our laboratory has demonstrated the viral dCMP hydroxymethylase and dTMP synthase to be associated in a deoxyribonucleotide synthetase enzyme complex. Our current approach, using anti-idiotypic antibodies as probes for protein-protein interactions, and complementary studies involving dCMP hydroxymethylase enzyme affinity columns indicate a direct association between bacteriophage T4 dCMP hydroxymethylase and dTMP synthase.     

Specific associations of T4 bacteriophage proteins with immobilized deoxycytidylate hydroxymethylase.

Is the enzymatic machinery for DNA precursor biosynthesis linked to the DNA replication apparatus? To identify intermolecular associations among deoxyribonucleotide biosynthetic enzymes and to ask whether these enzymes are linked to replication proteins, we analyzed radiolabeled T4 bacteriophage proteins that bind specifically to a column of immobilized T4 deoxycytidylate hydroxymethylase. More than a dozen T4 proteins and a few Escherichia coli proteins are adsorbed specifically by this column. Several of the T4 proteins were identified by two-dimensional gel electrophoresis and radioautography. These include five enzymes involved in DNA precursor biosynthesis, dCMP hydroxymethylase, thymidylate synthase, dihydrofolate reductase, dCTPase-dUTPase, and ribonucleotide reductase large and small subunits, plus several proteins of DNA metabolism and replication. Analysis of extracts of cells infected with phage amber mutants defective in specific proteins suggested a specific association involving thymidylate synthase and the gene 32 single-strand DNA-binding protein.     

Crystal structure of deoxycytidylate hydroxymethylase from bacteriophage T4, a component of the deoxyribonucleoside triphosphate-synthesizing complex

Bacteriophage T4 deoxycytidylate hydroxymethylase (EC 2.1.2.8), a homodimer of 246-residue subunits, catalyzes hydroxymethylation of the cytosine base in deoxycytidylate (dCMP) to produce 5-hydroxymethyl-dCMP. It forms part of a phage DNA protection system and appears to function in vivo as a component of a multienzyme complex called deoxyribonucleoside triphosphate (dNTP) synthetase. We have determined its crystal structure in the presence of the substrate dCMP at 1.6 A resolution. The structure reveals a subunit fold and a dimerization pattern in common with thymidylate synthases, despite low (approximately 20%) sequence identity. Among the residues that form the dCMP binding site, those interacting with the sugar and phosphate are arranged in a configuration similar to the deoxyuridylate binding site of thymidylate synthases. However, the residues interacting directly or indirectly with the cytosine base show a more divergent structure and the presumed folate cofactor binding site is more open. Our structure reveals a water molecule properly positioned near C-6 of cytosine to add to the C-7 methylene intermediate during the last step of hydroxymethylation. On the basis of sequence comparison and crystal packing analysis, a hypothetical model for the interaction between T4 deoxycytidylate hydroxymethylase and T4 thymidylate synthase in the dNTP-synthesizing complex has been built.     

Characteristics of a bacteriophage T4-induced complex synthesizing deoxyribonucleotides

A preparation of bacteriophage T4-induced deoxyribonucleotide synthetase complex is described. This very large complex of enzymes can be separated by centrifugation at 100,000 X g, by sucrose step gradient centrifugation, or with molecular exclusion columns. By direct assay and by unidimensional and two-dimensional acrylamide electrophoretic separations the following T4-coded enzymes were shown to be associated with the complex: ribonucleoside diphosphate reductase, dCMP deaminase, dCTP/dUTPase, dCMP hydroxymethylase, dTMP synthetase, and DNA polymerase. Other phage-coded prereplicative proteins related to DNA replication and other phage functions such as the proteins coded by genes 32, 46, rIIA, and rIIB as well as many unidentified proteins were also consistently associated with the isolated fractions. T4 DNA topoisomerase, a membrane-bound enzyme, was found in quantity in all purified fractions of the complex, even in preparations apparently free of membrane and of T4 DNA. The functional integrity of a segment of the complex was followed by measuring the conversion of [5-3H]CDP to the level of 5-hydroxymethyl dCMP. This series of reactions requires the actions of T4-coded ribonucleoside diphosphate reductase and its associated reducing system, dCTP/dUTPase and dCMP hydroxymethylase, 3H being lost to water at the last step. In this reaction sequence an intermediate, [5-3H]dCMP, is maintained at low steady state concentrations, and argument is presented that the synthesis of deoxyribonucleotides is channeled and normally tightly coupled to DNA replication. One of the primary characteristics of this complex is its ready dissociation of dilution into smaller complexes of proteins and to the free forms of the proteins. That the complex is held together by weak electrostatic forces was supported by its sensitivity to dissociation at moderate salt concentrations. Not only the enzymes required in deoxyribonucleotide synthesis but T4 DNA polymerase, T4 DNA topoisomerase, and a number of other proteins dissociate to varying degrees from the larger complexes under these conditions.     

On the inhibition of deoxycytidylate hydroxymethylase by 5-fluoro-2'-deoxycytidine 5'-monophosphate

Studies were performed to determine whether 5-fluoro-2'-deoxycytidine 5'-monophosphate (FdCMP) is an inhibitor of deoxycytidylate hydroxymethylase and whether it could form an isolable covalent complex with the enzyme and the cofactor, 5,10-methyl-enetetrahydrofolate. The results showed that although FdCMP is a competitive inhibitor of dCMP hydroxymethylase, it does not cause time-dependent inhibition of the enzyme in the presence of cofactor. Further, although uv difference spectral evidence was found for FdCMP-cofactor-enzyme complex, the complex was not sufficiently stable to isolate on nitrocellulose filters. We conclude that FdCMP is not a mechanism-based inhibitor of dCMP hydroxymethylase.     

Deoxycytidylate hydroxymethylase gene of bacteriophage T4. Nucleotide sequence determination and over-expression of the gene

We describe two approaches to cloning and over-expressing gene 42 of bacteriophage T4, which encodes the early enzyme deoxycytidylate hydroxymethylase. In Bochum a library of sonicated fragments of wild-type phage DNA cloned into M13mp18 was screened with clones known to contain parts of gene 42. Two overlapping fragments, each of which contained one end of the gene, were cleaved at a HincII site and joined, to give a fragment containing the entire gene. In Corvallis a 1.8-kb fragment of cytosine-substituted DNA, believed to contain the entire gene, was cloned into pUC18 and shown to express the enzyme at low level. The cloned fragment bore an amber mutation in gene 42. From the DNA sequence of gene 42, the cloned gene was converted to the wild-type allele by site-directed mutagenesis. Both gene-42-containing fragments were cloned into the pT7 expression system and found to be substantially overexpressed. dCMP hydroxymethylase purified from one of the over-expressing strains had a turnover number similar to that of the enzyme isolated earlier from infected cells. In addition, the N-terminal 20 amino acid residues matched precisely the sequence predicted from the gene sequence. The amino acid sequence of gp42 bears considerable homology with that of thymidylate synthase of either host or T4 origin. The gene 42 nucleotide sequences of bacteriophages T2 and T6 were determined and found to code for amino acid sequences nearly identical to that of T4 gp42.     

T6r+-induced Proteins and Nucleic Acids in Escherichia coli Infected in the Presence of Streptomycin

Streptomycin does not strongly inhibit T-even phage multiplication in the streptomycin-susceptible polyauxotroph, Escherichia coli strain T(-)H(-)U(-). The relatively slight inhibition, observed earlier, on production of late proteins has now been studied further. The phage-induced ribonucleic acid, synthesized in T6 phage infection in the presence of streptomycin, has been characterized by its base composition, size distribution, and behavior in hybridization tests. Comparison of these properties to those of control samples, taken during either early or late periods of infection, have not shown any significant differences. Phage-induced proteins, synthesized at different times during infection, were studied by disc-gel electrophoresis. Staining and autoradiography of the patterns of pulse-labeled proteins, formed in the absence and presence of the antibiotic showed only slight quantitative changes in the appearance of early proteins. More marked quantitative effects were detected later in infection. Nevertheless, changes in the mobilities of the different proteins were not observed in the streptomycin-treated cultures at any time after infection, suggesting the absence of gross misreading sufficiently great to alter the distinctive electrophoretic patterns of the extracts. Cells infected and incubated in the presence of the antibiotic were found to contain intact virus particles, as shown by electron microscopy. Such infected cells contained extensive deoxyribonucleic acid pools and did not develop the rounded nucleoids with enclosed dense bodies characteristic of the lethal action of the antibiotic. On the other hand, infected bacteria previously exposed to lethal concentrations of streptomycin were unable to synthesize the early enzymes, deoxycytidylate (dCMP) hydroxymethylase and dihydrofolate reductase, or to make phage deoxyribonucleic acid and phage. Such previously killed cells contained the rounded and clotted nucleoids and were unable to unravel this pathological structure after phage infection.     

Intracellular DNA-protein complexes from bacteriophage T4-infected cells isolated by a rapid two-step procedure. Characterization and identification of the protein components.

A simple technique has been developed for isolating intracellular DNA and its bound proteins from uninfected and phage-infected bacteria. This technique, which utilizes aqueous salt concentrations in the physiological range, is based upon the fact that DNA exists in normal cell lysates in a stiff random coil conformation, and has an unusually large excluded volume to mass ratio. Such stiff coils display a unique combination of low sedimentation coefficient and large Stokes radius, enabling them to be separated rapidly from all other cellular components by successive centrifugal and gel permeation steps. Analysis of this purified intracellular DNA fraction from bacteriophage T4-infected Escherichia coli reveals mainly DNA and protein, with a small amount of RNA also present. Among the major proteins obtained are the DNA-dependent RNA polymerase of the host and the products of T4 genes rIIA, rIIB, and 32 (DNA-"unwinding" protein). Small amounts of the proteins coded by T4 genes 43 (DNA polymerase) and 42 (dCMP hydroxymethylase) have also been identified, in addition to at least 13 other phage-coded proteins of unidentified genes. Much of the phage-coded protein in the complex, including the gene 32 protein, does not exchange readily with the same protein exogenously added in the lysate.     

Protein-DNA interactions in the T4 dNTP synthetase complex dependent on gene 32 single-stranded DNA-binding protein

Our laboratory has reported data suggesting a role for T4 phage gene 32 single-stranded DNA-binding protein in organizing a complex of deoxyribonucleotide-synthesizing enzymes at the replication fork. In this article we examined the effects of gene 32 ablation on the association of these enzymes with DNA-protein complexes. These experiments showed several deoxyribonucleotide-synthesizing enzymes to be present in DNA-protein complexes, with some of these associations being dependent on gene 32 protein. To further understand the role of gp32, we created amber mutations at codons 24 and 204 of gene 32, which encodes a 301-residue protein. We used the newly created mutants along with several experimental approaches--DNA-cellulose chromatography, immunoprecipitation, optical biosensor analysis and glutathione-S-transferase pulldowns--to identify relevant protein-protein and protein-DNA interactions. These experiments identified several proteins whose interactions with DNA depend on the presence of intact gp32, notably thymidylate synthase, dihydrofolate (DHF) reductase, ribonucleotide reductase (RNR) and Escherichia coli nucleoside diphosphate (NDP) kinase, and they also demonstrated direct associations between gp32 and RNR and NDP kinase, but not dCMP hydroxymethylase, deoxyribonucleoside monophosphate kinase, or DHF reductase. Taken together, the results support the hypothesis that the gene 32 protein helps to recruit enzymes of deoxyribonucleoside triphosphates synthesis to DNA replication sites.     

Allosteric regulation of the class III anaerobic ribonucleotide reductase from bacteriophage T4

Ribonucleotide reductase (RNR) is an essential enzyme in all organisms. It provides precursors for DNA synthesis by reducing all four ribonucleotides to deoxyribonucleotides. The overall activity and the substrate specificity of RNR are allosterically regulated by deoxyribonucleoside triphosphates and ATP, thereby providing balanced dNTP pools. We have characterized the allosteric regulation of the class III RNR from bacteriophage T4. Our results show that the T4 enzyme has a single type of allosteric site to which dGTP, dTTP, dATP, and ATP bind competitively. The dissociation constants are in the micromolar range, except for ATP, which has a dissociation constant in the millimolar range. ATP and dATP are positive effectors for CTP reduction, dGTP is a positive effector for ATP reduction, and dTTP is a positive effector for GTP reduction. dATP is not a general negative allosteric effector. These effects are similar to the allosteric regulation of class Ib and class II RNRs, and to the class Ia RNR of bacteriophage T4, but differ from that of the class III RNRs from the host bacterium Escherichia coli and from Lactococcus lactis. The relative rate of reduction of the four substrates was measured simultaneously in a mixed-substrate assay, which mimics the physiological situation and illustrates the interplay between the different effectors in vivo. Surprisingly, we did not observe any significant UTP reduction under the conditions used. Balancing of the pyrimidine deoxyribonucleotide pools may be achieved via the dCMP deaminase and dCMP hydroxymethylase pathways.     

T4 phage ribonucleotide reductase. Allosteric regulation in vivo by thymidine triphosphate

Based upon analyses of purified enzyme preparations, T4 bacteriophage-coded ribonucleotide reductase is considered to be relatively insensitive to control by allosteric inhibition. However, two factors suggest that CDP reduction to dCDP is feedback-controlled by dTTP in infected cells. First, the pool of 5-hydroxymethyldeoxycytidine triphosphate, which expands manyfold upon infection by a dCMP deaminase-deficient T4 mutant, shrinks to near-normal levels as a consequence of dTTP accumulation, and ribonucleotide reductase is the only apparent control point. Second, analysis of mutagenesis by 5-bromodeoxyuridine suggests that most induced mutations result from localized pool depletion of 5-hydroxymethyl-dCTP at replication sites, as if 5-bromo-dUTP were behaving like dTTP in inhibiting the CDP reductase activity of the phage enzyme. We found that CDP reductase activity in crude extracts of T4 phage-infected bacteria is sensitive to inhibition by either dTTP or 5-bromo-dUTP, at concentrations as low as 0.01 mM. However, in partially purified enzyme preparations that sensitivity is lost. Although we don't know the basis for this loss of feedback sensitivity, the results suggest that kinetic properties of enzymes in intact cells are determined by the cellular milieu in ways not apparent from analysis of purified enzymes.     

On the defect of a dCMP hydroxymethylase mutant of bacteriophage T4 showing enzyme activity in extracts

Infection by $\text{L}\text{13}$, a temperature-sensitive mutant of gene 42 of phage T4, the structural gene for dCMP hydroxymethylase, previously was shown not to form T4 DNA at nonpermissive temperatures. Yet the enzyme activity was found in extracts. Since inactivation of the enzyme was not reversible, we have examined acid-soluble extracts of cells infected at nonpermissive temperature by $\text{tsL}\text{13}$ for 5-hydroxymethyldCMP in order to determine whether the enzyme functioned $\text{in vivo}$. A double mutant of $\text{tsL13}$ and $\text{amB}\text{24}$ (5-hydroxymethyldCMP kinase) did not form the nucleotide at nonpermissive temperature, but the control, $\text{amB}\text{24}$, formed large quantities. From these results and previous temperature-shift studies it is suggested that the enzyme is normally activated to function $\text{in vivo}$ between 5 and 8 minutes after infection.     

Biochemistry of DNA-Defective Amber Mutants of Bacteriophage T4 IV. DNA Synthesis in Plasmolyzed Cells

Requirements for bacteriophage T4 DNA synthesis have been investigated in situ by use of plasmolyzed infected cells. When such cells are incubated with dATP, dGTP, dTTP, hydroxymethyldeoxycytidine triphosphate, and rATP, significant semiconservative synthesis of DNA occurs. This DNA hybridizes preferentially to T4 DNA. T4 amber mutants defective in genes 44 and 45, which display a DNA-negative phenotype in vivo, are unable to synthesize DNA in situ. By contrast, T4 amber mutants bearing lesions in genes 41 and 62, which also display a DNA-negative phenotype in vivo, do allow DNA synthesis in situ, the extent of synthesis being 80 to 90% that of the wild-type synthesis under the same conditions. Cells infected with gene 42 mutants (dCMP hydroxymethylase) are unable to synthesize DNA in situ even though exogenous nucleotides are provided. Also one gene 1 mutant (deoxynucleotide kinase) was found to synthesize DNA in situ, but two other gene 1 mutants did not. These results point to possible roles of hydroxymethylase and kinase in DNA metabolism, in addition to provision of essential DNA precursors, as has recently been suggested by Wovcha et al. (1973).     

Deoxycytidylate hydroxymethylase: purification, properties, and the role of a thiol group in catalysis

Deoxycytidylate (dCMP) hydroxymethylase from Escherichia coli infected with a T-4 bacteriophage amber mutant has been purified to homogeneity. It is a dimer with a subunit molecular weight of 28,000. Chemical modification of the homogeneous enzyme with N-ethylmaleimide (NEM) and 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) leads to complete loss of enzyme activity. dCMP can protect the enzyme against NEM inactivation, but the dihydrofolate analogues methotrexate and aminopterin alone do not afford similar protection. Compared to dCMP alone, dCMP plus either methotrexate or aminopterin greatly enhances protection against NEM inactivation. DTNB inactivation is reversed by dithiothreitol. For both reagents, inactivation kinetics obey second-order kinetics. NEM inactivation is pH dependent with a pKa for a required thiol group of 9.15 +/- 0.11. Complete enzyme inactivation by both reagents involves the modification of one thiol group per mole of dimeric enzyme. There are two thiol groups in the totally denatured enzyme modified by either NEM or DTNB. Kinetic analysis of NEM inactivation cannot distinguish between these two groups; however, with DTNB kinetic analysis of 2-nitro-5-thiobenzoate release shows that enzyme inactivation is due to the modification of one fast-reacting thiol followed by the modification of a second group that reacts about 5-6-fold more slowly. In the presence of methotrexate, the stoichiometry of dCMP binding to the dimeric enzyme is 1:1 and depends upon a reduced thiol group. It appears that the two equally sized subunits are arranged asymmetrically, resulting in one thiol-containing active site per mole of dimeric enzyme.     

Selective screening procedure for the isolation of heat- and cold-sensitive, DNA replication-deficient mutants of bacteriophage SPO1 and preliminary characterization of the mutants isolated.

A procedure is described for the selective isolation of temperature-sensitive replication-deficient mutants of Bacillus subtilis phage SPO1. A modification of the procedure permits the isolation of temperature-sensitive mutants in specific cistrons of interest. The applicability of these procedures to other viral systems is discussed. The mutations isolated were assigned to eight replication-deficient cistrons, with the cold-sensitive mutations showing a distribution strikingly different from that of the heat-sensitive mutations. As a preliminary to the identification of initiation-deficient mutants, the mutants were divided into three classes on the basis of their ability to synthesize DNA after a shift to nonpermissive temperature. We also report two incidental results: (i) the SPO1 dUMP hydroxymethylase, like the T4 dCMP hydroxymethylase, may be part of a multifunctional complex; and (ii) mutants were isolated that were replication positive but lysis deficient and failed to complement one of the replication-deficient mutants.     

Roles of Cys148 and Asp179 in catalysis by deoxycytidylate hydroxymethylase from bacteriophage T4 examined by site-directed mutagenesis.

The proposed roles of Cys148 and Asp179 in deoxycytidylate (dCMP) hydroxymethylase (CH) have been tested using site-directed mutagenesis. CH catalyzes the formation of 5-(hydroxymethyl)-dCMP, essential for DNA synthesis in phage T4, from dCMP and methylenetetrahydrofolate. CH resembles thymidylate synthase (TS), an enzyme of known three-dimensional structure, in both amino acid sequence and the reaction catalyzed. Conversion of Cys148 to Asp, Gly, or Ser decreases CH activity at least 10(5)-fold, consistent with a nucleophilic role for Cys148 (analogous to the catalytic Cys residue in TS). In crystalline TS, hydrogen bonds connect O4 and N3 of the substrate dUMP to the side-chain amide of an Asn; the corresponding residue in CH is Asp179. Conversion of Asp179 to Asn reduces the value of kcat/KM for dCMP by (1.5 x 10(4))-fold and increases the value of kcat/KM for dUMP by 60-fold; as a result, CH(D179N) has a slight preference for dUMP. Wild-type CH and CH(D179N) are covalently inactivated by 5-fluoro-dUMP, a mechanism-based inactivator of TS. Asp179 is proposed to stabilize covalent catalytic intermediates, by protonating N3 of the pyrimidine-CH adduct.     

In vivo cleavage of cytosine-containing bacteriophage T4 DNA to genetically distinct, discretely sized fragments

Mutants of bacteriophage T4D that are defective in genes 42 (dCMP hydroxymethylase), 46 (DNA exonuclease), and 56 (dCTPase) produce limited amounts of phage DNA in Escherichia coli B. In this DNA, glucoylated 5-hydroxymethylcytosine is completely replaced by cytosine. We found that this DNA rapidly becomes fragmented in vivo to at least 16 discrete bands as visualized on agarose gels subjected to electrophoresis. The sizes of the fragments ranged from more than 20 to less than 2 kilobase pairs. When DNAs from two of these bands were radioactively labeled in vitro by nick translation and hybridized to XbaI restriction fragments of cytosine-containing T4 DNA, evidence was obtained that the two bands are genetically distinct, i.e., they contain DNA from different parts of the T4 genome. Mutational inactivation of T4 endonuclease II (gene denA) prevented the fragmentation. Three different mutations in T4 endonuclease IV (gene denB) caused the same minor changes in the pattern of fragments. We conclude that T4 endonuclease II is required, and endonuclease IV is involved to a minor extent, in the in vivo production of these cytosine-containing T4 DNA fragments. We view these DNA fragments as "restriction fragments" since they represent degradation products of DNA "foreign" to T4, they are of discrete size, and they are genetically distinct. Thus, this report may represent the first, direct in vivo demonstration of discretely sized genetically distinct DNA restriction fragments.     

In vivo functional interaction between DNA polymerase and dCMP-hydroxymethylase of bacteriophage T4.

Some mutations in the structural gene for T4 DNA polymerase (gene 43) behave as suppressors of a deficiency in T4 dCMP-hydroxymethylase (gene 42). The suppression appears to involve a functional interaction between the two enzymes at the level of DNA replication. The hydroxymethylase deficiency caused DNA structural abnormalities in replication, and DNA polymerase lesions appeared to partially reverse these abnormalities. The results do not necessarily imply protein-protein interactions between the two enzymes, although both enzymes appear to play roles in controlling the fidelity of phage DNA replication.