Asymmetric transcription of bacteriophage Mu-1

Unusual transcriptional and translational regulation of the bacteriophage Mu mom operon

The bacteriophage Mu mom gene encodes a novel DNA modification that protects the viral genome against a wide variety of restriction endonucleases. Expression of mom is subject to a series of unusual regulatory controls. Transcription requires the action of a phage-encoded protein, C, which binds (probably as a dimer) the mom promoter from -33 to -52 (with respect to the transcription start site) in two adjacent DNA major grooves on one face of the helix. No apparent direct interaction between C and the host RNA polymerase (RNAP) is evident; however, C binding alters mom DNA conformation. In the absence of C, RNAP binds the mom promoter at a site that results in transcription in a direction away from the mom gene. The function of this transcription is unknown. An additional layer of transcriptional regulation complexity is due to the fact that the host Dam DNA-(N6-adenine)methyltransferase is required. Dam methylation of three closely spaced upstream GATC sequences is necessary to prevent binding by the host protein, OxyR, which acts as a repressor. Repression is not mediated by inhibition of C binding, but rather through interference with C-mediated recruitment of RNAP to the correct site. Translation of mom is regulated by the phage Com protein. Com is only 62 amino acids long and contains a zinc finger-like structure (coordinated by four cysteine residues) in the amino terminal domain. Com binds mom mRNA 5' to the mom open reading frame, whose translation start signals are contained in a stem-loop translation-inhibition-structure. Com binding to its target site (5' to and adjacent to the translation-inhibition-structure) results in a stable change in RNA secondary structure that exposes the translation start signals.

Bidirectional transcription in the mom promoter region of bacteriophage Mu

Transcription of the Mu mom operon requires activation by the phage gene product, C, a site-specific DNA binding protein. Previous in vivo and in vitro footprinting studies showed that Escherichia coli RNA polymerase (Esigma70=RNAP) bound the wild-type (wt) mom promoter (Pmom) region in the absence of C; this site, now designated momP2 (-11 to -64), is slightly upstream of, but overlapping with, momP1 (+16 to -49), the functional binding site for mom operon (rightward) transcription. The location/distribution of KMnO4-sensitive sites on the two DNA strands suggested that RNAP bound at momP2 was in an open-complex, but that transcription was in the opposite direction. Here, we used both runoff transcription and reverse transcriptase-primer extension sequencing to provide direct evidence that in the absence of C protein, RNAP carries out leftward transcription from momP2 both in vitro and in vivo. In addition, the 5' ends of these transcripts were mapped to the same upstream initiation site, -58G, relative to the initiation site of C-activated rightward transcription. We also present evidence that leftward transcription from momP2 requires RNAP recognition of an UP-element by the carboxyl-terminal domain of the alpha subunit.

Activation of the bacteriophage Mu lys promoter by Mu C protein requires the sigma 70 subunit of Escherichia coli RNA polymerase

Bacteriophage Mu C protein, a product of the middle operon, is required for activation of the four Mu late promoters. To address its mechanism of action, we overproduced the approximately 16.5-kilodalton C protein from a plasmid containing the C gene under the control of a phage T7 promoter and ribosome-binding site. A protein fraction highly enriched for Escherichia coli RNA polymerase (E sigma 70) and made from the overproducing strain was able to activate transcription in vitro from both the tac promoter (Ptac) and a Mu late promoter, Plys. The behavior of Plys was similar in vivo and in vitro; under both conditions, transcription was C dependent and the RNA 5' ends were identical. When anti-sigma 70 antibody was added to C-dependent transcription reactions containing both Ptac and Plys templates, transcription from both promoters was inhibited; transcription was restored by the addition of excess E sigma 70. This result suggests that C-dependent activation of Plys requires sigma 70. Further supporting evidence was provided by a reconstitution experiment in which an E sigma 70-depleted fraction containing C was unable to activate transcription from Plys unless both purified sigma 70 and core polymerase were added. These results strongly suggest that C is not a new sigma factor but acts as an activator for E sigma 70-dependent transcription.

Characterization of the C operon transcript of bacteriophage Mu

Mu transcription occurs in three phases: early, middle, and late. Middle transcription occurs in the region of the C gene, which encodes the transactivator for late transcription. A middle promoter, Pm, was previously localized between 0.28 and 1.2 kilobase pairs upstream of C. We used S1 nuclease mapping with both unlabeled and radiolabeled capped RNAs from induced lysogens to characterize C transcription and identify its promoter. The C transcription initiation site was localized to a 4-base-pair region, approximately 740 base pairs upstream of C within the region containing Pm. Transcription of C was activated between 4 and 8 min after induction of cts and Cam lysogens and increased throughout the lytic cycle. Significant C transcription did not occur in replication-defective Aam lysogens. These kinetic and regulatory characteristics identify the C transcript as a middle RNA species and demonstrate that Pm is the C promoter. DNA sequence analysis of the Pm region showed a good -10, but poor -35, site homology to the Escherichia coli RNA polymerase consensus sequence. In addition, the sequence demonstrated that C is the distal gene in a middle operon containing several open reading frames. S1 mapping also showed an upstream transcript with a 3' end in the Pm region at a sequence strongly resembling a Rho-independent terminator. The regulatory characteristics of this RNA are consistent with this terminator, t9.2, being the early operon terminator.

Minute amounts of RNA are synthesized from several regions of the bacteriophage Mu DNA during the lysogenic state

The transcription of phage Mu DNA during the lysogenic state has been quantitatively analysed. For this purpose pulse-labelled RNA from two lysogens and from their nonlysogenic parental strains were hybridized to non-overlapping Mu DNA restriction fragments covering the whole phage genome. The data revealed that all regions of the prophage are transcribed at low rates and that phage promoters are involved in this transcription. For this study an improved assay for quantitative filter hybridization was employed. The high sensitivity and reproducibility that can be obtained with the assay make it suitable for the quantitative analysis of minute amounts of mRNA.

An assay for quantitative nucleic acid hybridization on membrane filters

A quantitative nucleic acid hybridization assay based on a 6-mm-diameter nitrocellulose membrane filter and only 20 microliters of hybridization mixture per determination is described. As a consequence of the small ratio of hybridization volume to membrane surface, the hybridization rates reached in this system are higher than those obtained at volume to surface ratios of conventional protocols, allowing even RNA at very low concentrations to complete hybridization. This advantage, together with the high reproducibility and hybrid stability obtained with the assay, increases the ability of the filter hybridization technique to analyze quantitatively minute amounts of RNA.

Bacteriophage Mu late promoters: four late transcripts initiate near a conserved sequence

Late transcription of bacteriophage Mu, which results in the expression of phage morphogenetic functions, is dependent on Mu C protein. Earlier experiments indicated that Mu late RNAs originate from four promoters, including the previously characterized mom promoter. S1 nuclease protection experiments were used to map RNA 5' ends in the three new regions. Transcripts were initiated at these points only in the presence of C and were synthesized in a rightward direction on the Mu genome. Amber mutant marker rescue analysis of plasmid clones and limited DNA sequencing demonstrated that these new promoters are located between C and lys, upstream of I, and upstream of P within the N gene. A comparison of the promoter sequences upstream from the four RNA 5' ends yielded two conserved sequences: the first (tA . . cT, where capital and lowercase letters indicate 100 and 75% base conservation, respectively), at approximately -10, shares some similarity with the consensus Escherichia coli sigma 70 -10 region, while the second (ccATAAc CcCPuG/Cac, where Pu indicates a purine), in the -35 region, bears no resemblance to the E. coli -35 consensus. We propose that these conserved Mu late promoter consensus sequences are important for C-dependent promoter activity. Plasmids containing transcription fusions of these late promoters to lacZ exhibited C-dependent beta-galactosidase synthesis in vivo, and C was the only Mu product needed for this transactivation. As expected, the late promoter-lacZ fusions were activated only at late times after induction of a Mu prophage. The C-dependent activation of lacZ fusions containing only a few bases of the 5' end of Mu late RNA and the presence of altered promoter sequences imply that C acts at the level of transcription initiation.

Morphogenetic structures present in lysates of amber mutants of bacteriophage Mu

The Mu phage particle is structurally similar to that of the T-even phages, consisting of an icosahedral head and contractile tail. This study continues an analysis of the morphogenesis of the Mu phage particle by defining the structural defects resulting from mutations in specific Mu genes. Defective lysates produced by induction of 55 amber mutants, representing 24 essential genes, were examined in the electron microscope and categorized into eight classes based on the observed phage-related structures. (1) Mutations in genes lys, F and G, and some H mutations, did not cause a visible alteration in particle structure. (2) Mutants defective in genes A, B, and C produced no detectable phage structures, consistent with their lack of production of late RNA. (3) Extracts defective in genes L, M, Y, N, P, Q, V, W, and R contained only head structures, and these appeared normal. (4) K-defective mutants accumulated free heads as well as free tails which were longer than normal and variable in length. (5) Tails which appeared normal were the only structures found in T- and some I-defective extracts. (6) Free tails and empty heads accumulated in D-, E-, and some I- and H-defective extracts. These heads were as much as 16% smaller than normal heads. The heads found in some I amber lysates had a protruding neck-like structure and unusually thick shells suggestive of a scaffolding-like structure. (7) Defects in gene J resulted in the accumulation of unattached tails and full heads. (8) Previous analysis of lysates produced by inversion-defective gin mutants fixed in the G(+) orientation demonstrated that S and U mutants produced particles lacking tail fibers (F.J. Grundy and M.M. Howe (1984), Virology 134, 296-317). In these experiments with Gin+ phages S and U mutants produced apparently normal phage particles. Presumably the tail fiber defects were masked by the production of S' and U' proteins by G(-) phages in the population.

Involvement of the invertible G segment in bacteriophage mu tail fiber biosynthesis

The orientation [G(+) or G(-)] of the invertible G segment of bacteriophage Mu DNA determines the host range specificity of the phage particles. In this study the hypothesis that the G segment genes are involved in synthesis of Mu tail fibers has been tested. Serum blocking power (SBP) assays demonstrated that among Mu late gene mutants only those defective in genes S or U encoded by the G segment were defective in G(+) SBP and that they lacked the same antigens. Electron microscopy of lysates produced by inversion-defective gin mutants (isolated by their inability to complement a hin inversion-defective mutant of the Salmonella phase variation segment) showed that G(+) phages with amber mutations in S or U made tail-fiberless particles with contracted tail sheaths. Inversion of G to the G(-) orientation or suppression of the amber mutations restored the normal phage particle morphology. These experiments demonstrate that genes S and U are required for Mu G(+) tail fiber biosynthesis and/or attachment.

Cloning and expression of the phage Mu A gene

We have cloned the phage Mu A gene, with and without the gene ner, under the control of the pL promoter of phage lambda in a multicopy plasmid vector. We demonstrate that plasmid-carrying cells are able to support growth of superinfecting Mu A am phages in a temperature-dependent fashion in a host strain carrying a defective lambda prophage which specifies the cI857-coded lambda repressor. In addition, we show that the presence of the ner gene reduces the efficiency of plating of the superinfecting phage. Analysis of proteins specified by the cloned Mu fragments indicates that two proteins, 70 and 33 kDal, are synthesized. The level of synthesis, compared to that of the vector-encoded beta-lactamase, was found to increase with temperature. This indicates that their transcription is driven by the pL promoter. The Mr of the 70-kDal protein is identical to that previously observed for pA.

The early promoter of bacteriophage Mu: definition of the site of transcript initiation

The early promoter of bacteriophage Mu has been identified and characterized by a nitrocellulose filter binding assay and analysis of RNA products transcribed in vitro and in vivo. A tight, heparin resistant, RNA polymerase-DNA binding site overlaps the left Mu Hind III site. In vitro [gamma 32P] ATP initiated transcription begins approximately 25 nucleotides to the right of the Hind III restriction site. Dinucleotide initiation with ApA and S1 mapping of in vitro and in vivo transcripts shows that transcription is initiated 1028 base pairs from the Mu genetic left end.

Production and modification of Mu (G-) phage particles in E. coli K12 and Erwinia

We studied the amount of Mu(G+) and Mu(G−) phages in different Mu lysates prepared either upon induction or upon infection ofE. coliandErwiniastrains. We also looked at the level of expression of the modification function (mom) by Mu(G−) phages, both after induction and after infection ofE. coliandErwinia. The expression ofmomseems to be regulated in the same manner inE. coliand in the strain ofErwinia carotovoratested. The proportion of both types of Mu(G+) and Mu(G−) phages in induced lysates is very variable and we found growth conditions favouring the production of Mu(G−) particles. This should extend the use of Mu as a genetic tool and as a generalized transducing phage to many enterobacteria.

Nucleotide sequence of the immunity region of bacteriophage Mu

The leftmost 1590 bp of Mu DNA covering the immunity region have been sequenced. This region encodes the cI repressor, the cII or ner function and the beginning of gene A. An open reading frame extends from position 863 to 342 on the l-strand corresponding to cI protein with a molecular weight of 19212. It is preceded by a sequence resembling a promoter. To the right of the HindIII site an open reading frame extends from position 1099 to 1323 corresponding to cII or ner protein (molecular weight of 8505) followed by the beginning of gene A at position 1328. Between position 863 and 1099 promoters for leftward and rightward transcription and operator-like structures can be recognized in the sequence. The promoter for rightward transcription overlaps with the HindIII site and coincides with a RNA polymerase binding site as demonstrated by electron microscopy.

Instability of transposase activity: evidence from bacteriophage mu DNA replication

Transposition of genetic elements involves coupled replication and integration events catalyzed in part by a class of proteins called transposases. We have asked whether the transposase activity of bacteriophage Mu (the Mu A protein) is stable and capable of catalyzing multiple rounds of coupled replication/integration, or whether its continued synthesis is required to maintain Mu DNA replication. Inhibition of protein synthesis during the lytic cycle with chloramphenicol inhibited Mu DNA synthesis with a half-life of approximately 3 min, demonstrating a need for continued protein synthesis to maintain Mu DNA replication. Synthesis of specific Mu-encoded proteins was inhibited by infecting a host carrying a temperature-sensitive suppressor, at permissive temperature, with Mu amber phages, then shifting to nonpermissive temperature. When Aam phages were used, Mu DNA replication was inhibited with kinetics essentially identical to those with chloramphenicol addition; hence, it is likely that continued synthesis of the Mu A protein is required to maintain Mu DNA replication. The data suggest that the activity of the Mu A protein is unstable, and raise the possibility that the Mu A protein and other transposases may be used stoichiometrically rather than catalytically.

Plasmid vectors derived from phage Mu allow direct selection of transformants containing cloned HindIII and PstI fragments

The vector plasmids pKN001 and pKN80 both contain the EcoRi.C fragment of E.coli phage Mu DNA which codes for a killing function that is efficiently expressed upon transformation into Mu-sensitive bacteria. By in vitro insertion of HindIII fragments at the single HindIII site of pKN80 or of PstI fragments at the single PstI site of pKN001 the killing function is inactivated. The resulting plasmids have a selective advantage over the religated vector when transformed into Mu-sensitive bacteria. More than 90% of the transformations contain hybrid plasmids. These results show the usefulness of Mu DNA containing plasmids pKN001 and pKN80 as vectors that allow the direct selection for recombinant plasmids.

Transcription of bacteriophage Mu. II. Transcription of the repressor gene

Using pBR322 as a vector, three plasmids were constructed, pGP2, pGP3, and pGP7, containing respectively 5, 100, 700-950, and 1,000 base pairs derived from the immunity end of bacteriophage Mu. All three plasmids contain a functional repressor gene coding for a thermosensitive repressor. RNAs produced when the DNA of these plasmids was used as template in in vitro RNA synthesis, were analysed by hybridization to the DNA of several lambda pMu transducing phages. In spite of the differences in length of the Mu fragments all three plasmids show the same amount of Mu specific l-strand transcription. Since the repressor gene comprises at least 70% of the Mu fragments of pGP3 and pGP7, these results indicate that the repressor gene c of bacteriophage Mu is transcribed on the l-strand. Analysis of in vivo RNA from cells harboring the plasmids pGP2, pGP3, or pGP7 also indicates that the repressor gene of phage Mu is transcribed on the l-strand, as all Mu-specific RNA extracted from these cells at 28 degrees C hybridizes with the l-strand of the first 3,100 basepairs from the Mu immunity end.

Mapping of the modification function of temperate phage Mu-1

Using internal deletions in the Mu genome, we have mapped the gene coding for Mu modification in the beta segment of Mu DNA.

Origin and binding specificity of protein(s) coded for by Mu prophages

Crude extracts of bacteria lysogenic for temperature phage Mu contain proteins that retain specifically Mu DNA on nitrocellulose filters. The amount of binding protein is directly proportional to the number of Mu prophages per E. coli genome. Specificity of the binding reaction could be demonstrated by using heterologous DNAs as substrate and by a competition experiment. By using hybrid plasmids containing different amounts of the immunity end and extending to various degrees into MuDNA, it was found that the binding activity is coded for by the left 1,000 nucleotide-pair HindIII fragment. When using these hybrid plasmids as binding substrate, two different binding sites for the immunity product were detected. Joining of the MucI gene to the left lambda early promoter resulted in increased production of immunity protein at elevated temperature. A possible explanation for the relatively low amounts of immunity protein in all of the different strains studied is discussed.

In vitro constructed plasmids containing both ends of bacteriophage Mu DNA express phage functions

The construction of a plasmid carrying the right end PstI . B fragment of bacteriophage Mu DNA and of plasmids containing in addition the left end EcoRI.C fragment of Mu DNA into the vector pBR322 is described. Inversion of the G segment still occurs in all these plasmids. By marker rescue and complementation experiments the right PstI cleavage site was located to the left of gene Q. The composite plasmids inheriting also the left end EcoRI fragment of Mu DNA express both the immunity and killing functions of Mu and direct the in vitro synthesis of presumably Mu-specific polypeptides. These results demonstrates that Mu-specific functions can be analyzed from cloned fragments.

Mechanism of phage Mu-1 integration: nalidixic acid treatment causes clustering of Mu-1-induced mutations near replication origin

Frequencies of Mu-1-induced mutants of Escherichia coli have been compared under two different experimental conditions: cells in exponential growth and the same cells treated with nalidixic acid. The average of values obtained from the nalidixic acid-treated culture is 3 times higher than that obtained from the control. Individual ratios of the frequency of mutants in the two cultures yield decreasing values from 6 to 1, starting from the point of origin of DNA replication to the termini of DNA replication. These results are compatible with the idea that Mu-1 integrates at the replication fork.

Early events in the replication of Mu prophage DNA

To determine whether the early replication of Mu prophage DNA proceeds beyond the termini of the prophage into hose DNA, the amounts of both Mu DNA and the prophage-adjacent host DNA sequences were measured using a DNA-DNA annealing assay after induction of the Mu vegetative cycle. Whereas Mu-specific DNA synthesis began 6 to 8 min after induction, no amplification of the adjacent DNA sequences was observed. These data suggest that early Mu-induced DNA synthesis is constrained within the boundaries of the Mu prophage. Since prophage Mu DNA does not undergo a prophage lambda-like excision from its original site after induction (E. Ljungquist and A. I. Bukhari, Proc. Natl. Acad. Sci. U.S.A. 74:3143--3147, 1977), we propose the existence of a control mechanism which excludes prophage-adjacent sequences from the initial mu prophage replication. The frequencies of the Mu prophage-adjacent DNA sequences, relative to other Escherichia coli genes, were not observed to change after the onset of Mu-specific DNA replication. This suggests that these regions remain associated with the host chromosome and continue to be replicated by the chromosomal replication fork. Therefore, we conclude that both the Mu prophage and adjacent host sequences are maintained in the host chromosome, rather than on an extrachromosomal form containing Mu and host DNA.

Characterization of the inhomogeneous DNA in virions of bacteriophage Mu by DNA reannealing kinetics

The DNA of bacteriophage Mu has been studied to characterize a region of inhomogeneous sequence that occurs at one end of the molecule. The kinetics of reassocation of tracer amounts of labeled host DNA in the presence of Mu DNA show that Mu DNA contains a complete selection of host sequences. These host sequences are shown to be covalently attached to phage-specific sequences and are present at a concentration that accounts for the inhomogeneity observed in the electron microscope. The significance and possible function of the host DNA attachment is discussed.

Transcription of bacteriophage mu. An analysis of the transcription pattern in the early phase of phage development

It has previously been shown that the transcription of Mu is asymmetric and takes place on the heavy DNA strand (Bade, 1972; Wijffelman et al., 1974). The direction of transcription of Mu has now been determined by RNA-DNA hybridizations between purified Mu-RNA and the separated strands of lambda-Mu hybrid phages. The direction of transcription is from the c-gene (immunity gene) end of the heavy strand to the beta-end (immunity distal end) (Fig. 1). Thermo-inducible, defective Mu lysogens, in which the prophage is deleted from the beta-end, have a normal early transcription pattern, but the increase of RNA at later times is absent. A defective lysogen, which contains only the immunity gene c and the genes A and B, still has an early transcription pattern similar to that of the wild-type. Therefore, we conclude that the early RNA is transcribed from that region of the Mu genome. The early Mu-RNA synthesis is negatively regulated with a minimum rate of transcription at 9 minutes after induction. Before the onset of the late RNA synthesis, at about 22 minutes there is a rather long period in which the rate of Mu-RNA synthesis slowly increases. Using DNA strands of lambda-Mu hybrids which contain only that part of the Mu-DNA on which the early RNA synthesis takes place, we have determined that during the first half in the intermediate phase only early genes are transcribed. The amount of Mu-RNA synthesized by a Mu prophage carrying the X-mutation, which influences the excision of Mu, is greatly reduced. Negative regulation of early transcription occurs normally in this mutant.

Isolation of heterogeneous circular DNA from induced lysogens of bacteriophage Mu-1

Covalently-closed circular DNA molecules are formed after induction of phage Mu cts4 and after infection with phage Mu cts4. The circular molecules obtained after induction have a molecular length range from 36.5 to 156.7 kilobases as measured by electron microscopic techniques. These heterogeneous molecules have no consistent correlation to exact multiples of a Mu genome equivalent (37.3 +/- 1.2 kilobases). Direct evidence is given that these molecules contain phage Mu DNA that is covalently linked to other DNA sequences.

A mutant of Escherichia coli with a new, highly efficient promoter for the lactose operon

We have isolated a mutant of E. coli whose maximal rate of synthesis of lac mRNA is 25-fold greater than that of its parental wild-type strain. The mutant also shows alterations in the kinetics of beta-galactosidase synthesis, the functional half-life of beta-galactosidase mRNA, and the properties of lac repressor.