In vitro synthesis of bacteriophage f1 proteins

Identification of blue-green algal nitrogen fixation genes by using heterologous DNA hybridization probes

In the filamentous blue-green alga Anabaena 7120, aerobic nitrogen fixation is linked to the differentiation of specialized cells called heterocysts. In order to study control of heterocyst development and nitrogen fixation in Anabaena, we have used cloned fragments of the Klebsiella pneumoniae nitrogen fixation (nif) genes as probes in DNA.DNA hybridizations with restriction endonuclease fragments of Anabaena DNA. Using this technique, we were able to identify and clone Anabaena nif genes, demonstrating the feasibility of using heterologous probes to identify genes for which no traditional genetic selection exists. From the patterns of hybridization observed, we deduced that although DNA sequence homology has been retained between some of the nif genes of these divergent organisms, the nif gene order has been rearranged.

Identification of a region of Escherichia coli DnaB required for functional interaction with DnaG at the replication fork

The fundamental activities of the replicative primosomes of Escherichia coli are provided by DnaB, the replication fork DNA helicase, and DnaG, the Okazaki fragment primase. As we have demonstrated previously, DnaG is recruited to the replication fork via a transient protein-protein interaction with DnaB. Here, using site-directed amino acid mutagenesis, we have defined the region on DnaB required for this protein-protein interaction. Mutations in this region of DnaB affect the DnaB-DnaG interaction during both general priming-directed and phiX174 complementary strand DNA synthesis, as well as at replication forks reconstituted in rolling circle DNA replication reactions. The behavior of the purified mutant DnaB proteins in the various replication systems suggests that access to the DnaG binding pocket on DnaB may be restricted at the replication fork.

Characterization of the unique C terminus of the Escherichia coli tau DnaX protein. Monomeric C-tau binds alpha AND DnaB and can partially replace tau in reconstituted replication forks

A contact between the dimeric tau subunit within the DNA polymerase III holoenzyme and the DnaB helicase is required for replication fork propagation at physiologically-relevant rates (Kim, S., Dallmann, H. G., McHenry, C. S., and Marians, K. J. (1996) Cell 84, 643-650). In this report, we exploit the OmpT protease to generate C-tau, a protein containing only the unique C-terminal sequences of tau, free of the sequences shared with the alternative gamma frameshifting product of dnaX. We have established that C-tau is a monomer by sedimentation equilibrium and sedimentation velocity ultracentrifugation. Monomeric C-tau binds the alpha catalytic subunit of DNA polymerase III with a 1:1 stoichiometry. C-tau also binds DnaB, revealed by a coupled immunoblotting method. C-tau restores the rapid replication rate of inefficient forks reconstituted with only the gamma dnaX gene product. The acceleration of the DnaB helicase can be observed in the absence of primase, when only leading-strand replication occurs. This indicates that C-tau, bound only to the leading-strand polymerase, can trigger the conformational change necessary for DnaB to assume the fast, physiologically relevant form.

Distinct effects of the UvrD helicase on topoisomerase-quinolone-DNA ternary complexes

Quinolone antibacterial drugs target both DNA gyrase (Gyr) and topoisomerase IV (Topo IV) and form topoisomerase-quinolone-DNA ternary complexes. The formation of ternary complexes results in the inhibition of DNA replication and leads to the generation of double-strand breaks and subsequent cell death. Here, we have studied the consequences of collisions between the UvrD helicase and the ternary complexes formed with either Gyr, Topo IV, or a mutant Gyr, Gyr (A59), which does not wrap the DNA strand around itself. We show (i) that Gyr-norfloxacin (Norf)-DNA and Topo IV-Norf-DNA, but not Gyr (A59)-Norf-DNA, ternary complexes inhibit the UvrD-catalyzed strand-displacement activity, (ii) that a single-strand break is generated at small portions of the ternary complexes upon their collisions with UvrD, and (iii) that the majority of Topo IV-Norf-DNA ternary complexes become nonreversible when UvrD collides with the Topo IV-Norf-DNA ternary complexes, whereas the majority of Gyr-Norf-DNA ternary complexes remain reversible after their collision with the UvrD helicase. These results indicated that different DNA repair mechanisms might be involved in the repair of Gyr-Norf-DNA and Topo IV-Norf-DNA ternary complexes.

Purification and characterization of DnaC810, a primosomal protein capable of bypassing PriA function

Escherichia coli strains lacking PriA are severely compromised in their ability to repair UV-damaged DNA and to perform homologous recombination. These phenotypes arise because of a lack of PriA-directed replication fork assembly at recombination intermediates such as D-loops. Naturally arising suppressor mutations in dnaC restore strains carrying the priA2::kan null allele to wild-type function. We have cloned one such gene, dnaC810, and overexpressed, purified, and characterized the DnaC810 protein. DnaC810 can support a PriA-independent synthesis of phiX174 complementary strand DNA. This can be attributed to its ability, unlike wild-type DnaC, to catalyze a SSB-insensitive general priming reaction with DnaB and DnaG on any SSB-coated single-stranded DNA. Gel mobility shift analysis revealed that DnaC810 could load DnaB directly to SSB-coated single-stranded DNA as well as to D loop DNA. This explains the ability of DnaC810 to bypass the requirement for PriA, PriB, PriC, and DnaT during replication fork assembly at recombination intermediates.

Interactions between DNA helicases and frozen topoisomerase IV-quinolone-DNA ternary complexes

Collisions between replication forks and topoisomerase-drug-DNA ternary complexes result in the inhibition of DNA replication and the conversion of the normally reversible ternary complex to a nonreversible form. Ultimately, this can lead to the double strand break formation and subsequent cell death. To understand the molecular mechanisms of replication fork arrest by the ternary complexes, we have investigated molecular events during collisions between DNA helicases and topoisomerase-DNA complexes. A strand displacement assay was employed to assess the effect of topoisomerase IV (Topo IV)-norfloxacin-DNA ternary complexes on the DnaB, T7 gene 4 protein, SV40 T-antigen, and UvrD DNA helicases. The ternary complexes inhibited the strand displacement activities of these DNA helicases. Unlike replication fork arrest, however, this general inhibition of DNA helicases by Topo IV-norfloxacin-DNA ternary complexes did not require the cleavage and reunion activity of Topo IV. We also examined the reversibility of the ternary complexes after collisions with these DNA helicases. UvrD converted the ternary complex to a nonreversible form, whereas DnaB, T7 gene 4 protein, and SV40 T-antigen did not. These results suggest that the inhibition of DnaB translocation may be sufficient to arrest the replication fork progression but it is not sufficient to generate cytotoxic DNA lesion.

Filamentous phage IKe mRNAs conserve form and function despite divergence in regulatory elements

As a means of determining whether there has been selection to conserve the basic pattern of filamentous phage mRNAs, the major mRNAs representing genes II to VIII have been defined for a phage distantly related to the Ff group specific for Escherichia coli hosts bearing F pili. Phage IKe has a genome with 55% identity with the Ff genome and infects E. coli strains bearing N pili. The results reveal a remarkably similar pattern of overlapping polycistronic mRNAs with a common 3' end and unique 5' ends. The IKe mRNAs, like the Ff phage mRNAs, represent a combination of primary transcripts and processed RNAs. However, examination of the sequences containing the RNA endpoint positions revealed that effectively the only highly conserved regulatory element is the rho-independent terminator that generates the common 3' end. Promoters and processing sites have not been maintained in identical positions, but frequently are placed so as to yield RNAs with similar coding function. By conserving the pattern of transcription and processing despite divergence in the regulatory elements and possibly the requirements for host, endoribonucleases, the results argue that the pattern is not simply fortuitous.

tau couples the leading- and lagging-strand polymerases at the Escherichia coli DNA replication fork

Synthesis of an Okazaki fragment occurs once every 1 or 2 s at the Escherichia coli replication fork. To account for the rapid recycling required of the lagging-strand polymerase, it has been proposed that it is held at the replication fork by protein-protein interactions with the leading-strand polymerase as part of a dimeric polymerase assembly. Solution studies showed that the replicative polymerase, the DNA polymerase III holoenzyme, was indeed a dimer with two catalytic cores held together by the tau subunit. However, the functionality of this arrangement at the replication fork has never been demonstrated. We showed previously that the lagging-strand polymerase acted processively during multiple rounds of Okazaki fragment synthesis, i.e. the same polymerase core assembly synthesized each and every fragment made by the fork. Using extreme dilution of active replication forks and the isolation of protein-DNA complexes capable of supporting coupled leading- and lagging-strand synthesis, we demonstrate here that this coupling of leading- and lagging-strand synthesis is, in fact, mediated by the tau subunit of the holoenzyme acting as a physical bridge between the core assemblies synthesizing the leading and lagging strands.

The extreme C terminus of primase is required for interaction with DnaB at the replication fork

We have shown previously that a protein-protein interaction between DnaG and DnaB is required to attract the primase to the replication fork. This interaction was mediated by the C-terminal 16-kDa domain (p16) of the primase. A screen was developed that allowed the detection of mutant p16 proteins that did not interact with DnaB. Various mutagenesis protocols were used to localize this interaction domain to the extreme C terminus of the primase. A mutant primase missing only the C-terminal 16 amino acids was isolated and its activities examined. This mutant enzyme was fully active as a primase, but was incapable of interacting with DnaB. Thus, the mutant primase could not support DNA synthesis in either the general priming reaction or during phiX174 complementary strand DNA replication. Alanine cluster mutagenesis and deletion analysis in p16 allowed the further localization of the interaction domain to the extreme C-terminal 8 amino acids in primase.

Tau protects beta in the leading-strand polymerase complex at the replication fork

Replication forks formed in the absence of the tau subunit of the DNA polymerase III holoenzyme produce shorter leading and lagging strands than when tau is present. We show that one reason for this is that in the absence of tau, but in the presence of the gamma-complex, leading-strand synthesis is no longer highly processive. In the absence of tau, the size of the leading strand becomes proportional to the concentration of beta and inversely proportional to the concentration of the gamma-complex. In addition, the beta in the leading-strand complex is no longer resistant to challenge by either anti-beta antibodies or poly(dA):oligo(dT). Thus, tau is required to cement a processive leading-strand complex, presumably by preventing removal of beta catalyzed by the gamma-complex.

Characterization and sequence of the Escherichia coli stress-induced psp operon

We describe a new Escherichia coli operon, the phage shock protein (psp) operon, which is induced in response to heat, ethanol, osmotic shock and infection by filamentous bacteriophages. The operon includes at least four genes: pspA, B, C and E. PspA associates with the inner membrane and has the heptad repeats characteristic of proteins that can form coiled coils. The operon encodes a factor that activates psp expression, and deletion analyses indicate that this protein is PspC; PspC is predicted to possess a leucine zipper, a motif present in many eukaryotic transcription factors. The pspE gene is expressed in response to stress as part of the operon, but is also transcribed from its own promoter under normal conditions. In vitro studies suggest that PspA and C are modified in vivo. Expression of the psp genes does not require the heat shock sigma factor, sigma32. The increased duration of psp induction in a sigma32 mutant suggests that a product (or products) of the heat shock response down-regulates expression of the operon.

Secretion and membrane integration of a filamentous phage-encoded morphogenetic protein

The filamentous phage-encoded gene IV protein is required at high levels for virus assembly, although it is not a constituent of the virion. It is an integral membrane protein that does not contain an extended hydrophobic region of the kind often required for stable integration in the inner membrane. Rather, like a number of Escherichia coli outer membrane proteins, pIV is rich in charged amino acid residues and is predicted to consist of extensive beta-sheet structures. In phage-producing cells, pIV is primarily detected in the outer membrane, while in cells that produce it from the cloned gene, pIV is found in both the inner and outer membranes. The protein is synthesized as a precursor. Following cleavage of the signal sequence and translocation into the periplasm, the mature form is initially found as a soluble species. Soluble pIV then integrates into the membrane with a half-time of one to two minutes. Neither phage assembly nor other phage proteins are needed for this membrane integration, and phage assembly does not require the presence of the soluble form. The gene IV protein may be part of the structure through which the assembling phage is extruded.

A hybrid toxin from bacteriophage f1 attachment protein and colicin E3 has altered cell receptor specificity

A hybrid protein was constructed in vitro which consists of the first 372 amino acids of the attachment (gene III) protein of filamentous bacteriophage f1 fused, in frame, to the carboxy-terminal catalytic domain of colicin E3. The hybrid toxin killed cells that had the F-pilus receptor for phage f1 but not F- cells. The activity of the hybrid protein was not dependent upon the presence of the colicin E3 receptor, BtuB protein. The killing activity was colicin E3 specific, since F+ cells expressing the colicin E3 immunity gene were not killed. Entry of the hybrid toxin was also shown to depend on the products of tolA, tolQ, and tolR which are required both for phage f1 infection and for entry of E colicins. TolB protein, which is required for killing by colicin E3, but not for infection by phage f1, was also found to be necessary for the killing activity of the hybrid toxin. The gene III protein-colicin E3 hybrid was released from producing cells into the culture medium, although the colicin E3 lysis protein was not present in those cells. The secretion was shown to depend on the 18-amino-acid-long gene III protein signal sequence. Deletion of amino acids 3 to 18 of the gene III moiety of the hybrid protein resulted in active toxin, which remained inside producing cells unless it was mechanically released.

Escherichia coli replication factor Y, a component of the primosome, can act as a DNA helicase

The primosome is a mobile multienzyme DNA replication-priming complex that requires seven Escherichia coli proteins for assembly (the products of the dnaB, dnaC, dnaG, and dnaT genes as well as proteins n and n" and replication factor Y). It has been shown previously that the primosome, in combination with the E. coli DNA polymerase III holoenzyme, can form replication forks in vitro that move at rates similar to those measured in vivo and that the primosome and one of the components of the primosome, the DNA B protein, have DNA helicase activity. Evidence is presented here that another component of the primosome, replication factor Y, possesses DNA helicase activity as well. Factor Y helicase activity requires the presence of E. coli single-stranded DNA binding protein, Mg2+, and hydrolyzable ATP or dATP. Helicase activity is stimulated 15-fold when the enzyme is actively loaded onto single-stranded DNA through a primosome assembly site, and duplex DNA is unwound unidirectionally, 3'----5', along the DNA strand to which the protein is bound.

The fusion-related hydrophobic domain of Sendai F protein can be moved through the cytoplasmic membrane of Escherichia coli

Recent work on a prokaryotic membrane protein, gene III protein (pIII) of coliphage f1, showed that polypeptide segments of sufficient hydrophobicity functioned to stop transfer of the polypeptide across the cell membrane: strings of 16 or more hydrophobic amino acids sufficed. A fusion-related hydrophobic domain (FRHD) of Sendai F protein, a sequence of 26 consecutive uncharged residues, has been implicated in the fusion of the viral membrane envelope and the target-cell membrane through a hydrophobic interaction. As it is located on the exterior of the viral membrane, this sequence must be transferred across the host-cell membrane during synthesis. We have inserted either the FRHD or the F protein membrane anchor (the COOH-terminal region of the F protein) into an internal site of a secreted pIII, which lacks its natural membrane anchor. These two hydrophobic sequences behave in the bacteria just as they do in their natural eukaryotic cell host. The F protein membrane anchor functions to stop transfer, conferring a membrane-spanning topology to the F-pIII hybrid protein; however, the FRHD is moved through the cytoplasmic membrane and derivatives carrying this sequence are secreted to the periplasm. We discuss how the FRHD is compatible with passage through the membrane and yet is still able to mediate membrane fusion through a presumed hydrophobic interaction.

Multiple mechanisms of protein insertion into and across membranes

Protein localization in cells is initiated by the binding of characteristic leader (signal) peptides to specific receptors on the membranes of mitochondria or endoplasmic reticulum or, in bacteria, to the plasma membrane. There are differences in the timing of protein synthesis and translocation into or across the bilayer and in the requirement for a transmembrane electrochemical potential. Comparisons of protein localization in these different membranes suggest underlying common mechanisms.

Nucleotide sequence and genetic organization of the genome of the N-specific filamentous bacteriophage IKe. Comparison with the genome of the F-specific filamentous phages M13, fd and f1

The nucleotide sequence and genetic organization of the genome of the N-specific filamentous single-stranded DNA phage IKe has been established and compared with that of the F-specific filamentous phages M13, fd and f1 (Ff). The IKe DNA sequence comprises 6883 nucleotides, which is 476 (475) nucleotides more than the nucleotide sequence of the Ff genome. The data indicate that IKe and Ff have evolved from a common ancestor (overall homology approx. 55%) and that their genomes contain ten homologous genes, the order of which is identical. Similar to Ff, the major coat protein and the gene III-encoded pilot protein of IKe are synthesized via precursor molecules. The extent of homology between the genes of IKe and Ff differs significantly from one gene to another. Genes that code for viral capsid proteins are less homologous than genes whose products are involved in the processes of DNA replication and phage morphogenesis. During evolution, large nucleotide sequence rearrangements have occurred in the gene (gene III) whose product is needed for the attachment of the virion to the conjugative pili of the host cell, suggesting that these rearrangements have led to phages with different host specificities. Extensive nucleotide sequence homology was noted between the structural elements involved in DNA replication and phage morphogenesis, indicating that the mechanisms involved in DNA replication and morphogenesis are highly conserved.

Reduction of the minimal sequence for initiation of DNA synthesis by qualitative or quantitative changes of an initiator protein

Initiation of DNA synthesis at an origin of DNA replication involves complex protein-DNA interactions that are still poorly understood. Some of these interactions are highly specific and involve proteins (initiator proteins) thought to be essential for regulation of the initiation process because of their rate-limiting activity. We show here that both qualitative and quantitative changes in one of these proteins have profound effects on protein-DNA interactions at an origin of DNA replication, and are sufficient to reduce to less than one-third the minimal sequence required for initiation. The general implications of these findings are discussed.

Transcription in bacteriophage f1-infected Escherichia coli: RNA synthesized on DNA of deletion mutant PII shows the existence of a two-site terminator

Two different transcripts are synthesized on the DNA of deletion mutant PII of bacteriophage f1 in E. coli cells infected with this miniphage. Both RNA species appear to be primary transcripts and differ by about 100 nucleotides at their 3'OH end. Mapping of these molecules on the miniphage genome suggests that a two-site terminator is active at the end of the I region of transcription of bacteriophage f1.

Minor protein content of the gene V protein/phage single-stranded DNA complex of the filamentous bacteriophage f1

The gene V protein/phage single-stranded (SS) DNA complex is an intermediate in the assembly of the filamentous bacteriophage f1. The minor protein content of this complex isolated from wild-type and amber mutant phage-infected Escherichia coli bacteria has been analyzed. Other than the gene V protein, none of the proteins found in purified samples of the complex correspond to any known phage gene products. In particular, the minor coat proteins found in the mature phage particle do not appear to be components of the cytoplasmic gene V protein/f1 SS DNA complex. However, approximately 1-3 molecules of E. coli single-stranded DNA binding protein (SSB) copurify with the complex and may be stably associated with this structure in vivo.

Specificity of translational regulation by two DNA-binding proteins

The gene V protein of the filamentous bacteriophages fl, fd and M13, and the gene 32 protein of bacteriophage T4 share the property of binding strongly and co-operatively to single-stranded nucleic acids, especially DNA. Moreover, both are capable of repressing the translation of specific mRNAs (gene 32 protein its own, and gene V protein that of the filamentous phage gene II), both in vivo and in vitro. If the mechanism of repression by either of these proteins were based solely on its ability to bind single strands co-operatively, then the other would be expected to mimic or interfere with its effect in vitro. We have found no such mimicry or interference, even at protein concentrations high enough to have substantial non-specific effects on translation. This suggests that the sites of repression on the mRNAs must offer something other than simple "unstructuredness" for binding and repression to occur.

Cloning of eukaryotic genes in single-strand phage vectors: the human interferon genes

Using oligonucleotide probes with defined sequences, we have selected clones from a human lymphocyte cDNA library which represent human leukocyte (HuIFN-alpha) and fibroblast (HuIFN-beta) interferon gene sequences. Double-stranded f1 phage DNA was used as the vector for initial cloning of cDNA. Clones carrying interferon gene sequences were identified by hybridization with the oligonucleotide probes. The same oligonucleotide probes were used as primers for dideoxy chain termination sequencing of the clones. One HuIFN-alpha clone, 201, has a nucleotide sequence different from published HuIFN-alpha sequences. Under control of the lacUV5 promoter, the 201 gene has been used to express biologically active HuIFN-alpha in Escherichia coli.

Co-evolution of a filamentous bacteriophage and its defective interfering particles

Serial passage of bacteriophage f1 at high multiplicities of infection results in the appearance of defective deletion mutants (miniphage) that harbor a tandem reiteration of regions of the f1 genome near the origin of DNA replication. These miniphage interfere with the growth of wild-type f1, and cause a sharp decrease of the viable phage titer. Upon further passage, however, the titer increases again. Viable phage variants (maxiphage) appear which harbor the same tandem reiteration of DNA as the miniphage. The maxiphage are more resistant than the wild type to interference by the miniphage. In the absence of miniphage the maxiphage grow at the same rate as the wild type. The structure of the DNA reiteration gradually changes during further passage. Miniphage and maxiphage follow, in parallel, a similar course of changes in the pattern of reiteration. In miniphage the reiterations change while the deletions are conserved. Serial passage of maxiphage quickly yields miniphage, which harbor a reiteration identical to that of the parental maxiphage. Both reiteration and deletion are relevant to the mechanism of interference by miniphage. Thus serial passage of the filamentous phage affords an experimental system to study evolution of a DNA genome in test tubes. Possible mechanisms of the interference by miniphage are discussed.

Methyl-directed repair of DNA base-pair mismatches in vitro

An assay has been developed that permits analysis of DNA mismatch repair in cell-free extracts of Escherichia coli. The method relies on repair of heteroduplex molecules of f1 R229 DNA, which contain a base-pair mismatch within the single EcoRI site of the molecule. As observed with mismatch heteroduplexes of lambda DNA [Pukkila, P. J., Peterson, J., Herman, G., Modrich, P. & Meselson, M. (1983) Genetics, in press], in vivo mismatch correction of f1 heteroduplexes is directed by the state of dam methylation of d(G-A-T-C) sequences within the DNA duplex. Thus, the heteroduplex (formula: see book) is repaired in vivo to an EcoRI-sensitive form if the strand bearing the wild-type EcoRI sequence carries the dam modification and the other does not. Such molecules are also subject to mismatch repair by E. coli extracts. The in vitro activity is also dependent on ATP, the state of dam methylation of mismatch heteroduplexes, and products of mutH, mutL, mutS, and uvrE loci. However, crude fractions deficient in these gene products do complement in the cell-free system, thus providing assays for their isolation. The in vitro reaction is accompanied by repair synthesis on the unmethylated DNA strand.

Transcription in bacteriophage f1-infected Escherichia coli: very large RNA species are synthesized on the phage DNA

Fractionation of pulse-labeled RNA extracted from E. coli cells infected with phage f1 and hybridization of this RNA to f1 DNA reveals that very large species are synthesized on the phage genome. Hybridization of the RNA to specific fragments of f1 DNA shows that, in the infected cell, at least one mRNA is present into which the sequences of genes III, VI, and I are all transcribed together. This result fully explains the polar effect shown by gene III mutants on the expression of genes VI and I (Pratt et al. 1966).

A bacterial gene, fip, required for filamentous bacteriophage fl assembly

An Escherichia coli mutant which does not support the growth of filamentous bacteriophage fl allows phage fl DNA synthesis and gene expression in mutant cells, but progeny particles are not assembled. The mutant cells have no other obvious phenotype. On the basis of experiments with phage containing nonlethal gene I mutations and with mutant fl selected for the ability to grow on mutant bacteria, we propose an interaction between the morphogenetic function encoded by gene I of the phage and the bacterial function altered in this mutant. The bacterial mutation defines a new gene, fip (for filamentous phage production), located near 84.2 min on the E coli chromosome.

Transcription in bacteriophage f1-infected Escherichia coli. Messenger populations in the infected cell

Transcription of bacteriophage f1 DNA in vivo occurs in two independent regions. They are separated from one another by a strong terminator just downstream from gene VIII on one side, and by the filamentous phage intergenic space on the other. One of these regions contains genes II, V, VII, IX and VIII, and is actively transcribed. In this region there are a number of promoters but only one effective terminator. Thus, most of the RNAs that come from this region overlap and share sequences close to the termination site. The other region, which contains genes III, VI, I and IV, is transcribed much less actively. This region gives rise to a long (approximately 4 X 10(3) bases) RNA that covers the entire region, and several RNAs that overlap in the region closest to their 5' termini. Several other RNAs appear to overlap only with the 4 X 10(3) base transcript. Thus, not only the frequency but the organization of transcription differs in the two portions of the genome.

Genetic transformation of Streptococcus pneumoniae by DNA cloned into the single-stranded bacteriophage f1

A Staphylococcus aureus plasmid derivative, pFB9, coding for erythromycin and chloramphenicol resistance was cloned into the filamentous Escherichia coli phage f1. Recombinant phage-plasmid hybrids, designated plasmids, were isolated from E. coli and purified by transformation into Streptococcus pneumoniae. Single-stranded DNA was prepared from E. coli cells infected with two different plasmids, fBB101 and fBB103. Introduction of fully or partially single-stranded DNA into Streptococcus pneumoniae was studied, using a recipient strain containing an inducible resident plasmid. Such a strain could rescue the donor DNA marker. Under these marker rescue conditions, single-stranded fBB101 DNA gave a 1% transformation frequency, whereas the double-stranded form gave about a 31% frequency. Transformation of single-stranded fBB101 DNA was inhibited by competing double-stranded DNA and vice versa, indicating that single-stranded DNA interacts with the pneumococcus via the same binding site as used by double-stranded DNA. Heteroduplexed DNA containing the marker within a 70- or 800-base single-stranded region showed only slightly greater transforming activity than pure single-stranded DNA. In the absence of marker rescue, both strands of such imperfectly heteroduplexed DNA demonstrated transforming activity. Pure single-stranded DNA demonstrated low but significant transforming activity into a plasmid-free recipient pneumococcus.

In vitro characterization of the fibroin gene promoter by the use of single-base substitution mutants

A highly efficient method for segment-directed mutagenesis has been developed. The method relies on the deamination by sodium nitrite of the bases in the separated strands of a small DNA restriction fragment. The mutagen-treated strands produce transition mutations by the following sequence: (i) hybridization with the complementary strand of the wild-type DNA that had been cloned into a phage fl vector, (ii) repair synthesis in vitro, and (iii) transfection of Escherichia coli. Using this method, we have isolated 14 single-point mutants within a 31-base-pair stretch of the fibroin gene (from the T-A-T-A box at the nucleotide position -30 to the cap site at +1). In vitro transcription experiments with the HeLa cell or the silk gland cell extract show that single-base transitions at the T-A-T-A box (T to C at -30, A to G at -29, and T to C at -28) and at the -20 region (G to A at -21, T to C at -20, and A to G at -17) result in decreased promoter activities, whereas those at the cap site and the -10 regions have no effect. The initiation site of transcription is the same for five "down" (reduced activity) mutants (T to C at -30, T to C at -28, G to A at -21, T to C at -20, and A to G at -17), the cap site mutant (A to G at +1), and the wild-type genes--position +1. However, the A-to-G transition at -29 (the second base of the T-A-T-A box) induces an additional transcription start from position +4. Functions of the T-A-T-A box and the -20 regions are discussed.

Deletion mutants defining the Escherichia coli replication factor Y effector site sequences in pBR322 DNA

The Escherichia coli DNA replication factor Y, along with other genetically undefined replication proteins, is involved in a dnaB-, dnaC-, and dnaG-dependent pathway of primer formation on phi X174 single-stranded circular DNA. In addition, replication factor Y has a site-specific, single-stranded DNA-dependent ATPase activity. We have previously demonstrated the presence of two factor Y effector sites on pBR322 DNA. When inserted into the filamentous phage f1R229, these sites can function as rifampicin-resistant dnaB-, dnaC-, and dnaG-dependent origins of DNA replication. We report here the construction of deletion mutants of the two pBR322 factor Y effector sites. These deleted sites no longer function as effectors for factor Y ATPase activity nor as templates for rifampicin-resistant dnaB-, dnaC-, and dnaG-dependent DNA synthesis. We conclude that the DNA sequences required for factor Y ATPase activity and origin function are likely to be identical.

Purification and properties of the Hpa I methylase

The purification and catalytic properties of the homogeneous Hpa I methylase is described. The enzyme exists as a single polypeptide chain with a molecular weight of 37,000 +/- 2,000 was shown by sedimentation equilibrium and polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. The Hpa I methylase transfers methyl groups of S-adenosylmethionine to adenine present in the recognition sequence d(G-T-T-A-A*-C), A* is the N6 methyl adenosine. An average of 2.1 methyl groups per recognition site are transferred by the Hpa I methylase.

Nucleotide sequence of bacteriophage f1 DNA

The nucleotide sequence of the DNA of the filamentous coliphage f1 has been determined. In agreement with earlier conclusions, the genome was found to comprise 6,407 nucleotides, 1 less than that of the related phage fd. Phage f1 DNA differs from that of phage M13 by 52 nucleotide changes, which lead to 5 amino acid substitutions in the corresponding proteins of the two phages, and from phage fd DNA by 186 nucleotide changes (including the single-nucleotide deletion), which lead to 12 amino acid differences between the proteins of phages f1 and fd. More than one-half of the nucleotide changes in each case are found in the sequence of 1,786 nucleotides comprising gene IV and the major intergenic region between gene IV and gene II. The sequence of this intergenic region (nucleotides 5501 to 6005) of phage f1 differs from the sequence reported by others through the inclusion of additional single nucleotides in eight positions and of a run of 13 nucleotides between positions 5885 and 5897, a point of uncertainty in the earlier published sequence. The differences between the sequence of bacteriophage f1 DNA now presented and a complete sequence for the DNA previously published by others are discussed, and the f1 DNA sequence is compared with those of bacteriophages M13 and fd.

Effects of bacteriophage f1 gene III protein on the host cell membrane

Plasmids which encode bacteriophage f1 coat protein genes VIII and III are responsible for a number of unusual properties suggesting that they have a drastic effect on the bacterial outer membrane. Analysis of several such recombinant plasmids and selection of mutant plasmids unable to cause this effect established that the properties were caused by gene III protein or its amino-terminal fragment.

The filamentous phage (Ff) as vectors for recombinant DNA--a review

Derivatives of filamentous phage, f1, fd, and M13, useful as cloning vectors are listed, and procedures for their use are reviewed. Methods for growing phage, preparing single- and double-stranded DNA, and cloning are given in the "cook-book" form. These procedures minimize the practical problem often associated with filamentous-phage cloning, i.e., deletion of inserts.

Molecular cloning and characterization of double-stranded cDNA coding for bovine chymosin

A full-length cDNA copy of the mRNA encoding calf chymosin (also known as rennin), a proteolytic enzyme with commercial importance in the manufacture of cheese, has been cloned in an f1 bacteriophage vector. The nucleotide sequence of the cDNA was determined, and translation of that sequence into amino acids predicts that the zymogen prochymosin is actually synthesized in vivo as preprochymosin with a 16 amino acid signal peptide. In vitro translation of total poly(A)-enriched RNA from the calf fourth stomach (abomasum) and immunoprecipitation with antichymosin antiserum revealed that a form of chymosin (probably preprochymosin judging from the Mr-value) is the major in vitro translation product of RNA from that tissue. Gel-transfer hybridization of restriction endonuclease-cleaved bovine chromosomal DNA with labeled cDNA probes indicated that the two known forms of chymosin, A and B, must be products of two different alleles of a single chymosin gene.

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.

Staphylococcal plasmids that replicate and express erythromycin resistance in both Streptococcus pneumoniae and Escherichia coli

Plasmid pSA5700 from Staphylococcus aureus coding for erythromycin (EmR) and chloramphenicol (CmR) resistance was transformed into Streptococcus pneumoniae. High-copy-number and EmR constitutive mutants of this plasmid were isolated. Transformation frequencies in S. pneumoniae as high as 70% were obtained with a constitutive plasmid as donor DNA, into a recipient cell containing a resident, inducible, high-copy-number plasmid. With the aid of these high frequencies, the site of constitutive mutations could be mapped via a simple marker rescue technique that uses purified restriction endonuclease-generated fragments. One of the EmR constitutive mutants, pFB9, a plasmid originating from a Gram-positive host, was shown to replicate and express EmR and CmR in a Gram-negative organism, Escherichia coli. Four derivatives of pFB9 containing large (0.6-0.9 megadalton) insertion sequences that arose spontaneously in E. coli demonstrated unusual transforming activity, as well as enhanced EmR, in E. coli. The inserted elements mapped to the region in front of the EmR gene. Three of these inserted elements had the size and restriction patterns of insertion sequence IS1, IS2, and IS5. Plasmid pFB9 and derivatives are useful for isolation of new insertion sequences and for comparison of gene expression and illegitimate recombination between Gram-positive and Gram-negative species.