Isolation of mutations defining five new cistrons essential for development of bacteriophage Mu

Endolysin Regulation in Phage Mu Lysis

Bacteriophage Mu is a paradigm coliphage studied mainly because of its use of transposition for genome replication. However, in extensive nonsense mutant screens, only one lysis gene has been identified, the endolysin gp22. This is surprising because in Gram-negative hosts, lysis by Caudovirales phages has been shown to require proteins which disrupt all three layers of the cell envelope. Usually this involves a holin, an endolysin, and a spanin targeting the cytoplasmic membrane, peptidoglycan (PG), and outer membrane (OM), respectively, with the holin determining the timing of lysis initiation. Here, we demonstrate that gp22 is a signal-anchor-release (SAR) endolysin and identify gp23 and gp23.1 as two-component spanin subunits. However, we find that Mu lacks a holin and instead encodes a membrane-tethered cytoplasmic protein, gp25, which is required for the release of the SAR endolysin. Mutational analysis showed that this dependence on gp25 is conferred by lysine residues at positions 6 and 7 of the short cytoplasmic domain of gp22. gp25, which we designate as a releasin, also facilitates the release of SAR endolysins from other phages. Moreover, the entire length of gp25, including its N-terminal transmembrane domain, belongs to a protein family, DUF2730, found in many Mu-like phages, including those with cytoplasmic endolysins. These results are discussed in terms of models for the evolution and mechanism of releasin function and a rationale for Mu lysis without holin control. IMPORTANCE Host cell lysis is the terminal event of the bacteriophage infection cycle. In Gram-negative hosts, lysis requires proteins that disrupt each of the three cell envelope components, only one of which has been identified in Mu: the endolysin gp22. We show that gp22 can be characterized as a SAR endolysin, a muralytic enzyme that activates upon release from the membrane to degrade the cell wall. Furthermore, we identify genes 23 and 23.1 as spanin subunits used for outer membrane disruption. Significantly, we demonstrate that Mu is the first known Caudovirales phage to lack a holin, a protein that disrupts the inner membrane and is traditionally known to release endolysins. In its stead, we report the discovery of a lysis protein, termed the releasin, which Mu uses for SAR endolysin release. This is an example of a system where the dynamic membrane localization of one protein is controlled by a secondary protein.

Genetic analysis of phage Mu Mor protein amino acids involved in DNA minor groove binding and conformational changes

Gene expression during lytic development of bacteriophage Mu occurs in three phases: early, middle, and late. Transcription from the middle promoter, P(m), requires the phage-encoded activator protein Mor and the bacterial RNA polymerase. The middle promoter has a -10 hexamer, but no -35 hexamer. Instead P(m) has a hyphenated inverted repeat that serves as the Mor binding site overlapping the position of the missing -35 element. Mor binds to this site as a dimer and activates transcription by recruiting RNA polymerase. The crystal structure of the His-Mor dimer revealed three structural elements: an N-terminal dimerization domain, a C-terminal helix-turn-helix DNA-binding domain, and a β-strand linker between the two domains. We predicted that the highly conserved residues in and flanking the β-strand would be essential for the conformational flexibility and DNA minor groove binding by Mor. To test this hypothesis, we carried out single codon-specific mutagenesis with degenerate oligonucleotides. The amino acid substitutions were identified by DNA sequencing. The mutant proteins were characterized for their overexpression, solubility, DNA binding, and transcription activation. This analysis revealed that the Gly-Gly motif formed by Gly-65 and Gly-66 and the β-strand side chain of Tyr-70 are crucial for DNA binding by His-tagged Mor. Mutant proteins with substitutions at Gly-74 retained partial activity. Treatment with the minor groove- and GC-specific chemical chromomycin A(3) demonstrated that chromomycin prevented His-Mor binding but could not disrupt a pre-formed His-Mor·DNA complex, consistent with the prediction that Mor interacts with the minor groove of the GC-rich spacer in the Mor binding site.

Assembly of both the head and tail of bacteriophage Mu is blocked in Escherichia coli groEL and groES mutants

Like several other Escherichia coli bacteriophages, transposable phage Mu does not develop normally in groE hosts (M. Pato, M. Banerjee, L. Desmet, and A. Toussaint, J. Bacteriol. 169:5504-5509, 1987). We show here that lysates obtained upon induction of groE Mu lysogens contain free inactive tails and empty heads. GroEL and GroES are thus essential for the correct assembly of both Mu heads and Mu tails. Evidence is presented that groE mutations inhibit processing of the phage head protein gpH as well as the formation of a 25S complex suspected to be an early Mu head assembly intermediate.

Identification of a positive regulator of the Mu middle operon

Transcription of bacteriophage Mu occurs in a regulatory cascade consisting of three phases: early, middle, and late. The 1.2-kb middle transcript is initiated at Pm and encodes the C protein, the activator of late transcription. A plasmid containing a Pm-lacZ operon fusion was constructed. beta-Galactosidase expression from the plasmid increased 23-fold after Mu prophage induction. Infection of plasmid-containing cells with lambda phages carrying different segment of the Mu early region localized the Pm-lacZ transactivation function to the region containing open reading frames E16 and E17. Deletion and linker insertion analyses of plasmids containing this region identified E17 as the transactivator; therefore we call this gene mor, for middle operon regulator. Expression of mor under the control of a T7 promoter and T7 RNA polymerase resulted in the production of a single polypeptide of 17 kDa as detected by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Insertion of a linker into mor substantially reduced the ability of Mu to form plaques. When growth of the mor mutant was assayed in liquid, lysis was delayed by about 50 min and the burst size was approximately one-fifth that of wild-type Mu. The mor requirement for plaque formation and normal growth kinetics was abolished when C protein was provided in trans, indicating that the primary function of Mor is to provide sufficient C for late gene expression. Comparison of the predicted amino acid sequence of Mor with other proteins revealed that Mor and C share substantial amino acid sequence homology.

Instability of bacteriophage Mu transposase and the role of host Hfl protein

The activity of the transposase of bacteriophage Mu is unstable, requiring the protein to be synthesized throughout the lytic cycle (Pato and Reich, 1982). Using Western blot analysis, we analysed the stability of the transposase protein during the lytic cycle and found that it, too, is unstable. The instability of the protein is observed both in the presence and the absence of Mu DNA replication, and is independent of other Mu-encoded proteins and the transposase binding sites at the Mu genome ends. Stability of the protein is enhanced in host strains mutated at the hfl locus; however, stability of the transposase activity is not enhanced in these strains, suggesting that functional inactivation of the protein is not simply a result of its proteolysis.

Bacteriophage Mu sites and functions involved in the inhibition of lambda::mini-Mu growth

To better understand the nature of the mini-Mu-directed process which results in inhibition of lambda::mini-Mu growth we characterized spontaneous deletion mutants of the lambda::mini-Mu phage. On the basis of analysis of the deletion endpoints, mini-Mu replication functions, and integration and inhibition properties, the lambda::mini-Mu deletion mutants were divided into five classes which define the Mu sites and functions involved in lambda::mini-Mu growth inhibition. Class 1 mutants, which still exhibit lambda::mini-Mu growth inhibition, collectively delete all the Mu late functions encoded by the mini-Mu. Class 2 and 5 mutants, which show cis-dominant defects in inhibition and integration, delete the right and left mini-Mu attachment sites, respectively. Phages of Classes 3 and 4, which delete the Mu B or A and B genes, respectively, show recessive defects in growth inhibition. The properties of these mutants define the Mu replication functions, A and B, and the Mu attachment sites as essential for the inhibition of lambda::mini-Mu growth. The observation that the sites and functions essential for Mu replication also have requisite roles in the inhibition of lambda::mini-Mu growth suggests that inhibition results from mini-Mu-promoted replicative interference of lambda::mini-Mu development.

Nonsense mutants defining seven new genes of the lipid-containing bacteriophage PR4

Thirty-eight new nonsense mutants of the lipid-containing bacteriophage PR4 were isolated. These mutants define seven new viral genes, including the gene encoding the terminal genome protein and an accessory lytic factor. The defective gene products produced in uv-irradiated cells infected with representative mutants from each of the new genetic groups were identified using sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). Extracts of uv-irradiated cells infected with nonsense mutants that produce a defective major capsid protein, P2, also lacked two lower molecular weight proteins. The synthesis of all three protein species was recovered in cells infected with one-step revertants of two independent major capsid protein mutants, suggesting the possibility of post-translational processing or overlapping genes. The time course of protein synthesis in wild-type PR4-infected cells was examined using SDS-PAGE. These analyses revealed at least 34 proteins produced following phage PR4 infection that were not present in uninfected control cultures.

Kinetics and regulation of transcription of bacteriophage Mu

Mu transcription was analyzed by hybridization of [3H]uridine pulse-labeled RNA from heat-induced Mu lysogens to Mu DNA restriction fragments on nitrocellulose blots. Based on their time of appearance and dependence on Mu functions, we have defined three classes of transcripts: early, middle, and late. Replication-defective prophages containing A or B amber mutations or a deletion of the beta (right) end produced only early RNA derived from the left-most 8 to 10 kb of the Mu genome. A replication-proficient C amber mutant exhibited similar early transcription but at later times also produced middle transcripts from a region including C, which encodes the activator of late transcription. The C mutant did not produce late transcripts from the right-most 26 kb of the Mu genome encoding genes involved in phage morphogenesis and release. These results indicate that Mu DNA replication is required for efficient expression of middle RNA, which is itself required for expression of late transcripts. Amber mutations in essential genes other than A, B, and C had no significant effect on transcription except for polarity of one E mutation. Uninduced Mu c+ and Mu cts prophages produced very low levels of Mu-specific RNA derived from several regions including the c (immunity) gene and the region between genes B and C.

Characterization of amber mutations in bacteriophage Mu transposase: a functional analysis of the protein

We have characterized a series of amber mutations in the A gene of bacteriophage Mu encoding the phage transposase. We tested different activities of these mutant proteins either in a sup0 strain or in different sup bacteria. In conjunction with the results described in the accompanying paper by Bétermier et al. (1989) we find that the C-terminus of the protein is not absolutely essential for global transposase function, but is essential for phage growth. Specific binding to Mu ends is defined by a more central domain. Our results also reinforce the previous findings (Bétermier et al., 1987) that more than one protein may be specified by the A gene.

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.

In vivo mutagenesis of bacteriophage Mu transposase

We devised a method for isolating mutations in the bacteriophage Mu A gene which encodes the phage transposase. Nine new conditional defective A mutations were isolated. These, as well as eight previously isolated mutations, were mapped with a set of defined deletions which divided the gene into 13 100- to 200-base-pair segments. Phages carrying these mutations were analyzed for their ability to lysogenize and to transpose in nonpermissive hosts. One Aam mutation, Aam7110, known to retain the capacity to support lysogenization of a sup0 host (M. M. Howe, K. J. O'Day, and D. W. Shultz, Virology 93:303-319, 1979) and to map 91 base pairs from the 3' end of the gene (R. M. Harshey and S. D. Cuneo, J. Genet. 65:159-174, 1987) was shown to be able to complement other A mutations for lysogenization, although it was incapable of catalyzing either the replication of Mu DNA or the massive conservative integration required for phage growth. Four Ats mutations which map at different positions in the gene were able to catalyze lysogenization but not phage growth at the nonpermissive temperature. Phages carrying mutations located at different positions in the Mu B gene (which encodes a product necessary for efficient integration and lytic replication) were all able to lysogenize at the same frequency. These results suggest that the ability of Mu to lysogenize is not strictly correlated with its ability to perform massive conservative and replicative transposition.

Localization and DNA sequence analysis of the C gene of bacteriophage Mu, the positive regulator of Mu late transcription

The C gene of bacteriophage Mu, required for transcription of the phage late genes, was localized by construction and analysis of a series of deleted derivatives of pKN50, a plasmid containing a 9.4 kb Mu DNA fragment which complements Mu C amber mutant phages for growth. One such deleted derivative, pWM10, containing only 0.5 kb of Mu DNA, complements C amber phages and transactivates the mom gene, one of the Mu late genes dependent on C for activation. The DNA sequence of the 0.5 kb fragment predicts a single long open reading frame coding for a 140 amino acid protein. Sequence analysis of DNA containing a C amber mutation located the base change to the second codon of this reading frame. Generation of a frameshift mutation by filling in a BglII site spanning codon 114 of this reading frame resulted in the loss of C complementation and transactivation activity. These results indicate that this open reading frame encodes the Mu C gene product. Comparison of the predicted amino acid sequence of the C protein with those of other transcriptional regulatory proteins revealed some similarity to a region highly conserved among bacterial sigma factors.

A truncated form of the bacteriophage Mu B protein promotes conservative integration, but not replicative transposition, of Mu DNA

The phage-encoded proteins required for conservative integration of infecting bacteriophage Mu DNA were investigated. Our findings show that functional gpA, an essential component of the phage transposition system, is required for integration. The Mu B protein, which greatly enhances replicative transposition of Mu DNA, is also required. Furthermore, a truncated form of gpB lacking 18 amino acids from the carboxy terminus is blocked in replicative transposition, but not conservative integration. Our results point to a more prominent role for gpB than simply a replication enhancer in Mu DNA transposition. The ability of a truncated form of B to function in conservative integration, but not replicative transposition, also suggests a key role for the carboxy-terminal domain of the protein in the replicative reaction. The existence of a shortened form of gpB, which uncouples conservative integration from replicative transposition, should be invaluable for future dissection of Mu DNA transposition.

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.

Multiple factors and processes involved in host cell killing by bacteriophage Mu: characterization and mapping

The regions of bacteriophage Mu involved in host cell killing were determined by infection of a lambda-immune host with 12 lambda pMu-transducing phages carrying different amounts of Mu DNA beginning at the left end. Infecting lambda pMu phages containing 5.0 (+/- 0.2) kb or less of the left end of Mu DNA did not kill the lambda-immune host, whereas lambda pMu containing 5.1 kb did kill, thus locating the right end of the kil gene between approximately 5.0 and 5.1 kb. For the Kil+ phages the extent of killing increased as the multiplicity of infection (m.o.i.) increased. In addition, killing was also affected by the presence of at least two other regions of Mu DNA: one, located between 5.1 and 5.8 kb, decreased the extent of killing; the other, located between 6.3 and 7.9 kb, greatly increased host cell killing. Killing was also assayed after lambda pMu infection of a lambda-immune host carrying a mini-Mu deleted for most of the B gene and the middle region of Mu DNA. Complementation of mini-Mu replication by infecting B+ lambda pMu phages resulted in killing of the lambda-immune, mini-Mu-containing host, regardless of the presence or absence of the Mu kil gene. The extent of host cell killing increased as the m.o.i. of the infecting lambda pMu increased, and was further enhanced by both the presence of the kil gene and the region located between 6.3 and 7.9 kb. These distinct processes of kil-mediated killing in the absence of replication and non-kil-mediated killing in the presence of replication were also observed after induction of replication-deficient and kil mutant prophages, respectively.

A Mu gin complementing function and an invertible DNA region in Escherichia coli K-12 are situated on the genetic element e14

The Gin product catalyzes an inversion of 3,000 base pairs of DNA in the genome of bacteriophage Mu. The orientation of the invertible of G-region determines the host range of the phage. Gin- mutants are complemented by a host function in strain HB101 and several other Escherichia coli K-12 strains. At least three clones in the E. coli gene bank described previously (L. Clarke and J. Carbon, Cell 9:91-99, 1976) contained the gin complementing function. This function, which we named pin, catalyzes an inversion of 1,800 base pairs in the adjacent DNA. The invertible region, named the P-region, together with pin, was further subcloned on pBR322. Conjugation and transduction experiments mapped the pin gene between the genes purB and fabD near position 25 on the E. coli chromosome. Also situated in this region is e14, a cryptic, UV- excisable , genetic element (A. Greener and C.W. Hill, J. Bacteriol . 144:312-321, 1980). We demonstrated that pin and the P-region are part of e 14. The e 14 element was cloned on pBR322 by genetic manipulation techniques in vivo. It has the properties of a defective prophage containing integration and excision functions and a SOS-sensitive repressor.

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.

Nonsense mutants of the lipid-containing bacteriophage PR4

Thirty-three nonsense mutants of phage PR4 representing 12 complementation groups were isolated. One or two mutants of each group were grown on a suppressor-negative (Su-) host and characterized by the following criteria (i) proteins synthesized, (ii) level of phage DNA synthesis, and (iii) ability to assemble particles. We determined the protein and phospholipid compositions of the particles assembled in an Su- host, the presence of DNA in the particles, and the ability of the particles to adsorb to host cells. Finally each complementation group was tested for the ability to lyse an Su- host. We have identified one protein required for DNA synthesis, five proteins required for proper assembly of the protein coat and lipid membrane of the phage, two proteins required for stable insertion of DNA into the virion, a protein required for adsorption, a protein required for attachment of the adsorption protein to the virion, and a phage-encoded lytic enzyme.

Transcription initiation of Mu mom depends on methylation of the promoter region and a phage-coded transactivator

The product of the bacteriophage Mu gene mom modifies adenine residues of DNA within the consensus sequence CGAGCNPy, providing protection against various restriction endonucleases (ref. 1 and D. Kamp, personal communication cited in ref. 2). The mom gene is only expressed during lytic development of the phage. It is known that mom is nonfunctional in Escherichia coli host mutants in a gene (dam) which itself encodes an adenine methylation system. We show here that the E. coli dam gene is essential for transcription initiation of the mom gene, and that this dependence on dam seems to lie in a short segment preceding the mom coding region, which also contains the mom promoter. The sequence of this segment reveals the presence of dam methylation sites (GATC), and suggests a model for the regulation of mom gene expression based on DNA secondary structure, which may explain why mom is only expressed during phage lytic development. We also show that expression of phage-coded proteins (A, B and C) is needed for transactivation of mom transcription.