Identification and biosynthesis of the bacteriophage T4 mot regulatory protein.

The T4 mot gene regulates middle mode RNA synthesis in phage-infected cells. The mot gene product has been identified in two ways. (i) Infections with amber and temperature-sensitive mot mutants both lead to the disappearance of a number of protein bands on SDS-polyacrylamide gels. These are middle mode proteins whose synthesis depends on mot function. The mot protein disappears from such gels after infection with a mot amber mutant, but not with the mot missense mutant. (ii) This same protein is the only one to have a charge alteration when proteins from wild-type phage and mot missense mutant infections are compared by two-dimensional gel electrophoresis. Mot protein is basic and has a mol. wt. of 24 000. It migrates between the positions of gp 1 and gp IPIII on 15% SDS-polyacrylamide gels. Mot protein synthesis begins immediately after infection and continues until 4 min after infection at 30 degrees C, after which time it is strongly inhibited. This inhibition depends neither on T4 DNA synthesis nor on ADP ribosylation of the alpha subunits of the Escherichia coli RNA polymerase. The mot protein does not regulate its own biosynthesis. It is stable throughout the course of infection.     

Factors involved in the initiation of phage phi 29 DNA replication in vitro: requirement of the gene 2 product for the formation of the protein p3-dAMP complex.

To study the requirements for the in vitro formation of the protein p3-dAMP complex, the first step in phi29 DNA replication, extracts from B. subtilis infected with phi29 mutants in genes 2, 3, 5, 6 and 17, involved in DNA synthesis, have been used. The formation of the initiation complex is completely dependent on the presence of a functional gene 2 product, in addition to protein p3 and phi29 DNA-protein p3 as template. ATP is also required, although it can be replaced by other nucleotides. The products of genes 5, 6 and 17 do not seem to be needed in the formation of the initiation complex. Inhibitors of the host DNA polymerase III, DNA gyrase or RNA polymerase had no effect on the formation of the protein p3-dAMP complex, suggesting that these proteins are not involved in the initiation of phi29 DNA replication. ddATP or aphidicolin, inhibitors of DNA chain elongation, had also no effect on the formation of the initiation complex.     

Characterization of the DNA-dependent GTPase activity of T4 gene 41 protein, an essential component of the T4 bacteriophage DNA replication apparatus

The product specified by T4 bacteriophage gene 41 is known from genetic analyses to be essential for phage DNA replication in vivo. Correspondingly, the purified gene 41 protein is an essential component of an efficient in vitro DNA replication system reconstructed from seven purified T4 replication proteins; it is required both for the synthesis of short RNA primers (in conjunction with the T4 gene 61 protein) and for the rapid unwinding of the double-helical DNA template at a replication fork. The purified gene 41 protein exhibits a DNA-dependent GTPase (and ATPase) activity. In this report, we have used this associated GTPase activity as a biochemical probe for the analysis of the interactions between DNA and the 41 protein. Our results suggest that, upon binding GTP, the 41 protein monomer is induced to form a dimer, which can them form a tight complex with single-stranded DNA. Driven by the repeated hydrolysis of GTP molecules, the 41 protein dimer appears to run rapidly along the bound DNA chain. Studies with the synthetic GTP analogue, GTP gamma S, suggest that GTP hydrolysis is required for this 41 protein movement, but that it is not essential for the function of the 41 protein in RNA primer synthesis. In sum, our observations suggest that a 41 protein dimer runs along the lagging strand template at a DNA replication fork; from this position, it functions as a DNA helicase and simultaneously interacts with the T4 gene 61 protein to make the pentaribonucleotide primers which initiate Okazaki pieces at specific primer initiation sites.     

Effects of the bacteriophage T4 dda protein on DNA synthesis catalyzed by purified T4 replication proteins

The T4 bacteriophage dda protein is a DNA-dependent ATPase and DNA helicase that is the product of an apparently nonessential T4 gene. We have examined its effects on in vitro DNA synthesis catalyzed by a purified, multienzyme T4 DNA replication system. When DNA synthesis is catalyzed by the T4 DNA polymerase on a single-stranded DNA template, the addition of the dda protein is without effect whether or not other replication proteins are present. In contrast, on a double-stranded DNA template, where a mixture of the DNA polymerase, its accessory proteins, and the gene 32 protein is required, the dda protein greatly stimulates DNA synthesis. The dda protein exerts this effect by speeding up the rate of replication fork movement; in this respect, it acts identically with the other DNA helicase in the T4 replication system, the T4 gene 41 protein. However, whereas a 41 protein molecule remains bound to the same replication fork for a prolonged period, the dda protein seems to be continually dissociating from the replication fork and rebinding to it as the fork moves. Some gene 32 protein is required to observe DNA synthesis on a double-stranded DNA template, even in the presence of the dda protein. However, there is a direct competition between this helix-destabilizing protein and the dda protein for binding to single-stranded DNA, causing the rate of replication fork movement to decrease at a high ratio of gene 32 protein to dda protein. As shown elsewhere, the dda protein becomes absolutely required for in vitro DNA synthesis when E. coli RNA polymerase molecules are bound to the DNA template, because these molecules otherwise stop fork movement (Bedinger, P., Hochstrasser, M., Jongeneel, C.V., and Alberts, B. M. (1983) Cell 34, 115-123).     

Architecture of the replication complex and DNA loops at the fork generated by the bacteriophage t4 proteins

Rolling circle replication has previously been reconstituted in vitro using M13 duplex circles containing preformed forks and the 10 purified T4 bacteriophage replication proteins. Leading and lagging strand synthesis in these reactions is coupled and the size of the Okazaki fragments produced is typical of those generated in T4 infections. In this study the structure of the DNAs and DNA-protein complexes engaged in these in vitro reactions has been examined by electron microscopy. Following deproteinization, circular duplex templates with linear tails as great as 100 kb are observed. The tails are fully duplex except for one to three single-stranded DNA segments close to the fork. This pattern reflects Okazaki fragments stopped at different stages in their synthesis. Examination of the DNA-protein complexes in these reactions reveals M13 duplex circles in which 64% contain a single large protein mass (replication complex) and a linear duplex tail. In 56% of the replicating molecules with a tail there is at least one fully duplex loop at the replication complex resulting from the portion of the lagging strand engaged in Okazaki fragment synthesis folding back to the replisome. The single-stranded DNA segments at the fork bound by gene 32 and 59 proteins are not extended but rather appear organized into highly compact structures ("bobbins"). These bobbins constitute a major portion of the mass of the full replication complex.     

Control of Early Gene Expression of Bacteriophage T4: Involvement of the Host rho Factor and the mot Gene of the Bacteriophage

Many early mRNA species of bacteriophage T4 are not synthesized after infection of Escherichia coli in the presence of chloramphenicol. This has been interpreted as a need for T4 protein(s) to be synthesized to allow expression of some early genes, e.g., those for deoxycytidinetriphosphatase, deoxynucleosidemonophosphate kinase and UDP-glucose-DNA beta-glucosyltransferase. In the experiments described here, early mRNA of bacteriophage T4 was allowed to accumulate during chloramphenicol treatment. After the addition of rifampin to inhibit further RNA synthesis, and subsequent removal of chloramphenicol, the accumulated mRNA was permitted to express itself into measured enzyme activities. It was shown that the early mRNA species coding for deoxycytidinetriphosphatase and UDP-glucose-DNA beta-glucosyltransferase could be formed in the presence of chloramphenicol if the E. coli host cell carried a mutation in the structural gene for the RNA chain termination factor rho. This was interpreted to mean that T4 protein(s) with anti-rho activity is normally required for the expression of these two early genes. An altered rho-factor could not, however, relieve the need of phage protein synthesis for the formation of another early mRNA, that coding for deoxynucleosidemonophosphate kinase. In this case the mot gene of T4 seemed to be involved, since the primary infection of E. coli cells with the mot gene mutant tsG1 did not allow subsequent deoxynucleoside monophosphate kinase mRNA synthesis after wild-type phage infection in the presence of chloramphenicol. In control experiments, deoxynucleoside monophosphate kinase mRNA synthesis induced by wild-type phage superinfecting in the presence of chloramphenicol was facilitated by the primary infection with T4 phage containing an unmutated mot gene.     

Trypsin cleavage in the COOH terminus of the bacteriophage T4 gene 41 DNA helicase alters the primase-helicase activities of the T4 replication complex in vitro

The bacteriophage T4 gene 41 protein is a 5' to 3' DNA helicase which unwinds DNA ahead of the growing replication fork and, together with the T4 gene 61 protein, also functions as a primase to initiate DNA synthesis on the lagging strand. Proteolytic cleavage by trypsin approximately 20 amino acids from the COOH terminus of the 41 protein produces 41T, a 51,500-dalton fragment (possibly still associated with small COOH-terminal fragments) which still retains the ssDNA-stimulated GTPase (ATPase) activity, the 61 protein-stimulated DNA helicase activity, and the ability to act with 61 protein to synthesize pentaribonucleotide primers. In the absence of the T4 gene 32 ssDNA binding protein, the primase-helicase composed of the tryptic fragment (41T) and 61 proteins efficiently primes DNA synthesis on circular ssDNA templates by the T4 DNA polymerase and the three T4 polymerase accessory proteins. In contrast, the 41T protein is defective as a helicase or a primase component on 32 protein-covered DNA. Thus, unlike the intact protein, 41T does not support RNA-dependent DNA synthesis on 32 protein-covered ssDNA and does not stimulate strand displacement DNA synthesis on a nicked duplex DNA template. High concentrations of 32 protein strongly inhibit RNA primer synthesis with either 41 T or intact 41 protein. The 44/62 and 45 polymerase accessory proteins (and even the 44/62 proteins to some extent) substantially reverse the 32 protein inhibition of RNA primer synthesis with intact 41 protein but not with 41T protein. We propose that the COOH-terminal region of the 41 protein is required for its interaction with the T4 polymerase accessory proteins, permitting the synthesis and utilization of RNA primers and helicase function within the T4 replication complex. When this region is altered, as in 41T protein, the protein is unable to assemble a functional primase-helicase in the replication complex. An easy and rapid purification of T4 41 protein produced by a plasmid encoding this gene (Hinton, D. M., Silver, L. L., and Nossal, N. G. (1985) J. Biol. Chem. 260, 12851-12857) is also described.     

Precursors of the T4 internal peptides.

The precursors of the two T4 internal peptides have been identified by in vitro cleavage of individual phage proteins eluted from sodium dodecyl sulfate-acrylamide gels. The precursor of internal peptide VII is p22, the product of T4 gene 22 and an essential component of the morphogenic core. The precursor of peptide II is a protein with a molecular weight of approximately 13,000, whose gene has yet to be defined by mutation. A newly detected protein of approximately 15,000 molecular weight is found to be cleaved and is, therefore, likely to be a component of precursor head structures.     

RNA priming of DNA replication by bacteriophage T4 proteins

Bacteriophage T4 DNA replication proteins have been shown previously to require ribonucleoside triphosphates to initiator new DNA chains on unprimed single-stranded DNA templates in vitro. This DNA synthesis requires a protein controlled by T4 gene 61, as well as the T4 gene 41, 43 (DNA polymerase), 44, 45, and 62 proteins, and is stimulated by the gene 32 (helix-destabilizing) protein. In this paper, the nature of the RNA primers involved in DNA synthesis by the T4 proteins has been determined, using phi X174 and f1 DNA as model templates. The T4 41 and "61" proteins synthesize pentanucleotides with the sequence pppA-C(N)3 where N in positions 3 and 4 can be G, U, C, or A. The same group of sequences is found in the RNA at the 5' terminus of the phi X174 DNA product made by the seven T4 proteins. The DNA product chains begin at multiple discrete positions on the phi X174 DNA template. The characteristics of the T4 41 and "61" protein priming reaction are thus appropriate for a reaction required to initiate the synthesis of discontinuous "Okazaki" pieces on the lagging strand during the replication of duplex DNA.     

Eukaryotic translation initiation: there are (at least) two sides to every story

The eukaryotic cap and poly(A) tail binding proteins, eIF4E and Pab1p, play important roles in the initiation of protein synthesis. The recent structures of the complex of eIF4E bound to the methylated guanosine (cap) found at the 5'end of messenger RNA (mRNA), the complex of eIF4E bound to peptide fragments of two related translation factors (eIF4G and 4E-BP1), and the complex of the N-terminal fragment of Pab1p bound to polyadenylate RNA have revealed that eIF4E and Pab1p contain at least two distinct functional surfaces. One surface is used for binding mRNA, and the other for binding proteins involved in translation initiation.     

Interactions of the DNA polymerase and gene 4 protein of bacteriophage T7. Protein-protein and protein-DNA interactions involved in RNA-primed DNA synthesis

Three proteins catalyze RNA-primed DNA synthesis on the lagging strand side of the replication fork of bacteriophage T7. Oligoribonucleotides are synthesized by T7 gene 4 protein, which also provides helicase activity. DNA synthesis is catalyzed by gene 5 protein of the phage, and processivity of DNA synthesis is conferred by Escherichia coli thioredoxin, a protein that is tightly associated with gene 5 protein. T7 DNA polymerase and gene 4 protein associate to form a complex that can be isolated by filtration through a molecular sieve. The complex is stable in 50 mM NaCl but is dissociated by 100 mM NaCl, a salt concentration that does not inhibit RNA-primed DNA synthesis. T7 DNA polymerase forms a stable complex with single-stranded M13 DNA at 50 mM NaCl as measured by gel filtration, and this complex requires 200 mM NaCl for dissociation, a salt concentration that inhibits RNA-primed DNA synthesis. Gene 4 protein alone does not bind to single-stranded DNA. In the presence of MgCl2 and dTTP or beta, gamma-methylene dTTP, a gene 4 protein-M13 DNA complex that is stable at 200 mM NaCl is formed. The affinity of DNA polymerase for both gene 4 protein and single-stranded DNA leads to the formation of a gene 4 protein-DNA polymerase-M13 DNA complex even in the absence of nucleoside triphosphates. However, the binding of each protein to DNA plays an important role in mediating the interaction of the proteins with each other. High concentrations of single-stranded DNA inhibit RNA-primed DNA synthesis by diluting the amount of proteins bound to each template and reducing the frequency of protein-protein interactions. Preincubation of gene 4 protein, DNA polymerase, and M13 DNA in the presence of dTTP forms protein-DNA complexes that most efficiently catalyze RNA-primed DNA synthesis in the presence of excess single-stranded competitor DNA.     

Nucleotide sequence from the genetic left end of bacteriophage T7 DNA to the beginning of gene 4

The nucleotide sequence running from the genetic left end of bacteriophage T7 DNA to within the coding sequence of gene 4 is given, except for the internal coding sequence for the gene 1 protein, which has been determined elsewhere. The sequence presented contains nucleotides 1 to 3342 and 5654 to 12,100 of the approximately 40,000 base-pairs of T7 DNA. This sequence includes: the three strong early promoters and the termination site for Escherichia coli RNA polymerase: eight promoter sites for T7 RNA polymerase; six RNAase III cleavage sites; the primary origin of replication of T7 DNA; the complete coding sequences for 13 previously known T7 proteins, including the anti-restriction protein, protein kinase, DNA ligase, the gene 2 inhibitor of E. coli RNA polymerase, single-strand DNA binding protein, the gene 3 endonuclease, and lysozyme (which is actually an N-acetylmuramyl-l-alanine amidase); the complete coding sequences for eight potential new T7-coded proteins; and two apparently independent initiation sites that produce overlapping polypeptide chains of gene 4 primase. More than 86% of the first 12,100 base-pairs of T7 DNA appear to be devoted to specifying amino acid sequences for T7 proteins, and the arrangement of coding sequences and other genetic elements is very efficient. There is little overlap between coding sequences for different proteins, but junctions between adjacent coding sequences are typically close, the termination codon for one protein often overlapping the initiation codon for the next. For almost half of the potential T7 proteins, the sequence in the messenger RNA that can interact with 16 S ribosomal RNA in initiation of protein synthesis is part of the coding sequence for the preceding protein. The longest non-coding region, about 900 base-pairs, is at the left end of the DNA. The right half of this region contains the strong early promoters for E. coli RNA polymerase and the first RNAase III cleavage site. The left end contains the terminal repetition (nucleotides 1 to 160), followed by a striking array of repeated sequences (nucleotides 175 to 340) that might have some role in packaging the DNA into phage particles, and an A · T-rich region (nucleotides 356 to 492) that contains a promoter for T7 RNA polymerase, and which might function as a replication origin.     

Dissection of RNA-primed DNA synthesis catalyzed by gene 4 protein and DNA polymerase of bacteriophage T7. Coupling of RNA primer and DNA synthesis

Gene 4 protein and DNA polymerase of bacteriophage T7 catalyze RNA-primed DNA synthesis on single-stranded DNA templates. T7 DNA polymerase exhibits an affinity for both gene 4 protein and single-stranded DNA, and gene 4 protein binds stably to single-stranded DNA in the presence of dTTP (Nakai, H. and Richardson, C. C. (1986) J. Biol. Chem. 261, 15208-15216). Gene 4 protein-T7 DNA polymerase-template complexes may be formed in both the presence and absence of nucleoside 5'-triphosphates. The protein-template complexes may be isolated free of unbound proteins and nucleotides by gel filtration and will catalyze RNA-primed DNA synthesis in the presence of ATP, CTP, and the four deoxynucleoside 5'-triphosphates. RNA-primed DNA synthesis may be dissected into separate reactions for primer synthesis and DNA synthesis. Upon incubation of gene 4 protein with single-stranded DNA, ATP, and CTP, a primer-template complex is formed; it is likely that gene 4 protein mediates stable binding of the oligonucleotide to the template. The complex, purified free of unbound proteins and nucleotides, supports DNA synthesis upon addition of DNA polymerase and deoxynucleoside 5'-triphosphates. Association of primers with the template is increased by the presence of dTTP or DNA polymerase during primer synthesis. DNA synthesis supported by primer-template complexes initiates predominantly at gene 4 recognition sequences, indicating that primers are bound to the template at these sites.     

Bacteriophage T4 regA protein binds RNA as a monomer, overcoming dimer interactions.

The stoichiometry of the complex formed between the T4 translational repressor protein regA and the 16 nt gene 44 recognition element (gene 44RE) RNA has been determined. Under quantitative binding conditions, the association of wild-type regA protein with gene 44RE RNA exhibits saturation at a 1:1 ratio of protein to RNA. It is known that regA protein exists as a dimer in protein crystals. Thus, the stoichiometry may be indicative of a regA dimer bound to two RNAs or a regA monomer bound to one RNA. Gel filtration through Sephadex G-75 revealed that wild-type and R91L regA proteins (14.6 kDa) elute at a mass of 29 kDa, consistent with the mass of a dimer. However, wild-type regA preincubated with gene 44RE (1:1) resulted in a complex that eluted at approximately 20 kDa, consistent with a regA monomer-RNA complex. Covalent crosslinking of surface lysines with glutaraldehyde confirmed that wild-type and R91L proteins exist as dimers and higher oligomers in solution. However, the addition of RNA to wild-type regA protein prior to crosslinking inhibited the formation of crosslinked dimers. Thus, the regA protein-protein interactions observed in solution are disrupted or blocked in the presence of gene 44RE RNA. Together, these studies demonstrate that regA protein binds RNA as a monomer, although free protein exists predominantly as a dimer.