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

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.

Construction and characterization of a phage-plasmid hybrid (phagemid), pCAK1, containing the replicative form of viruslike particle CAK1 isolated from Clostridium acetobutylicum NCIB 6444

A bacteriophage-plasmid hybrid (phagemid) designated pCAK1 was constructed by ligating 5-kbp Escherichia coli plasmid pAK102 (AprEmr) and the 6.6-kbp HaeIII-linearized replicative form of the CAK1 viruslike particle from Clostridium acetobutylicum NCIB 6444. Phagemid pCAK1 (11.6 kbp) replicated via the ColE1 replication origin derived from pAK102 in E. coli. Single-stranded DNA (ssDNA) molecules complexed with protein in a manner which protected ssDNA from nucleases were recovered from the supernatant of E. coli DH11S transformants containing pCAK1 in the absence of cell lysis. This suggests that the viral-strand DNA synthesis replication origin of CAK1 and associated gene expression are functional in E. coli DH11S. The single-stranded form of pCAK1 isolated from E. coli supernatant was transformed into E. coli DH5 alpha' or DH11S by electroporation. Isolation of ampicillin-resistant E. coli transformants following transformation suggests that the complementary-strand DNA synthesis replication origin of CAK1 is also functional in E. coli. The coat proteins associated with ssDNA of pCAK1 demonstrated sensitivity to proteinase K and various solvents (i.e., phenol and chloroform), similar to the results obtained previously with CAK1. Following phagemid construction in E. coli, pCAK1 was transformed into C. acetobutylicum ATCC 824 and C. perfringens 13 by intact cell electroporation. Restriction enzyme analysis of pCAK1 isolated from erythromycin-resistant transformants of both C. acetobutylicum and C. perfringens suggested that it was identical to that present in E. coli transformants.

Translational control of phage f1 gene expression by differential activities of the gene V, VII, IX and VIII initiation sites

Phage-specific transcription and subsequent RNA processing in Escherichia coli infected with the filamentous phage (f1, M13, fd) generate a pool of abundant and relatively long-lived phage mRNA species encoding the four adjacent genes V, VII, IX and VIII. Yet the products of gene V and gene VIII are synthesized at much higher levels than the gene VII and gene IX proteins. To ask if the translational initiation sites heading these genes show corresponding differences in activity and/or functional properties, we have purified a number of the phage mRNAs from cells infected with f1 and examined them in in vitro initiation reactions. The ribosome binding patterns obtained for the phage mRNA species and for smaller defined RNA fragments containing selected initiator regions reveal a large range in apparent ribosome binding strengths. The gene V and gene VIII sites are recognized efficiently in each mRNA species in which they are present. Gene IX site activity appears to be limited by local mRNA structure: the site has undetectable or low ribosome binding activity in all of the phage mRNA species, but is at least tenfold more active if the RNA sequences required to form a potential hairpin stem-and-loop 15 nucleotides upstream from the initiator AUG have been removed. The gene VII site shows no evidence of interaction with ribosomes in any phage mRNA or RNA fragment tested. The same striking differences in initiation activity were observed in vivo by cloning small f1 DNA fragments containing gene V or gene VII initiation site sequences to drive beta-galactosidase synthesis. High levels of a gene V-beta-galactosidase fusion protein are initiated at the V site, but no detectable synthesis occurs from the VII site. If the VII site is preceded by all of the information encoding the upstream gene V, however, modest amounts of a fusion protein initiated at the VII site are produced. The overall results, in accord with the observed yields of proteins in the phage-infected cell, provide strong evidence that the properties of these translational initiation sites determine in a significant way the differential expression of phage f1 genes V, VII, IX and VIII.

Association of the adenovirus DNA-binding protein with RNA both in vitro and in vivo

The multifunctional DNA-binding protein (DBP) encoded by human adenovirus binds RNA. The association of purified DBP with RNA in vitro was demonstrated by using either a gel filtration or a filter binding assay. This association is sensitive to ionic strength and exhibits no apparent sequence specificity. DBP also interacts with RNA in vivo; it can be crosslinked to polyadenylylated RNA by UV-irradiation of intact cells during the late phase of adenovirus infections. The 46-kDa carboxyl-terminal domain of DBP binds RNA in vitro and was found to be associated with polyadenylylated RNA in vivo. This is the same domain that interacts with DNA. However, the differences in sensitivity of DBP to trypsin when bound to RNA versus DNA suggest that RNA and DNA either bind at different sites within this domain or induce different conformational changes within the protein.

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.

Rho-dependence of the terminator active at the end of the I region of transcription of bacteriophage f1

Infection of rho- Escherichia coli cells with deletion mutant PII of bacteriophage f1 results in a miniphage RNA population composed of transcripts longer than those synthesized in the infection of rho+ cells. This indicates a Rho dependence of the terminator active at the end of the I region of transcription of bacteriophage f1. An estimate of the length of a transcript, which represents a good fraction of the RNA that passes beyond the terminator, indicates that the hairpin structure where synthesis of complementary strand DNA initiates also acts as a fairly efficient Rho-independent terminator.

Initiation and termination signals for transcription in bacteriophage M13

Transcription of the infrequently expressed phage M13 genome domain, comprising genes III, VI, I and IV, has been studied in detail by hybridization and S1-nuclease mapping studies. The contiguous genes III and VI are transcribed via an 1800 nucleotide-long RNA molecule that is initiated at a promoter which overlaps with the Rho-independent termination signal between genes III and VIII. Its synthesis is terminated at a Rho-dependent terminator in the proximal part of gene I. Transcription of gene I is not mediated by an independent promoter but most probably by read-through of RNA-polymerase through this terminator. Transcription of gene IV is accomplished by synthesis of four distinct RNAs of about 1500 to 1680 nucleotides long which are initiated at a promoter located immediately in front of gene IV. Termination of these transcripts is generated at least four different sites located in tandem within the intergenic region between genes IV and II.

A rho-dependent transcription termination signal in bacteriophage f1

The bacteriophage f1 intergenic region distal to gene IV encodes a rho-dependent transcription termination signal. Terminator function in vivo and in vitro is dependent upon active Escherichia coli rho protein, although the RNA 3' ends detected in vivo differ from those seen in vitro. The minimal sequence required for terminator function in a heterologous plasmid system encompasses approximately 100 nucleotides distal to gene IV, which can be drawn as a large hairpin structure. The in vivo rho-dependent 3' end occurs within this sequence, while the in vitro rho-dependent 3' ends occur just distal to it. In vivo in a rho mutant host, f1 transcripts pass through the rho-dependent sites and stop within a sequence of high potential secondary structure near the f1 origin of DNA replication. This sequence alone causes transcription termination in the heterologous plasmid system in vivo. In vitro in the absence of rho protein, transcription does not terminate within this sequence. The RNA 3' ends detected in these studies do not occur within A + T-rich sequences.

The major coat protein gene of the filamentous Pseudomonas aeruginosa phage Pf3: absence of an N-terminal leader signal sequence

From in vitro protein synthesis studies and nucleotide sequence analysis it has been deduced that, unlike the major coat proteins of the hitherto studied filamentous bacterial viruses Ff (M13, fd and f1), IKe and Pf1, the major coat protein of the filamentous Pseudomonas aeruginosa virus Pf3 is not synthesized as a precursor containing a leader signal polypeptide at its N-terminal end. From the elucidated nucleotide sequence of the Pf3 major coat protein gene it follows that the coat protein is 44 amino acid residues long (mol.wt. 6425). No sequence homology was observed with the major coat protein genes of either the Ff group or IKe but, similar to these phages, 3' ward of the Pf3 coat protein gene a DNA sequence is located which has many characteristics in common with rho-independent transcription termination signals.

The hisR locus of Salmonella: nucleotide sequence and expression

In S. typhimurium, the hisR locus is defined by mutations causing reduced levels of the histidine transfer RNA. As a preliminary step in the analysis of the hisR mutants, a 972 bp DNA fragment containing the histidine tRNA gene from wild-type Salmonella was cloned and completely sequenced. This analysis revealed the existence of a tRNA gene cluster which, in addition to the tRNAHis gene, includes the genes for tRNALeu1, tRNAPro1 and a tentative tRNAArgCGG. All four tRNA genes are present as single copies and are separated by spacer sequences ranging from 20 to 53 bp in length. The gene cluster is efficiently transcribed in vitro by E. coli RNA polymerase and yields a transcript, approximately 480 nucleotides long, which contains all four tRNA sequences. This tetrameric precursor can be processed to 4S RNA in vitro with a wild-type Salmonella extract, but not with an extract prepared from a hisU (RNase P) mutant. Using portions of the tRNA gene cluster as specific hybridization probes, various processing intermediates were shown to accumulate in vivo in the hisU mutant. Most of these RNAs are monomeric precursors only a few nucleotides longer than the respective mature tRNA species.

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).

Compilation and analysis of Escherichia coli promoter DNA sequences

The DNA sequence of 168 promoter regions (-50 to +10) for Escherichia coli RNA polymerase were compiled. The complete listing was divided into two groups depending upon whether or not the promoter had been defined by genetic (promoter mutations) or biochemical (5' end determination) criteria. A consensus promoter sequence based on homologies among 112 well-defined promoters was determined that was in substantial agreement with previous compilations. In addition, we have tabulated 98 promoter mutations. Nearly all of the altered base pairs in the mutants conform to the following general rule: down-mutations decrease homology and up-mutations increase homology to the consensus sequence.

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.

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.

Nucleotide sequence of the genes III, VI and I of bacteriophage M13

A DNA region of 2750 base pairs encompassing the genes III, VI and I of bacteriophage M13 has been sequenced by the Maxam-Gilbert procedure. By establishing the nucleotide changes introduced by several amber mutations, the coding region and the regulatory signals of each gene have been deduced. The genes appear to span 1275 base pairs (gene III; mol.wt. 44,748) 339 base pairs (gene VI; mol.wt. 12,264) and 1047 base pairs (gene I; mol.wt. 39,500). Their separating non-codogenic regions are extremely short, namely two and one base pair, respectively. The C-terminal end of gene I, however, intrudes 23 nucleotides into gene IV. From the nucleotide sequence it appears that the minor capsid protein of the phage, which is encoded by gene III, is synthesized in a precursor form containing 18 extra amino acids at its N-terminal end. Furthermore, in this capsid protein two clusters of a fourfold repeat of the sequence Glu-Gly-Gly-Gly-Ser are apparent. Gene VI appears to code for a small, extremely hydrophobic polypeptide. Its total hydrophobic amino acids content of 51% suggests that this protein can only function in the host cell membrane.

Bacteriophage f1 infection of Escherichia coli: identification and possible processing of f1-specific mRNAs in vivo

[3H]Uracil-pulse-labeled RNA from Escherichia coli infected with f1 bacteriophage was fractionated on polyacrylamide gels containing urea. Eight phage-specific RNA species were present with approximate lengths ranging from 2100 to 400 nucleotides. The amount of the seven largest species was increased when the infected bacteria were incubated at 41 degrees C. When the RNA was isolated and used as message in an in vitro protein-synthesizing system, most of the RNA species appeared to direct the synthesis of the phage gene VIII protein. The six largest species also directed the synthesis of the phage gene V protein. Some of the labeled smaller RNA species increased in amount after addition to rifampicin, suggesting that they may have resulted from cleavage of larger RNA species. These particular smaller RNA species also were present in infected bacteria containing a mutant RNase III. The data are discussed in terms of the regulation of synthesis of the phage-specific proteins.