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

Translation of phage f1 gene VII occurs from an inherently defective initiation site made functional by coupling

Expression of the filamentous phage f1 gene VII is shown to be translationally coupled to that of the upstream gene V. Fusions of the gene VII initiation site to the lacZ coding region were used to determine that initiation at the VII site is completely dependent on the process of translation having proceeded up to a stop codon immediately upstream from the VII site. Coupled expression from the VII site was found to be inefficient, proportional to the level of upstream translation, and very sensitive to the distance from the functional upstream stop codon. Independent expression from the VII site was not observed, even in a deletion series designed to remove potentially masking RNA structure. On the basis of the VII site's dissimilarity to ribosome binding site sequences and its properties overall, we suggest that it inherently lacks the features required for independent recognition by ribosomes, and acquires the ability to initiate synthesis of gene VII protein by virtue of the coupling process.

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.

Morphogenesis of f1 filamentous bacteriophage. Increased expression of gene I inhibits bacterial growth

We have cloned the gene I sequence of the filamentous bacteriophage f1 downstream from the lambda leftward promoter on a plasmid that also contains the temperature-sensitive lambda repressor, cI857. Temperature induction of gene I protein (pI) resulted in rapid cessation of growth. This inhibition appears to involve a rapid decrease in synthesis of host protein and RNA. The ability of pI to cause this inhibition is not dependent on thioredoxin, a host factor that is necessary for phage morphogenesis and has been shown by genetic data to interact with pI. The inhibition does not appear to be mediated by the amino half of the protein, as induction of an identical plasmid construction of an amber mutant positioned two-thirds along gene I, does not affect cell growth. Analysis of the transcription products from the cloned gene I confirmed previous suggestions that a transcription terminator exists in the amino-terminal portion of the gene. In addition, there is no detectable promoter activity in the 152 bases immediately upstream from the gene. These data and the inability to overproduce pI argue for down-regulation of pI production. Radioactive labeling of proteins in maxi-cells and normal Escherichia coli cells identifies pI as a protein of about 39,000 Mr that partitions with the cell envelope. Pulse-chase experiments suggest that pI is not processed to any appreciable extent.

Effects of bacteriophage fd infection on Escherichia coli HB11 envelope: a morphological and biochemical study

Phage fd-infected host bacteria revealed three characteristic changes in their envelope. (i) The preferred cleavage plane during freeze-fracturing shifted from the inner to the outer membrane (OM). (ii) The total lipids of the OM of the infected cells increased by 25% without major alterations in the relative concentration of phospholipids. We propose that such an increase would to some extent contribute to the change in the freeze-fracture behavior of the OM; however, additional factors will have to play a role in the apparent fracture resistance of the inner membrane. (iii) Ultrathin sectioning and immunolabeling methods revealed that extrusion of fd phages takes place at membrane adhesion sites of the infected cells.

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.

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.

mRNA processing in Escherichia coli: an activity encoded by the host processes bacteriophage f1 mRNAs

To examine the regions of the male-specific filamentous bacteriophage f1 genome that include signals for mRNA processing, the 5' endpoints of the major in vivo phage mRNAs have been located in the f1 DNA sequence by S1 nuclease mapping. The 5' ends of the purified mRNAs and additional phage-specific RNAs transiently visible early after infection occur in clusters of T-rich residues within genes that code for three phage proteins. When a 270-nucleotide region encompassing the 5' endpoints of three processed RNAs is transcribed as part of the bacteriophage lambda N mRNA in uninfected female cells, RNA 5' ends identical to ends of the three f1 RNAs are generated from the lambda-f1 precursor. This finding indicates that the mRNA processing activity is encoded by the bacterial host, and that its recognition sites are present in the local regions near the 5' ends which result from RNA cleavage. Several characteristics of f1 mRNA processing events have implications for the differential regulation of adjacent phage genes constrained in the same transcription unit, and may be representative of similar processing events occurring in the bacterial cell.

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).

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.

Translational control of bacteriophage f1 gene II and gene X proteins by gene V protein

The gene II region of bacteriophage f1 DNA codes for two proteins, the 46 kd gene II protein and the 13 kd gene X protein, which results from an in-phase start at codon 300 of gene II. Using antigene II protein IgG, we show that the intracellular concentration of both proteins is controlled by the phage gene V protein. In wild-type f1-infected cells, the amount of gene II protein reaches a plateau of about 1500 molecules per cell at 20 min after infection, as measured by blot immunoassay. Similarly, the amount of gene X protein reaches a peak of about 500 molecules per cell around 10 min after infection. In contrast, when the gene V protein is inactive, both gene II and gene X proteins continue to accumulate at a high rate for at least 40 min after infection. This difference is caused by decreased synthesis of gene II and gene X proteins in the presence of gene V protein, which represses the translation of these two proteins.

Genes VI, VII, and IX of phage M13 code for minor capsid proteins of the virion

The minor capsid proteins C and D from phage M13 have been characterized by differential amino acid labeling and amino-terminal sequence analysis. We demonstrate that D protein (Mr 12,260) is the product of gene VI, whereas the C component is composed of the products of both gene VII (Mr 3580) and gene IX (Mr 3650). Our data further show that the proteins of genes VI, VII, and IX are not subject to proteolytic processing but are packaged into mature virions as their primary translational products. On the basis of incorporation of specific amino acids, the copy numbers of these proteins in M13 virions could be estimated relative to the number of A protein molecules. The M13 phage contains on the average 5 molecules of A protein, 5 molecules of VI protein and 3-4 molecules of both VII protein and IX protein. These copy numbers remained unchanged in M13 recombinant phages of up to two times the length of wild-type phages, a fact that indicates that these minor capsid proteins are located at either one or both ends of the phage filament.

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.