Mapping of promoter sites on the genome of bacteriophage M13

Simulation of the M13 life cycle I: Assembly of a genetically-structured deterministic chemical kinetic simulation

To expand the quantitative, systems level understanding and foster the expansion of the biotechnological applications of the filamentous bacteriophage M13, we have unified the accumulated quantitative information on M13 biology into a genetically-structured, experimentally-based computational simulation of the entire phage life cycle. The deterministic chemical kinetic simulation explicitly includes the molecular details of DNA replication, mRNA transcription, protein translation and particle assembly, as well as the competing protein-protein and protein-nucleic acid interactions that control the timing and extent of phage production. The simulation reproduces the holistic behavior of M13, closely matching experimentally reported values of the intracellular levels of phage species and the timing of events in the M13 life cycle. The computational model provides a quantitative description of phage biology, highlights gaps in the present understanding of M13, and offers a framework for exploring alternative mechanisms of regulation in the context of the complete M13 life cycle.

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.

Cloning, expression and in vitro characterisation of the M13 gene 5 protein

The gene 5 protein encoded in the genome of bacteriophage M13 is a single stranded DNA binding protein essential for phage replication. We have cloned a fragment of the M13 genome containing gene 5, and investigated the effect of upstream elements on expression of the gene by means of Bal 31 deletion analysis. The gene was also expressed from the lac promoter of the phagemid vector pUC119, and the recombinant protein purified and characterised for DNA binding. The affinity of the recombinant protein for single-stranded DNA was shown to be essentially identical to that of wild type gene 5 protein. Wild type gene 5 protein has a glutamic acid residue at position 30 which, on the basis of the crystal structure, was believed to play a role in maintaining the tertiary structure of the protein through the formation of a salt bridge with arginine-80. We show that substitution of glutamic acid at position 30 by lysine does not impair DNA binding, suggesting that a salt bridge between glutamate-30 and arginine-80 is not essential for the structural integrity of the gene 5 protein as previously proposed.

Transcriptional organization of the DNA region controlling expression of the K99 gene cluster

The transcriptional organization of the K99 gene cluster was investigated in two ways. First, the DNA region, containing the transcriptional signals was analyzed using a transcription vector system with Escherichia coli galactokinase (GalK) as assayable marker and second, an in vitro transcription system was employed. A detailed analysis of the transcription signals revealed that a strong promoter PA and a moderate promoter PB are located upstream of fanA and fanB, respectively. No promoter activity was detected in the intercistronic region between fanB and fanC. Factor-dependent terminators of transcription were detected and are probably located in the intercistronic region between fanA and fanB (T1), and between fanB and fanC (T2). A third terminator (T3) was observed between fanC and fanD and has an efficiency of 90%. Analysis of the regulatory region in an in vitro transcription system confirmed the location of the respective transcription signals. A model for the transcriptional organization of the K99 cluster is presented. Indications were obtained that the trans-acting regulatory polypeptides FanA and FanB both function as anti-terminators. A model for the regulation of expression of the K99 gene cluster is postulated.

Transcription initiation by Escherichia coli RNA polymerase at the gene II promoter of M13 phage: stability of ternary complex, direct photocrosslinking to nascent RNA, and retention of sigma subunit

The initial stages of transcription have been characterized using a template containing the gene II promoter region of M13 phage. Initiation of transcription in the presence of all four nucleotides gives rise to the 140-residue run-off transcript, with a minor pause at the RNA hexamer stage. Cycling, leading to the accumulation of significant amounts of short oligonucleotides [1], was not observed. An RNA hexamer GUUUUU was the sole product when GpU and UTP were used and the ternary complex with the hexamer was stable and resistant to high salt (0.4 M) and S1 nuclease attack. After direct ultraviolet photocrosslinking of the RNA hexamer to RNA polymerase in the ternary complex, the radioactive label incorporation into various subunits was determined by autoradiography after sodium tetradecyl sulfate gel electrophoresis to be as follows: sigma, 86%; beta, 14%; beta' and alpha, negligible. Both electrophoresis and sucrose gradient centrifugation experiments indicate that the sigma subunit is not released from the ternary complex when either the RNA hexamer or the 140-residue RNA is synthesized on this template, even though the complexes are stable.

Gene-III protein of filamentous phages: evidence for a carboxyl-terminal domain with a role in morphogenesis

A filamentous phage derivative, fCA55, bearing a nonpolar deletion in gene III, has been constructed and characterized to study the functions of that gene. The deletion eliminates most of gene III without disturbing its reading frame or the putative promoter for the downstream gene, VI. Therefore it is assumed that any abnormalities exhibited by fCA55 are a direct effect of the gene-III lesion itself, and not polar effects on other genes. fCA55 Is abnormal in two respects. First, it is noninfective; in this it resembles another nonpolar gene-III deletion mutant, fKN16, which is missing 507 bp encompassing roughly the first half of the gene. Second, it is secreted as polyphage--very long particles containing many unit-length DNA molecules; in this respect, fCA55 differs from fKN16. When the viral proteins of these two mutants were analyzed with antibody directed against gene-III protein, it was found that fKN16 contains an altered gene-III protein, while fCA55 is unreactive. It was concluded that the gene-III protein has two functional domains: the N-terminal domain, missing in both mutants, is required for viral infectivity; while the C-terminal domain, partly missing in fCA55 but retained in fKN16, is incorporated into the virion, and is responsible for the protein's role in generating normal, unit-length particles.

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.

Control of transposon Tn5 transposition in Escherichia coli

Tn5 is a composite transposable element in which the insertion sequences IS50R and IS50L bracket a central region encoding kanamycin resistance (kanr). IS50R encodes a functional transposase, whereas IS50L contains the promoter of the kanr gene. To determine the relative activities of IS50R and IS50L in transposition we examined the structures of chimeric DNA molecules generated by insertion of segments of pBR322::Tn5 dimeric plasmids into red- lambda phage in recA- Escherichia coli. Restriction endonuclease analyses showed that the inserted sequences contained direct terminal repeats of pairs of IS50R or of IS50L elements and that the frequencies of usage of IS50R vs. IS50L depended on the position and orientation of Tn5 in the plasmid vector: IS50R was used preferentially when Tn5 was in transcriptionally quiescent regions of the vector (in either orientation) or when IS50L was immediately downstream from a strong promoter in the vector. In contrast, IS50L was used preferentially when IS50R was downstream from a strong promoter. We conclude IS50R tends to be used preferentially but that when transcription impinges on the end of an IS50 element the participation of that element in transposition is inhibited.

Nucleotide sequence and genome organisation of filamentous bacteriophages fl and fd

The DNA sequence of the filamentous phage F1, consisting of 6407 nucleotides, has been determined. When compared with the DNA sequence of the related filamentous phage fd (Beck et al., 1978), the f1 sequence is one nucleotide shorter and differs in 180 positions from the fd DNA. Only ten of these base exchanges cause amino acid exchanges in the known gene products. Most of the exchanges in f1 are the same as in M13 (Van Wezenbeek et al., 1980), showing a near identity of these two phage (there are only 59 nucleotide differences). Regulatory units for replication, transcription, and translation are in their essential parts identical in all three phage.

Transcription of bacteriocinogenic plasmid CloDF13 in vivo and in vitro: structure of the cloacin immunity operon

Escherichia coli minicells harboring plasmid CloDF13 synthesized at least 25 messenger ribonucleic acid (RNA) species; three of these RNAs, a 2,400-, a 2,200-, and a 100-nucleotide RNA, were synthesized in relatively large amounts. Using insertion and deletion mutants of CloDF13 as well as an RNA blotting technique, we could demonstrate that these three RNAs are transcripts from the CloDF13 DNA region from 0 to 40%. This region contains the cloacin and immunity genes and the genetic information involved in plasmid DNA replication. A transcription map of this region is presented and discussed. The data indicate that the cloacin and immunity genes were coordinately transcribed into messenger RNAs of about 2,400 and 2,200 nucleotides, which differ in length at their 3' terminus. RNA polymerase binding studies and in vitro transcription assays indicated that transcription of these genes initiates at a promoter located around 32% on the CloDF13 map. Furthermore, it is shown that a 100-nucleotide RNA is encoded by the CloDF13 DNA region between 7.7 and 8.8% on the plasmid genome; the synthesis of this RNA proceeds in a direction opposite to the transcription of the cloacin and immunity genes.

Nucleotide sequence of the filamentous bacteriophage M13 DNA genome: comparison with phage fd

The 6407 nucleotide-long sequence of bacteriophage M13 DNA has been determined using both the chemical degradation and chain-termination methods of DNA sequencing. This sequence has been compared with that of the closely related bacteriophage fd (Beck et al., 1978). M13 DNA appears to be only a single nucleotide shorter than fd DNA. There is an average of 3.0% of nucleotide-sequence differences between the two genomes, but the distribution of these changes is not random; the sequence of some genes is more conserved than of others. In contrast, the nucleotide sequences and positions of the regulatory elements involved in transcription, translation and replication appear to be identical in both filamentous phage DNA genomes.

Transcription of bacteriophage M13 DNA: existence of promoters directly preceding genes III, VI, and I

In vitro transcription and coupled transcription-translation studies have been performed with restriction fragments of bacteriophage M13 replicative-form DNA which contain either gene III, gene VI, or gene I. It could be demonstrated that DNA fragments which contain gene III were able to direct the synthesis of gene III protein. Fragments which encompassed genes VI and I gave rise to the synthesis of gene I protein only, whereas gene I-containing fragments were able to direct the synthesis of gene I protein. None of the fragments studied gave rise to a detectable level of gene VI protein, although an RNA transcript of gene VI could readily be obtained during in vitro transcription of the relevant gene VI-containing DNA fragments. From these results we have concluded that the promoters A0.44 and A0.49 are located in front of genes VI and I, respectively, and that gene III is also equipped with a promoter (X0.25). Introduction of a single cleavage within the gene III region does not abolish the expression of genes VI and I in vitro. Hence, the expression of these genes is not solely dependent on the initiation of RNA synthesis at the gene III promoter or on leakage of transcription through the central termination site (T0.25), but is also determined by the initiation frequency of RNA synthesis at their individual promoters.

Expression of bacteriophage M13 dna in vivo. I. Synthesis of phage-specific RNA and protein in minicells

It is demonstrated that after infection of the appropriate minicell-producing strain of Escherichia coli with the filamentous bacteriophage M13, its replicative form DNA is segregated into minicells. Consequently these minicells have acquired the capability to direct the synthesis of phage-specific RNA and protein. Comparision of the electrophoretic mobilities of phage-specific RNA species made in vitro with those made in M13 replicative form DNA harbouring minicells, have indicated that almost all in vitro synthesized G-start RNAs have an equivalent among the in vivo synthesized RNA products. Furthermore it could be demonstrated that in M13 replicative form DNA harbouring minicells the phage-specific proteins encoded by genes III, IV, V and VIII are made. In addition the synthesis of a phage-specific polypeptide (molecular weight approx. 3000) co-migrating with the recently discovered capsid protein (designated C-protein) could be demonstrated. The meaning of these results for the resolution of the regulatory mechanisms operative during the life cycle of this phage will be discussed.

Expression of bacteriophage M13 DNA in vivo. Localization of the transcription initiation and termination signal of the mRNA coding for the major capsid protein

During the infection cycle of the filamentous bacteriophage M13 a phage specific RNA species is made which selectively directs in vitro the synthesis of the precursor of the major capsid protein encoded by gene VIII. This RNA is unstable (its mean half-life is 11 min) and is made in amounts representing at least 2% of the newly synthesized RN. Nucleotide sequence analysis have indicated that the synthesis of this RNA species is initiated and terminated at the same promoter (G0.18) and termination signal (T0.25) of the M13 genome as the 8S RNA species made in vitro under the direction of M13 replicative form DNA.

Location of the cooperative melting regions in bacteriophage fd DNA

Differential melting profiles of the linear replicative form (RF-III) DNA of bacteriophage fd, of the fragments obtained by the restriction endonuclease R.HinHI and of those obtained by R.Hga were investigated. With these results a physical map which locates the cooperative melting regions on the DNA was constructed, and compared with the genetic map.