Complex of bacteriophage M13 single-stranded DNA and gene 5 protein

Lysates of bacteriophage M13-infected cells contain numerous unbranched filamentous structures approximately 1·1 μm long × 160 Å wide, that is, slightly longer and considerably wider than M13 virions. These structures are complexes of viral single-stranded DNA molecules with M13 gene 5 protein, a non-capsid protein required for single-stranded DNA production. All, or nearly all, of the single-stranded DNA from the infected cells and at least half to two-thirds of the gene 5 protein molecules are found as complex in the lysates. The complex contains about 1300 gene 5 protein molecules per DNA molecule but little if any of the two known capsid proteins. The complex is much less stable than virions in the presence of salt or ionic detergent solutions and in electron micrographs it appears to have a much looser and more open structure. If an excess of M13 single-stranded DNA is added to complex in a lysate, the gene 5 protein molecules from the complex redistribute onto all of the added as well as the original DNA, again suggesting a rather loose association of protein and DNA.By electron microscopy, the complex from infected cells appears to differ structurally from complex formed in vitro between purified single-stranded DNA and purified gene 5 protein. Because of this apparent structural difference and because previous experiments suggested the presence of complex in vivo, we presume that the complex which we have found in lysates of infected cells previously did exist as such inside the cells, but we have been unable to exclude that it formed during or after lysis. If it is assumed that complex does occur in vivo, the results of pulse-chase radioactive labeling experiments on infected cells can be interpreted as showing that with time the single-stranded DNA leaves complex, presumably to be matured into virions, while the gene 5 protein molecules are re-used to form more complex.     

A fast and simple method for sequencing DNA cloned in the single-stranded bacteriophage M13.

The chain termination DNA sequencing procedure of Sanger et al. (1977) requires single-stranded DNA as template. M13 phage DNA exists as a single strand and therefore every DNA sequence cloned in M13 can be easily obtained in this form. Here we show that M13 single-stranded DNA pure enough to be used as a template for sequence determination can be prepared by simple centrifugation of the phage particle and extraction with phenol.     

Solution hybridization of crosslinkable DNA oligonucleotides to bacteriophage M13 DNA. Effect of secondary structure on hybridization kinetics and equilibria

Several DNA oligonucleotides have been photochemically modified with the furocoumarin 4'-hydroxymethyl-4,5',8-trimethylpsoralen (HMT) such that each contained a single HMT furan side monoadduct to thymidine at a unique 5' TpA 3' sequence. When these oligonucleotides were hybridized to their respective complements, the HMT adduct could be driven to form an interstrand crosslink by irradiation of the hybrid with 360 nm light. The ability to crosslink probe-target complexes has allowed us to determine the kinetics and the extent of hybridization in solution between these oligonucleotides and their complementary sequences in single-stranded bacteriophage M13 DNA. Our data indicate that these parameters are strongly influenced by the existence of local as well as global secondary structure in the viral DNA. During hybridization, rearrangement of this secondary structure so as to expose the target sequence can be rate-limiting. Upon attainment of equilibrium, only a portion of the target sequence may be hybridized to the probe with the remainder involved in intrastrand base-pairing. Using crosslinkable oligonucleotide probes hybridized and irradiated near the melting temperature of the respective probe-target complex one can partially overcome these secondary structure effects.     

Electron microscopic studies of bacteriophage M13 DNA replication.

Intracellular forms of M13 phage DNA isolated after infection of Escherichia coli with wild-type phage have been studied by electron microscopy and ultracentrifugation. The data indicate the involvement of rolling-circle intermediates in single-stranded DNA synthesis. In addition to single-stranded circular DNA, we observed covalently closed and nicked replicative-form (RF) DNAs, dimer RF DNAs, concatenated RF DNAs, RF DNAs with single-stranded tails (theta, rolling circles), and, occasionally, RF DNAs with theta structures. The tails in theta molecules are always single stranded and are never longer than the DNA from mature phage; the proportion of theta to other RF molecules does not change significantly with time after infection. The origin of single-stranded DNA synthesis has been mapped by electron microscopy at a unique location on RF DNA by use of partial denaturation mapping and restriction endonuclease digestion. This location is between gene IV and gene II, and synthesis proceeds in a counterclockwise direction on the conventional genetic map.     

Replication of bacteriophage M13. 8. Differential effects of rifampicin and nalidixic acid on the synthesis of the two strands of M13 duplex DNA

Replication of bacteriophage M13 replicative forms is inhibited by rifampicin, an antibiotic that specifically inhibits the Escherichia coli RNA polymerase, and by nalidixic acid, an inhibitor of phage and bacterial DNA replication. Synthesis of the M13 complementary strand during RF³ replication was at least tenfold more sensitive to inhibition by rifampicin and by nalidixic acid than was that of the viral strand. Since M13 complementary strand synthesis is relatively insensitive to chloramphenicol, an inhibitor of protein synthesis, its inhibition by rifampicin suggests that complementary strands are initiated during RF replication by an RNA priming mechanism similar to that involved in parental RF formation. The nalidixic acid-sensitivity of complementary strand synthesis during RF replication clearly distinguishes this process from the nalidixic acid-resistant formation of the parental complementary strand in the conversion of the infecting single strand to RF.Production of progeny viral strands is indirectly affected by rifampiein in two ways. It prevents the conversion of supercoiled RF (RFI) to the open form (RFII), an essential step both in RF replication and in single-strand synthesis. In addition, rifampiein interferes with the expression of gene 5, an M13 gene function required for the accumulation of progeny viral strands.     

Single-stranded DNA binding protein and DNA helicase of bacteriophage T7 mediate homologous DNA strand exchange.

Two proteins encoded by bacteriophage T7, the gene 2.5 single-stranded DNA binding protein and the gene 4 helicase, mediate homologous DNA strand exchange. Gene 2.5 protein stimulates homologous base pairing of two DNA molecules containing complementary single-stranded regions. The formation of a joint molecule consisting of circular, single-stranded M13 DNA, annealed to homologous linear, duplex DNA having 3'- or 5'-single-stranded termini of approximately 100 nucleotides requires stoichiometric amounts of gene 2.5 protein. In the presence of gene 4 helicase, strand transfer proceeds at a rate of > 120 nucleotides/s in a polar 5' to 3' direction with respect to the invading strand, resulting in the production of circular duplex M13 DNA. Strand transfer is coupled to the hydrolysis of a nucleoside 5'-triphosphate. The reaction is dependent on specific interactions between gene 2.5 protein and gene 4 protein.     

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.     

Methylglyoxal, an endogenous aldehyde, crosslinks DNA polymerase and the substrate DNA

Methylglyoxal, a known endogenous and environmental mutagen, is a reactive α-ketoaldehyde that can modify both DNA and proteins. To investigate the possibility that methylglyoxal induces a crosslink between DNA and DNA polymerase, we treated a ‘primed template’ DNA and the exonuclease-deficient Klenow fragment (KF^exo–) of DNA polymerase I with methylglyoxal in vitro. When the reaction mixtures were analyzed by SDS–PAGE, we found that methylglyoxal induced a DNA–KF^exo– crosslink. The specific binding complex of KF^exo– and ‘primed template’ DNA was necessary for formation of the DNA–KF^exo– crosslink. Methylglyoxal reacted with guanine residues in the single-stranded portion of the template DNA. When 2′-deoxyguanosine was incubated with Nα-acetyllysine or N-acetylcysteine in the presence of methylglyoxal, a crosslinked product was formed. No other amino acid derivatives tested could generate a crosslinked product. These results suggest that methylglyoxal crosslinks a guanine residue of the substrate DNA and lysine and cysteine residues near the binding site of the DNA polymerase during DNA synthesis and that DNA replication is severely inhibited by the methylglyoxal-induced DNA–DNA polymerase crosslink.     

Selection and characterization of randomly produced mutants of gene V protein of bacteriophage M13.

Gene V protein of bacteriophage Ff (M13, f1, fd) is a master regulator of phage DNA replication and phage mRNA translation. It exerts these two functions by binding to single-stranded viral DNA or to specific sequences in the 5' ends of its target mRNAs, respectively. To study the structure/function relationship of gene V protein, M13 gene V was inserted in a phagemid expression vector and a library of missense and nonsense mutants was constructed by random chemical mutagenesis. Phagemids encoding gene V proteins with decreased biological activities were selected and the nucleotide sequences of their gene V fragments were determined. Furthermore, the mutant proteins were characterized both with respect to their ability to inhibit the production of phagemid DNA transducing particles and their ability to repress the translation of a chimeric lacZ reporter gene whose expression is controlled by the promoter and translational initiation signals of M13 gene II. From the data obtained, it can be deduced that the mechanism by which gene V protein binds to single-stranded DNA differs from the mechanism by which it binds to its target sequence in the gene II mRNA.     

Fluorescence studies of the complex formation between the gene 5 protein of bacteriophage M13 and polynucleotides

The binding characteristics of the interaction of gene 5 protein with polynucleotides, i.e. poly(dA), poly(dT) and M13 DNA, have been determined by following the quenching of the protein fluorescence. In general, the binding is highly co-operative and for the binding of the protein to poly(dA) and M13 DNA the co-operativity parameter ω is estimated to have values between 50 and 300. Under comparable experimental conditions, the intrinsic binding constant K_int is at least two orders of magnitude higher for poly(dT) than for poly(dA), while the value for M13 DNA is intermediate. For poly(dA), the binding has been studied as a function of ionic strength and temperature. From these experiments it can be concluded that ionic interactions as well as van der Waals interactions (e.g. stacking interactions) are important for the complex formation of the protein with polynucleotides. From a comparison of the binding of the protein to poly(dA) and poly(dT), it is concluded that stacking interactions in the polynucleotide have a negative influence on protein binding. This conclusion, in conjunction with the weak temperature dependence of K_int. indicates that ionic interactions play a major role in the stabilization of the protein-poly(dA) complex. The co-operativity factor ω is little or not dependent on the ionic strength or the type of polynucleotide involved in binding. It is determined by interactions between complexed protein molecules. These interactions are primarily non-electrostatic.The binding characteristics obtained for the gene 5 protein-polynucleotide complexes are compared with those we have found for the binding to small oligonucleotides. It appears that oligonucleotide and polynucleotide binding differ in many aspects; i.e. there is a difference in K_int, ω and the number of nucleotides covered. The validity of linear lattice binding theories is discussed in this context. By comparing the binding parameters found for the gene 5 protein with those of the Escherichia coli DNA binding protein I. it is possible to explain the displacement of the E. coli protein by the gene 5 protein that occurs in vivo.     

Mutability of bacteriophage M13 by ultraviolet light: Role of pyrimidine dimers

Summary The role of pyrimidine dimers in mutagenesis by ultraviolet light was examined by measuring the UV-induced reversion of six different bacteriophage M13 amber mutants for which the neighboring DNA sequences are known. The mutational response at amber (TAG) codons preceded by a guanine or adenine (where no pyrimidine dimer can be formed) were compared with those preceded by thymine or cytosine (where dimer formation is possible). Equivalent levels of UV-induced mutagenesis were observed at both kinds of sites. This observation demonstrates that there is no requirement for a pyrimidine dimer directly at the site of UV-induced mutation in this single-stranded DNA phage. UV irradiation of the phage was also performed in the presence of Ag⁺ ions, which specifically sensitize the DNA to dimer formation. The two methods of irradiation, when compared at equal survival levels (and presumably equal dimer frequencies), produced equivalent frequencies of reversion of the amber phage. We believe these results indicate that while the presence of pyrimidine dimers may be a prerequisite for UV mutagenesis, the actual mutagenic event can occur at a site some distance removed from a dimer.     

Cloning of a functional replication origin of phage G4 into the genome of phage M13.

A chimeric single-stranded DNA phage, M13Gori1, has been formed as a result of the in vitro insertion of a 2216 base-pair HaeII fragment of bacteriophage G4 replicative form DNA into the replicative form DNA of bacteriophage M13. The inserted G4 DNA carries the dnaG-dependent origin for G4 complementary strand synthesis. The cloned G4 origin functions both in vivo and in vitro in the conversion of M13Gori1 single-stranded viral DNA to the duplex replicative form by a rifampicin-resistant mechanism. Labelling of the 3′ terminus of the single discontinuity in M13Gori1 replicative form II molecules synthesized in crude extracts and subsequent restriction analysis indicate that M13Gori1 complementary strand synthesis can be initiated at either the RNA polymeraseprimed M13 origin or at the dnaG-primed G4 origin. The M13Gori1 complementary strand initiated at the G4 origin terminates in the vicinity of the G4 origin after progressing around the circular template and traversing the M13 origin region, indicating the absence of a specific nucleotide sequence in the M13 origin for termination of the newly formed complementary strand. The ability of this chimeric phage to utilize the cloned G4 origin in vivo even in the presence of the presumed M13 pilot protein (gene 3 protein) indicate that the nucleotide sequence of the replication origin is sufficient for recognizing the appropriate initiation enzymes. Since decapsidation of M13 is tightly coupled to replicative form formation, initiation at the G4 origin, located over 1000 nucleotides from the M13 complementary strand origin, indicates that widely separated nucleotide sequences contained in the filamentous virion can be exposed to the cell cytoplasm during eclipse.     

Complex between single-stranded DNA and gene 5 protein of bacteriophage M13 studied with linear dichroism and ultraviolet absorption

We have studied complexes between the gene 5 protein (gp5) of bacteriophage M13 and various polynucleotides, including single-stranded DNA, using ultraviolet absorption and linear dichroism. Upon complex formation the absorption spectra of both the protein and the polynucleotides change. The protein absorption changes indicate that for at least two of the five tyrosine residues per protein monomer the environment becomes less polar upon binding to the polynucleotides but also to the oligonucleotide p(dT)8. All gp5-polynucleotide complexes give rise to intense linear dichroism spectra. These spectra are dominated by negative contributions from the bases, but also a small positive dichroism of the protein can be discerned. The spectra can be explained by polynucleotide structures, which are the same in all complexes. The base orientations are characterized by a substantial inclination and propellor twist. The number of possible combinations of inclination and propeller twist values, which are in agreement with the linear dichroism results, is rather limited. The base orientations with respect to the complex axis are essentially different from those in the complex with the single-stranded DNA-binding protein gp32 of bacteriophage T4.     

Nucleotide-dependent binding of the gene 4 protein of bacteriophage T7 to single-stranded DNA

The gene 4 protein of bacteriophage T7 is a multifunctional enzyme that catalyzes (i) the hydrolysis of nucleoside 5'-triphosphates, (ii) the synthesis of tetraribonucleotide primers at specific recognition sequences on a DNA template, and (iii) the unwinding of duplex DNA. All three activities depend on binding of gene 4 protein to single-stranded DNA followed by unidirectional 5' to 3' translocation of the protein (Tabor, S., and Richardson, C. C. (1981) Proc. Natl. Acad. Sci. U.S.A. 78, 205-209). Binding of gene 4 protein to single-stranded DNA, assayed by retention of DNA-protein complexes on nitrocellulose filters, is random with regard to DNA sequence. Although gene 4 protein does not bind to duplex DNAs, the presence of a 240-nucleotide-long single-stranded tail on a 7200-base pair duplex DNA molecule is sufficient for gene 4 protein to cause retention of the DNA on a filter. The binding reaction requires, in addition to MgCl2, the presence of a nucleoside 5'-triphosphate, but binding is not dependent on hydrolysis; nucleoside 5'-diphosphate will substitute for nucleoside 5'-triphosphate. Of the eight common nucleoside triphosphates, dTTP promotes optimal binding. The half-life of the gene 4 protein-DNA complex depends on both the secondary structure of the DNA and on whether or not the nucleoside 5'-triphosphate cofactor can be hydrolyzed. Using the nonhydrolyzable nucleoside 5'-triphosphate analog, beta,gamma-methylene dTTP, the half-life of the gene 4 protein-DNA complex is greater than 80 min. In the presence of the hydrolyzable nucleoside 5'-triphosphate, dTTP, the half-life of the gene 4 protein-DNA complex using circular M13 DNA is at least 4 times longer than that observed using linear M13 DNA.     

Replication of bacteriophage M13: XIII. Structure and replication of cloned M13 miniphage

Restriction analysis of the duplex replicative forms of four cloned M13 miniphage indicates that all species examined contain a single copy of the intergenic space between genes II and IV plus one or more copies of a portion of the genome extending from within gene IV to a site in the HaeIII G fragment within the intergenic space. Both the viral and the complementary strand origins of replication have been localized previously within the 160 base-pair HaeIII G fragment. Since reiteration of a portion of the HaeIII G fragment could possibly lead to phages having multiple copies of the origin of replication, we have determined the location of the viral strand origin-terminus in M13 miniphage by mapping the position of the discontinuity(ies) in mini-RFII³ molecules isolated during asymmetric viral strand synthesis. Limited repair of late life-cycle mini-RFII molecules with DNA polymerase I in the presence of labeled deoxynucleoside triphosphates followed by restriction analysis demonstrates that the discontinuity in the RFII is contained at a unique site within the single HaeIII G fragment. The absence of a discontinuity in the reiterated DNA sequence containing only a portion of the HaeIII G fragment indicates that the reiterations of the origin region do not include the entire sequence specifying the viral strand origin-terminus.     

Plasmid-controlled variation in the content of methylated bases in single-stranded DNA bacteriophages M13 and fd

The N⁶-methyladenine and 5-methylcytosine contents in the DNA of bacteriophages M13 and fd have been analyzed. The results are summarized as follows. (1) After growth in bacteria harboring the N-3ft^? drug resistance-factor, fd and M13 are observed to contain approximately 1 to 2 more 5-methylcytosine residues per DNA molecule than after growth in the parental drug-sensitive host; no effect on the N⁶-methyladenine content is produced by the plasmid. (2) After growth in bacteria harboring P1 prophage, fd and M13 are observed to contain approximately 2 to 3 more N⁶-methyladenine residues per DNA molecule than after growth in the parental P1-sensitive host; no apparent effect on the 5-methylcytosine content was produced by the P1 plasmid. (3) In agreement with others, fd carrying B-host specificity (fd·B) is observed to contain 2 more N⁶-methyladenine residues/DNA molecule than fd·K.     

A clear-plaque mutation of bacteriophage M13 affects the regulation of viral DNA synthesis.

A clear-plaque mutation (c2) of bacteriophage M13 has been shown to affect the regulation of viral DNA synthesis. This mutation increases the amount of the duplex replicative form DNA per cell while decreasing the synthesis of viral single strands. The relative synthesis of the M13 gene 5 protein is approximately half that observed in wild-type infections, suggesting that the effect of the c2 mutation on the regulation of viral DNA synthesis is a result of reduced expression of gene 5.