Control of bacteriophage T4 DNA polymerase synthesis

Nucleotide-sequence-specific and non-specific interactions of T4 DNA polymerase with its own mRNA

The DNA-binding DNA polymerase (gp43) of phage T4 is also an RNA-binding protein that represses translation of its own mRNA. Previous studies implicated two segments of the untranslated 5'-leader of the mRNA in repressor binding, an RNA hairpin structure and the adjacent RNA to the 3' side, which contains the Shine-Dalgarno sequence. Here, we show by in vitro gp43-RNA binding assays that both translated and untranslated segments of the mRNA contribute to the high affinity of gp43 to its mRNA target (translational operator), but that a Shine-Dalgarno sequence is not required for specificity. Nucleotide sequence specificity appears to reside solely in the operator's hairpin structure, which lies outside the putative ribosome-binding site of the mRNA. In the operator region external to the hairpin, RNA length rather than sequence is the important determinant of the high binding affinity to the protein. Two aspects of the RNA hairpin determine specificity, restricted arrangement of purine relative to pyrimidine residues and an invariant 5'-AC-3' in the unpaired (loop) segment of the RNA structure. We propose a generalized structure for the hairpin that encompasses these features and discuss possible relationships between RNA binding determinants of gp43 and DNA binding by this replication enzyme.

NMR structure of a bacteriophage T4 RNA hairpin involved in translational repression

A high-resolution structure of a 16-nucleotide bacteriophage T4 RNA hairpin, 5'-GCCU[AAUAACUC]GGGC (loop bases in square brackets), has been determined in solution by proton, phosphorus, and carbon (natural abundance) NMR spectroscopy. This RNA hairpin is known to play a crucial role in the translational repression of bacteriophage T4 DNA polymerase. Ultraviolet absorbance melting curves indicate that the structure formed is unimolecular. The NMR spectra indicate that a single conformation consistent with a hairpin structure is formed. Strong imino-imino NOEs confirm the formation of the G.U base pair at the stem-loop junction. There is no evidence that A5 is protonated (at pH 6.0) and involved in an A+.C pair. However, the NMR data indicate that the stem is extended beyond the G.U pair and that A-form stacking continues for three nucleotides on the 5' side and one nucleotide on the 3' side. Structure calculations using restraints obtained from NMR data give a precisely defined structure with an average root mean square deviation (RMSD) of approximately 1.2 A for the entire molecule. The assignment of all the protons and most of the 31P resonances in the loop yielded a large number of distance and torsion angle restraints for these nucleotides. These helped obtain a well-defined loop with an average RMSD of 1.1 A for the loop nucleotides of 11 converged structures.

Autogenous translational operator recognized by bacteriophage T4 DNA polymerase

The synthesis of the DNA polymerase of bacteriophage T4 is autogenously regulated. This protein (gp43), the product of gene 43, binds to a segment of its mRNA that overlaps its ribosome binding site, and thereby blocks translation. We have determined the Kd of the gp43-operator interaction to be 1.0 x 10(-9) M. The minimum operator sequence to which gp43 binds consists of 36 nucleotides that include a hairpin (containing a 5 base-pair helix and an 8 nucleotide loop) and a single-stranded segment that contains the Shine-Dalgarno sequence of the ribosome binding site. In the distantly related bacteriophage RB69 there is a remarkable conservation of this hairpin and loop sequence at the ribosome binding site of its DNA polymerase gene. We have constructed phage operator mutants that overproduce gp43 in vivo, yet are unchanged for in vivo replication rates and phage yield. We present data that show that the replicative and autoregulatory functions are mutually exclusive activities of this polymerase, and suggest a model for gp43 synthesis that links autoregulation to replicative demand.

Transcriptional activation of bacteriophage T4 middle promoters by the motA protein

Transcriptional activation of middle genes in bacteriophage T4 requires the phage-encoded motA protein. Many middle genes are involved in deoxyribonucleotide biosynthesis and phage DNA replication. In the absence of motA, the gene products that are required for DNA synthesis are transcribed from other, upstream promoters. Using primer extension sequencing on RNA templates isolated from T4 motA+ and motA- infected cells, we have characterized 14 motA-dependent transcripts. The T4 middle promoters have a consensus sequence of nine base-pairs, (a/t)(a/t)TGCTT(t/c)A, spaced 11 to 13 nucleotides away from the Escherichia coli--10 consensus sequence, TAnnnT. The motA protein also can act as a transcriptional repressor for at least one early gene. Furthermore, the phage-encoded motA protein can activate in trans a middle promoter resident on a plasmid.

Cloning and expression of T4 DNA polymerase

The structural gene coding for bacteriophage T4 DNA polymerase (gene 43) has been cloned into inducible plasmid vectors, which provide a source for obtaining large amounts of this enzyme after induction. The T4 DNA polymerase produced in this fashion was purified by an innovative three-step procedure and was fully active.

Bacteriophage T7 DNA polymerase: cloning and high-level expression

Phage T7 DNA polymerase consists of a 1:1 complex of the viral T7 gene 5 protein and the host cell thioredoxin. A 3.25-kilobase T7 DNA fragment containing the complete coding sequence of gene 5, and the nearby genes 4.7 and 5.3, was cloned in the BamHI site of the plasmid pBR322. Transformation of the thioredoxin-negative (trxA-) Escherichia coli strain BH215 with the recombinant plasmid pRS101 resulted in large overproduction of gene 5 protein corresponding to a level about 60-fold higher than in T7-infected cells. Transcription of gene 5 probably originates from a previously unknown E. coli RNA polymerase promoter located immediately upstream of the structural gene. Contrary to expectation, pRS101 could be maintained also in E. coli trxA+ cells despite the in vivo formation of active T7 DNA polymerase. However, the expression of gene 5 was lower by a factor of 5-10 than in trxA- cells. Since the plasmid copy number in the two strains was the same, a gene dosage effect can be excluded. The observed difference suggests an autoregulatory interaction of T7 DNA polymerase holoenzyme on the expression of T7 gene 5. The trxA- strain BH215/pRS101 is an excellent source of gene 5 protein and T7 DNA polymerase. After in vitro reconstitution of holoenzyme by addition of excess thioredoxin, highly active T7 DNA polymerase was purified to homogeneity by a simple antithioredoxin immunoadsorbent chromatography technique.

New control elements of bacteriophage T4 pre-replicative transcription

Bacteriophage T4 pre-replicative genes are transcribed, by Escherichia coli RNA polymerase, in two alternative modes: an early mode and a middle mode. Middle mode transcription is under the control of at least one viral protein, pmotA. We have identified two additional viral genes, motB and motC, that map in the dispensable region of the T4 genome, between genes 39 and 56. pmotB and pmotC are diffusible factors which provide an alternative to the motA dependent mode of middle transcription of many T4 genes. Deletions of motB and motC are in fact lethal only in combination with a motA mutant. motB controls one of the alternative modes of transcription of the rIIA gene. When motA or motB are missing, transcription of rIIA is quantitatively unaffected; when both are missing the transcription rate drops by about 75%. Control of transcription of the tRNA gene cluster is more complex. Transcription of subcluster 2 is maximally reduced (70%) only by deletions that, besides motB, cut out an adjacent region. We guess that this adjacent region codes for an additional control element, which we call motC. The motB gene is situated in a 750-base region between the left end-points of del(39-56)-1 and -4.

The replication of bacteriophage f1: gene V protein regulates the synthesis of gene II protein

Two filamentous phage gene products are required for the replication of phage DNA. One of these, the gene II protein, is a site-specific endonuclease required for all phage-specific DNA synthesis. The other, the gene V protein, is a single-stranded DNA-binding protein required only for single-strand synthesis. Purified gene V protein, when added to an in vitro protein synthesizing system programmed by f1 DNA, specifically inhibits the synthesis of gene II protein. Inhibition seems to be translational, since synthesis of gene II protein from an RNA template is also inhibited by gene V protein. Gene V protein control of gene II expression can account for the regulation of the level of expression of the filamentous phage genome.

Inhibitor studies of phage T4 wild-type and mutant DNA polymerases. V. A. summary of kinetic and inhibitor data

The DNA polymerases of phage T4 wild-type, the mutator mutant L98 and the antimutator mutant CB121 were purified about 100-fold free of foreign enzyme activities interfering with the polymerase assay. The enzymes were characterized as to thermostability, exonuclease activity and kinetic data with DNA template primer, deoxythymidine 5' -triphosphate, and a mixture of all four deoxynucleoside 5' -triphosphates. The effects of eight inhibitors of DNA synthesis on the three enzymes were determined (Schroeder and Jantschak 1978 and 1980, Jantschak and Schroeder 1980) and are compared here. The most selective inhibitor, pyridoxal 5' -phosphate, interacts with the active site of the polymerases while the two least discriminating drugs, distamycin A and actinomycin D, do not directly interact with the polymerases at all. The study was intended to test whether specific enzyme inhibitors elicit a differential response in temperature-sensitive structural variants of this enzyme and whether, in principle, structural variants of virus enzymes or the respective ts- mutants in vivo are suitable as a screening system for selective antiviral agents.

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.

Surface changes in differentiating Friend erythroleukemic cells in culture

The sensitivity to agglutination by several plant lectins has been studied during the induced erythroid differentiation of Friend erythroleukemic cells in culture. In addition, the number of lectin receptors on the cell has been measured. It is shown that early during the differentiation, there is an increase in agglutinability while the receptor density remains constant. In the later phase of the differentiation process, the cells lose their sensitivity to agglutination while the receptor number and density increases. These changes were not observed on nonerythroid mastocytoma culture cells. Two nondifferentiating variants of the FL cells were shown to have altered sensitivities to agglutination by ConA.

Suppressors of gene 32 am mutants that specifically overproduce P32 (unwinding protein) in bacteriophage T4

A gene 32 amber (am) mutant, amNG364, fails to grow on Escherichia coli Su3+ high temperatures, suggesting that the tyrosine residue inserted at the am codon by Su3+ leads to a temperature-sensitive gene 32 protein (P32). By plating amNG364 on E. coli Su3+ 45 degrees C, several pseudorevertants were found that proved to contain a suppressor (su) mutant in addition to the original am mutation. Crosses of two of these amNG364su strains to am+ phage indicated that the suppressors themselves are in or close to gene 32. Phage strains carrying either of the two su mutations, without amNG364, grew normally. When cells were infected by these su mutants and the proteins produced were examined by sodium dodecyl sulfate-gel electrophroesis, specific overproduction of P32 was found. Maximum overproduction compared to am+ phage was 6.6-fold for one su mutant and 2.4-fold for the other. Other proteins were produced in normal amounts and in normal time sequence. When amNG364su phage were allowed to infect E. coli S/6/5(Su-), the gene 32 am fragments produced were present at the same derepressed levels as in an infection by amNG364 without a suppressor. The suppressor mutations are interpreted as causing derepression of P32 by altering sites in this autogenously regulated protein involved in template recognition. Previously, specific derepression of gene 32 had only been shown using gene 32 conditional lethal mutants grown under restrictive conditions. We have shown that P32 can also be derepressed under permissive conditions, indicating that loss of P32 function is not necessary for specific derepression.

The influence of mutations upon the synthesis of RNA polymerase subunits in Escherichia coli cells

The influence of mutations in structural genes of beta and beta subunits of RNA polymerase upon the synthesis of these subunits in E. coli cells have been investigated. An amber-mutation ts22 in the beta subunit gene decreases the intracellular concentration of this subunit and the rate of its synthesis. At the same time the concentration and the rate of beta subunit synthesis is increased. These suggest the compensatory activation of the RNA polymerase operon that takes place under the conditions of shortage of one of the subunits. Reversions as well as more effective suppression of ts22 amber mutation, achieved by streptomycin addition, substitution of su2 by sul, or by specific mutations, result in a rise of beta and drop of beta subunit concentration and synthesis in ts22 mutant. TsX missense-mutation in the beta subunit gene alters the properties of the enzyme increasing, at the same time, the concentration and the rate of synthesis of both beta and beta subunits, particularly at a nonpermissive temperature. This points to an inversely proportional relationship between the rate of synthesis of RNA polymerase subunits and the total intracellular activity of the enzyme. Extra subunits are rapidly degraded in ts22 and tsX mutants. The whole complex of our data and those of others suggest that the regulation of the synthesis of RNA polymerase subunits is accomplished by interaction of a negative and a positive mechanisms of regulation which include not only activators and repressors but the enzyme itself as well.

Mutants of bacteriophage T4 deficient in the ability to induce nuclear disruption: shutoff of host DNA and protein synthesis gene dosage experiments, identification of a restrictive host, and possible biological significance

The shutoff of host DNA synthesis is delayed until about 8 to 10 min after infection when Escherichia coli B/5 cells were infected with bacteriophage T4 mutants deficient in the ability to induce nuclear disruption (ndd mutants). The host DNA synthesized after infection with ndd mutants is stable in the absence of T4 endonucleases II and IV, but is unstable in the presence of these nucleases. Host protein synthesis, as indicated by the inducibility of beta-galactosidase and sodium dodecyl sulfate-polyacrylamide gel patterns of isoptopically labeled proteins synthesize after infection, is shut off normally in ndd-infected cells, even in the absence of host DNA degradation. The Cal Tech wild-type strain of E. coli CT447 was found to restrict growth of the ndd mutants. Since T4D+ also has a very low efficiency of plating on CT447, we have isolated a nitrosoguanidine-induced derivative of CT447 which yields a high T4D+ efficiency of plating while still restricting the ndd mutants. Using this derivative, CT447 T4 plq+ (for T4 plaque+), we have shown that hos DNA degradation and shutoff of host DNA synthesis occur after infection with either ndd98 X 5 (shutoff delayed) or T4D+ (shutoff normal) with approximately the same kinetics as in E. coli strain B/5. Nuclear disruption occurs after infection of CT447 with ndd+ phage, but not after infection with ndd- phage. The rate of DNA synthesis after infection of CT447 T4 plq+ with ndd98 X 5 is about 75% of the rate observed after infection with T4D+ while the burst size of ndd98 X 5 is only 3.5% of that of T4D+. The results of gene dosage experiments using the ndd restrictive host C5447 suggest that the ndd gene product is required in stoichiometric amounts. The observation by thin-section electron microscopy of two distinct pools of DNA, one apparently phage DNA and the other host DNA, in cells infected with nuclear disruption may be a compartmentalization mechanism which separates the pathways of host DNA degradation and phage DNA biosynthesis.

Autogenous regulation of gene expression

A new term, autogenous regulation, is used to describe a phenomenon that is not a new discovery but rather is newly appreciated as a mechanism common to a number of systems in both prokaryotic and eukaryotic organisms. In this mechanism the product of a structural gene regulates expression of the operon in which that structural gene resides. In many (perhaps all) cases, the regulatory gene product has several functions, since it may act not only as a regulatory protein but also as an enzyme, structural protein, or antibody, for example. In a few cases, this protein is the multimeric allosteric enzyme that catalyzes the first step of a metabolic pathway, gearing together the two most important mechanisms for controlling the biosynthesis of metabolites in bacterial cells-feedback inhibition and repression. Autogenous regulation may provide a mechanism for amplification of gene expression (84); for severe and prolonged inactivation of gene expression (85); for buffering the response of structural genes to changes in the environment (45, 52); and for maintaining a constant intracellular concentration of a protein, independent of cell size or growth rate (86). Thus, autogenous regulation provides the cell with means for accomplishing a number of different regulatory tasks, each suited to better satisfying the needs of the organism for its survival.