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.     

Relationship Between Escherichia coli B Titer and the Level of Deoxycytidylate Deaminase Activity Induced on Bacteriophage T2r+ Infection

The activities of six bacteriophage T2r(+)-induced enzymes (thymidylate synthetase, deoxycytidylate deaminase, thymidylate kinase, deoxycytidylate hydroxymethylase, deoxycytidine pyrophosphatase, and dihydrofolate reductase) were measured after dilution of phage-infected Escherichia coli B from 8 x 10(8) to 2 x 10(8) cells per ml. The only enzyme activity altered was that of deoxycytidylate deaminase, which increased three- to fourfold. Conversely, the rapid concentration of cells from 2 x 10(8) to 8 x 10(8) per ml did not result in a reduction in deaminase activity. Although an enhancement in aeration reduced the response of deoxycytidylate deaminase to cellular dilution, the influence of potential metabolic inhibitors or activators could not be shown. The change in deoxycytidylate deaminase activity appeared to be associated with an altered translational event, since the increase could not be prevented by rifampin but was blocked effectively by chloramphenicol and hydroxylamine. In addition, antibody to the T2 phage-induced deoxycytidylate deaminase demonstrated that the increase in enzyme activity was associated with a corresponding increase in radioactive leucine incorporated into the enzyme antigen.     

Isolation of Bacteriophage T4 Mutants Defective in the Ability to Degrade Host Deoxyribonucleic Acid

A method was devised for identifying nonlethal mutants of T4 bacteriophage which lack the capacity to induce degradation of the deoxyribonucleic acid (DNA) of their host, Escherichia coli. If a culture is infected in a medium containing hydroxyurea (HU), a compound that blocks de novo deoxyribonucleotide biosynthesis by interacting with ribonucleotide reductase, mutant phage that cannot establish the alternate pathway of deoxyribonucleotide production from bacterial DNA will fail to produce progeny. The progeny of 100 phages that survived heavy mutagenesis with hydroxylamine were tested for their ability to multiply in the presence of HU. Four of the cultures lacked this capacity. Cells infected with one of these mutants, designated T4nd28, accumulated double-stranded fragments of host DNA with a molecular weight of approximately 2 x 10(8) daltons. This mutant failed to induce T4 endonuclease II, an enzyme known to produce single-strand breaks in double-stranded cytosine-containing DNA. The properties of nd28 give strong support to an earlier suggestion that T4 endonuclease II participates in host DNA degradation. The nd28 mutation mapped between T4 genes 32 and 63 and was very close to the latter gene. It is, thus, in the region of the T4 map that is occupied by genes for a number of other enzymes, including deoxycytidylate deaminase, thymidylate synthetase, dihydrofolate reductase, and ribonucleotide reductase, that are nonessential to phage production in rich media.     

Deoxyribonucleic Acid Replication and Expression of Early and Late Bacteriophage Functions in Bacillus subtilis

The role of deoxyribonucleic acid (DNA) replication in the control of the synthesis of deoxycytidylate (dCMP) deaminase and lysozyme in Bacillus subtilis infected with bacteriophage 2C has been studied. These phage-induced enzymes are synthesized at different times during the latent period. It was shown by actinomycin inhibition that the formation of the late enzyme (lysozyme) required messenger ribonucleic acid (mRNA) synthesized de novo after the initiation of translation of mRNA which specifies the early function (dCMP deaminase). The inhibition of phage DNA synthesis by mitomycin C prevented the synthesis of lysozyme only when added before the onset of phage DNA replication, but it did not affect the synthesis or action of dCMP deaminase when added at any time during the latent period. Treatment of infected cells with mitomycin C after phage DNA synthesis had reached 8 to 10% of its maximal rate resulted in the production of normal amounts of lysozyme. These observations suggest that mRNA specifying early enzymes can be transcribed from parental (and probably also from progeny) DNA, whereas late functional messengers can be transcribed only after the formation of progeny DNA.     

Complete amino acid sequence of an allosteric enzyme, T2 bacteriophage deoxycytidylate deaminase

The amino acid sequence of deoxycytidylate deaminase isolated from T2 phage-infected Escherichia coli has been determined. The enzyme is a hexamer, consisting of identical polypeptide subunits, each composed of 188 amino acids with a calculated Mr = 20,560. The primary structure was established by automatic Edman degradation of the intact carboxymethylated protein and of peptides derived from the protein by cleavage with cyanogen bromide, trypsin, chymotrypsin, the Staphylococcus aureus V8 protease, and 2-(2-nitrophenylsulfenyl)-3-methyl-3-bromoindolenine. Knowledge of the primary structure of deoxycytidylate deaminase should aid in determining the allosteric binding site of the negative effector, dTTP, recently reported (Maley, F., and Maley, G.F. (1982) J. Biol. Chem. 257, 11876-11878), and eventually that of the enzyme's positive regulator, dCTP, as well as its substrate. The deaminase has been crystallized through the use of polyethylene glycol; a scanning electron micrograph is presented.     

Purification and properties of T4 phage thymidylate synthetase produced by the cloned gene in an amplification vector

We have introduced the T4 thymidylate synthetase gene, resident in a 2.7-kilobase EcoRI restriction fragment, into an amplification plasmid, pKC30. By regulating expression of this gene from the phage lambda pL promoter within pKC30 in a thyA host containing a temperature-sensitive lambda repressor, the T4 synthetase could be amplified about 200-fold over that after T4 infection. At this stage, a 20-fold purification was required to obtain homogeneous enzyme, mainly by an affinity column procedure. The purified plasmid-amplified T4 synthetase appeared to be identical with the T2 phage synthetase purified from phage-infected Escherichia coli in molecular weight, amino end group analysis, and immunochemical reactivity. The individual nature of the phage and host proteins was revealed by the fact that neither the T2 nor the T4 enzyme reacted with antibody to the E. coli synthetase, nor did antibody to the phage enzymes react with the E. coli synthetase. These differences were corroborated by DNA hybridization experiments, which revealed the absence of apparent homology between the T4 and E. coli synthetase genes. The techniques and genetic constructions described support the feasibility of employing similar amplification methods to prepare highly purified thymidylate synthetases from other sources.     

Studies on identifying the allosteric binding sites of deoxycytidylate deaminase

Thymidine triphosphate, a negative regulator of deoxycytidylate deaminase, was found to bind covalently to this enzyme on exposure to UV light at 254 nM. The rate of half-maximal fixation was extremely rapid, occurring within 30 s and probably attaining a maximum of about 1 mol of dTTP fixed/mol of enzyme subunit. In contrast to the case of ribonucleotide reductase (Ericksson, S., Caras, I. W., and Martin, D. W., Jr. (1982) Proc. Natl. Acad. Sci. U. S. A. 79, 81-85) where the fixation of dTTP inactivated this enzyme, the activity of the deaminase was unaffected. The bound nucleotide could be released on exposure to UV 254 nm light in the presence of dCTP or dTTP but not dATP or dGTP. The enzyme-fixed nucleotide was found to remain with the larger of the two peptides released as a result of CNBr treatment of the labeled enzyme. Studies are in progress to define the location of this nucleotide, which will be aided greatly by our recent clarification of the complete amino acid sequence of T2-deoxycytidylate deaminase.     

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.     

A T4-phage deoxycytidylate deaminase mutant that no longer requires deoxycytidine 5'-triphosphate for activation

A deoxycytidylate (dCMP) deaminase encoded in T4-bacteriophage DNA that is induced on phage infection of Escherichia coli was shown earlier (Maley, G. F., Duceman, B. W., Wang, A. M., Martinez, J. M., and Maley, F. (1990) J. Biol. Chem. 265, 47-51) to be similar in size, properties, and amino acid composition to the T2-phage-induced deaminase. Neither enzyme is active in the absence of dCTP or its natural activator, 5-hydroxymethyl-dCTP. However, on changing the arginine (Arg) at residue 115 of the T4-deaminase to either a glutamate (R115E) or a glutamine (R115Q), the resulting mutant enzymes were active in the absence of dCTP, with each mutant possessing a turnover number or k(cat) that is about 15% that of the wild-type deaminase. When compared on the basis of specific activity, however, the mutants are about 40-50% of the wild-type (WT)-enzyme's specific activity. Molecular weight analysis on the wild-type and mutant deaminases using HPLC size exclusion chromatography revealed that the wild-type deaminase was basically a hexamer, particularly in the presence of dCTP, regardless of the extent of dilution. Under similar conditions, R115E remained a dimer, whereas R115Q and F112A varied from hexamers to dimers particularly at concentrations normally present in the assay solution. Activity measurements appear to support the conclusion that the hexameric form of the enzyme is activated by dCTP, while the dimer is not. Another feature emphasizing the difference between the WT and mutant deaminases was observed on their denaturation-renaturation in EDTA, which revealed the mutants to be restored to 50% of their original activities with the WT deaminase only marginally restored.     

Proteus mirabilis amino acid deaminase: cloning, nucleotide sequence, and characterization of aad.

Proteus, Providencia, and Morganella species produce deaminases that generate alpha-keto acids from amino acids. The alpha-keto acid products are detected by the formation of colored iron complexes, raising the possibility that the enzyme functions to secure iron for these species, which do not produce traditional siderophores. A gene encoding an amino acid deaminase of uropathogenic Proteus mirabilis was identified by screening a genomic library hosted in Escherichia coli DH5 alpha for amino acid deaminase activity. The deaminase gene, localized on a cosmid clone by subcloning and Tn5::751 mutagenesis, was subjected to nucleotide sequencing. A single open reading frame, designated aad (amino acid deaminase), which appears to be both necessary and sufficient for deaminase activity, predicts a 473-amino-acid polypeptide (51,151 Da) encoded within an area mapped by transposon mutagenesis. The predicted amino acid sequence of Aad did not share significant amino acid sequence similarity with any other polypeptide in the PIR or SwissProt database. Amino acid deaminase activity in both P. mirabilis and E. coli transformed with aad-encoding plasmids was not affected by medium iron concentration or expression of genes in multicopy in fur, cya, or crp E. coli backgrounds. Enzyme expression was negatively affected by growth with glucose or glycerol as the sole carbon source but was not consistent with catabolite repression.     

Isolation, sequence, and expression in Escherichia coli of the Pseudomonas sp. strain ACP gene encoding 1-aminocyclopropane-1-carboxylate deaminase.

Pseudomonas sp. strain ACP is capable of growth on 1-aminocyclopropane-1-carboxylate (ACC) as a nitrogen source owing to induction of the enzyme ACC deaminase and the subsequent conversion of ACC to alpha-ketobutyrate and ammonia (M. Honma, Agric. Biol. Chem. 49:567-571, 1985). The complete amino acid sequence of purified ACC deaminase was determined, and the sequence information was used to clone the ACC deaminase gene from a 6-kb EcoRI fragment of Pseudomonas sp. strain ACP DNA. DNA sequence analysis of an EcoRI-PstI subclone demonstrated an open reading frame (ORF) encoding a polypeptide with a deduced amino acid sequence identical to the protein sequence determined chemically and a predicted molecular mass of 36,674 Da. The ORF also contained an additional 72 bp of upstream sequence not predicted by the amino acid sequence. Escherichia coli minicells containing the 6-kb clone expressed a major polypeptide of the size expected for ACC deaminase which was reactive with ACC deaminase antiserum. Furthermore, a lacZ fusion with the ACC deaminase ORF resulted in the expression of active enzyme in E. coli. ACC is a key intermediate in the biosynthesis of ethylene in plants, and the use of the ACC deaminase gene to manipulate this pathway is discussed.     

Morphogenesis of the long tail fibers of bacteriophage T2 involves proteolytic processing of the polypeptide (gene product 37) constituting the distal part of the fiber

Gene 37 of phage T2 codes for a protein that, as a dimer, constitutes the most distal, receptor-recognizing part of its long tail fibers. It was found that, from a plasmid carrying a fragment of gene 37 that lacked a region of the gene encoding 87 CO2H-terminal amino acid residues, a protein was expressed that was slightly larger than that present in the phage. This size difference could not be accounted for. The missing region of gene 37 and also gene 38 (which codes for the auxiliary protein required for dimerization of protein 37) were cloned. Plasmids were constructed with gene 37, or gene 37 together with gene 38, under inducible control. Independent of the presence of the latter gene, a protein was produced that had the same size as protein 37 in the phage. A pulse-chase experiment revealed that a precursor of protein 37 is synthesized and processed such that approximately 120 amino acid residues, most likely CO2H-terminal, are removed. Therefore, the protein produced from the truncated gene was larger because it cannot be processed. This fact also solved an old puzzle: an amber fragment of protein 37 of phage T2 had been found to be larger than the mature protein. The amber codon could be located 24 codons away from the normal stop codon. Obviously, the fragment cannot be processed. The existence of this fragment demonstrates that processing occurs during phage maturation.     

Molecular cloning, sequencing, and mapping of the bacteriophage T2 dam gene.

Bacteriophage T2 codes for a DNA-(adenine-N6)methyltransferase (Dam), which is able to methylate both cytosine- and hydroxymethylcytosine-containing DNAs to a greater extent than the corresponding methyltransferase encoded by bacteriophage T4. We have cloned and sequenced the T2 dam gene and compared it with the T4 dam gene. In the Dam coding region, there are 22 nucleotide differences, 4 of which result in three coding differences (2 are in the same codon). Two of the amino acid alterations are located in a region of homology that is shared by T2 and T4 Dam, Escherichia coli Dam, and the modification enzyme of Streptococcus pneumoniae, all of which methylate the sequence 5' GATC 3'. The T2 dam and T4 dam promoters are not identical and appear to have slightly different efficiencies; when fused to the E. coli lacZ gene, the T4 promoter produces about twofold more beta-galactosidase activity than does the T2 promoter. In our first attempt to isolate T2 dam, a truncated gene was cloned on a 1.67-kilobase XbaI fragment. This construct produces a chimeric protein composed of the first 163 amino acids of T2 Dam followed by 83 amino acids coded by the pUC18 vector. Surprisingly, the chimera has Dam activity, but only on cytosine-containing DNA. Genetic and physical analyses place the T2 dam gene at the same respective map location as the T4 dam gene. However, relative to T4, T2 contains an insertion of 536 base pairs 5' to the dam gene. Southern blot hybridization and computer analysis failed to reveal any homology between this insert and either T4 or E. coli DNA.     

Gene 67, a new,essential bacteriophage T4 head gene codes for a prehead core component,PIP: I. Genetic mapping and DNA sequence

A new bacteriophage T4 gene has been identified and located between genes 20 and 21. This gene codes for PIP, a component of the prehead core and precursor to one of the two species of small, acidic peptides found inside the mature phage head. We have determined the DNA sequence of the gene. Both the DNA sequence and the amino acid sequence derived from it are unusual, and between them explain why suppressor-sensitive mutations in the gene have not been found using classical mutagenesis. The codon usage in this gene is highly non-random. In the accompanying paper we show that PIP is essential for T4 growth and assign its gene a number. 67, to indicate that fact.     

Genetic and Immunological Studies of Bacteriophage T4 Thymidylate Synthetase

Thymidylate synthetase, which appears after infection of Escherichia coli with bacteriophage T4, has been partially purified. The phage enzyme is immunologically distinct from the host enzyme and has a molecular weight of 50,000 in comparison to 68,000 for the host enzyme. A system has been developed to characterize T4 td mutants previously known to have impaired expression of phage thymidylate synthetase. For this system, an E. coli host lacking thymidylate synthetase was isolated. Known genetic suppressors were transduced into this host. The resulting isogenic hosts were infected with phage T4 td mutants. The specific activities and amounts of cross-reacting material induced by several different types of phage mutants under conditions of suppression or non-suppression have been examined. The results show that the phage carries the structural gene specifying the thymidylate synthetase which appears after phage infection, and that the combination of plaque morphology, enzyme activity assays, and an assay for immunologically cross-reacting material provides a means for identifying true amber mutants of the phage gene.