Partial correlation of the genetic and physical maps of bacteriophage Mu

The RcsC sensor kinase is required for normal biofilm formation in Escherichia coli K-12 and controls the expression of a regulon in response to growth on a solid surface

Bacteria are often found associated with surfaces as sessile bacterial communities called biofilms, and the formation of a biofilm can be split up into different stages each requiring the expression of specific genes. The production of extracellular polysaccharides (EPS) is important for the maturation of biofilms and is controlled by the Rcs two-component pathway in Escherichia coli (and other Gram-negative bacteria). In this study, we show, for the first time, that the RcsC sensor kinase is required for normal biofilm development in E. coli. Moreover, using a combination of DNA macroarray technology and transcriptional fusion analysis, we show that the expression of > 150 genes is controlled by RcsC in E. coli. In silico analyses of the RcsC regulon predicts that 50% of the genes encode proteins that are either localized to the envelope of E. coli or have activities that affect the structure/properties of the bacterial surface, e.g. the production of colanic acid. Moreover, we also show that RcsC is activated during growth on a solid surface. Therefore, we suggest that the RcsC sensor kinase may play an important role in the remodelling of the bacterial surface during growth on a solid surface and biofilm formation.

A new restriction-modification system, KpnBI, recognized in Klebsiella pneumoniae

A unique DNA restriction-modification (R-M) system has been identified in the GM236 strain of Klebsiella pneumoniae using the newly isolated phage, SBS. The system was designated KpnBI. The gene (hsdRKpnBI) complementing the restriction activity of the KpnBI system was cloned in pBR322. The nucleotide sequence of the cloned DNA revealed one open reading frame (ORF) of 3035 bp. Analysis of the deduced amino-acid sequence shows seven helicase motifs which are common to the restriction (R) subunit of both type-I and type-III R-M systems. Computer analysis (Dendrogram) of the R polypeptide of KpnBI suggests a closer relationship to EcoR124/3I, a member of type-IC family, than to other representative type-I and type-III systems.

Genomic hsd-Mu(lac) operon fusion mutants of Escherichia coli K-12

Genomic (chromosomal)hsd-Mu(lac) operon fusions have been constructed in two strains of Escherichia coli K-12 for the three hsd genes, hsdRK, hsdMK and hsdSK, using MudX and lambda placMu53. Expression of hsdK mutants ranged from 16 to 74 units (u) (with a mean of 52 u) for fusions to promoter pres and ranged from 26-75 u (also with a mean of 52 u) for fusions to promoter pmod. The expression of the two hsdK promoters was measured in different stages of growth. The pres fusion mutant showed a lag in beta-galactosidase (beta Gal) production, as compared to the pmod fusion mutant. One r-Km-K mutant (JR205) showed more than ten times the beta Gal activity of other insertion mutants. The activity of this mutant decreased by 20-fold upon the transfer of F101-102, which includes the wild-type hsd region. Positive gene-dosage effect was observed using F' plasmids containing the hsd-lacZ region.

Identification of a central regulator of stationary-phase gene expression in Escherichia coli

During carbon-starvation-induced entry into stationary phase, Escherichia coli cells exhibit a variety of physiological and morphological changes that ensure survival during periods of prolonged starvation. Induction of 30-50 proteins of mostly unknown function has been shown under these conditions. In an attempt to identify C-starvation-regulated genes we isolated and characterized chromosomal C-starvation-induced csi::lacZ fusions using the lambda placMu system. One operon fusion (csi2::lacZ) has been studied in detail. csi2::lacZ was induced during transition from exponential to stationary phase and was negatively regulated by cAMP. It was mapped at 59 min on the E. coli chromosome and conferred a pleiotropic phenotype. As demonstrated by two-dimensional gel electrophoresis, cells carrying csi2::lacZ did not synthesize at least 16 proteins present in an isogenic csi2+ strain. Cells containing csi2::lacZ or csi2::Tn10 did not produce glycogen, did not develop thermotolerance and H2O2 resistance, and did not induce a stationary-phase-specific acidic phosphatase (AppA) as well as another csi fusion (csi5::lacZ). Moreover, they died off much more rapidly than wild-type cells during prolonged starvation. We conclude that csi2::lacZ defines a regulatory gene of central importanc e for stationary phase E. coli cells. These results and the cloning of the wild-type gene corresponding to csi2 demonstrated that the csi2 locus is allelic with the previously identified regulatory genes katF and appR. The katF sequence indicated that its gene product is a novel sigma factor supposed to regulate expression of catalase HPII and exonuclease III (Mulvey and Loewen, 1989). We suggest that this novel sigma subunit of RNA polymerase defined by csi2/katF/appR is a central early regulator of a large starvation/stationary phase regulon in E. coli and propose 'rpoS' ('sigma S') as appropriate designations.

Mutations in trans which affect the anaerobic expression of a formate dehydrogenase (fdhF) structural gene

An operon fusion was constructed in which the chloramphenicol acetyltransferase gene (cat) is under the transcriptional control of the anaerobically-activated formate dehydrogenase (fdhF) gene promoter. It was used as a screening system for mutations in trans which prevent the formate-dependent anaerobic induction of fdhF gene expression. Five classes of mutants were identified. The defect in class I mutants was complemented by a plasmid (pBA11) or subclones thereof, which harbor genes of the Escherichia coli 58 min hyd (hydrogenase) gene cluster. They may comprise regulatory gene mutants. The phenotype of class II mutants was reversed by supplementing the medium with 100 microM MoO4(2-); WO4(2-) could substitute for MoO4(2-) in restoring anaerobic induction by formate. Similarly, class III mutants were phenotypically suppressed by inclusion of 500 microM Ni2+ in the medium; these mutants were shown to carry a defective fnr gene. The mutant of class IV had a defect in a formate dehydrogenase structural gene and that of class V was unable to grow under fermentative conditions while maintaining the capability to grow anaerobically in the presence of electron acceptors.

Transposition of lambda placMu is mediated by the A protein altered at its carboxy-terminal end

Lambda placMu phages are derivatives of bacteriophage lambda that use the transposition machinery of phage Mu to insert into chromosomal and cloned genes. When inserted in the proper fashion, these phages yield stable fusions to the Escherichia coli lac operon in a single step. We have determined the amount of DNA from the c end of phage Mu present in one of these phages, lambda placMu3, and have shown that this phage carries a 3137-bp fragment of Mu DNA. This DNA segment carries the Mu c-end attachment site and encodes the Mu genes cts62, ner+, and gene A lacking 179 bp at its 3' end (A'). The product of this truncated gene A' retains transposase activity and is sufficient for the transposition of lambda placMu. This was demonstrated by showing that lambda placMu derivatives carrying the A am1093 mutation in the A' gene are unable to transpose by themselves in a Su- strain, but their transposition can be triggered by coinfection with lambda pMu507(A+ B+). We have constructed several new lambda placMu phages that carry the A' am1093 gene and the kan gene, which confers resistance to kanamycin. Chromosomal insertions of these new phages are even more stable than those of the previously reported lambda placMu phages, which makes them useful tools for genetic analysis.

Characteristics of a ugp-encoded and phoB-dependent glycerophosphoryl diester phosphodiesterase which is physically dependent on the ugp transport system of Escherichia coli

The ugp-encoded transport system of Escherichia coli accumulates sn-glycerol-3-phosphate with high affinity; it is binding protein mediated and part of the pho regulon. Here, we report that glycerophosphoryl diesters (deacylated phospholipids) are also high-affinity substrates for the ugp-encoded system. The diesters are not taken up in an unaltered form but are hydrolyzed during transport to sn-glycerol-3-phosphate plus the corresponding alcohols. The enzyme responsible for this reaction is not essential for the translocation of sn-glycerol-3-phosphate or for the glycerophosphoryl diesters but can only hydrolyze diesters that are in the process of being transported. Diesters in the periplasm or in the cytoplasm were not recognized, and no enzymatic activity could be detected in cellular extracts. The enzyme is encoded by the last gene in the ugp operon, termed ugpQ. The product of the ugpQ gene, expressed in minicells, has an apparent molecular weight of 17,500. We present evidence that only one major phoB-dependent promoter controls all ugp genes.

Binding protein dependent transport of glycine betaine and its osmotic regulation in Escherichia coli K12

Glycine betaine, which functions as an osmoprotectant, is accumulated to high intracellular concentrations in Escherichia coli at high osmolarity. We demonstrate the presence of a high-affinity, binding protein dependent transport system for glycine betaine, which is encoded by the proU region. We show the osmotically regulated synthesis of a 32 kDa periplasmic protein that is a glycine betaine binding protein with a KD of 1.4 microM. ProU-mediated glycine betaine transport is osmotically stimulated at the level of gene expression. The osmolarity of the medium also regulates the activity of the transport system, while binding of glycine betaine to its binding protein is independent of the osmolarity. We also find a second glycine betaine transport system that is dependent on proP and exhibits a lower substrate affinity. Like ProU, this system is regulated at two levels: both gene expression and the activity of the transport system are osmotically stimulated. Using lambda plac Mu-generated lacZ operon and gene fusions, we find that expression of the proU region is osmotically regulated at the level of transcription. We cloned a part of the proU region together with the phi(proU-lacZ)hyb2 gene fusion into a multicopy plasmid and show that the DNA sequences required in cis for osmotic regulation are present on the plasmid.

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.

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.

Transposable lambda placMu bacteriophages for creating lacZ operon fusions and kanamycin resistance insertions in Escherichia coli

We have constructed several derivatives of bacteriophage lambda that translocate by using the transposition machinery of phage Mu (lambda placMu phages). Each phage carries the c end of Mu, containing the Mu cIts62, ner (cII), and A genes, and the terminal sequences from the Mu S end (beta end). These sequences contain the Mu attachment sites, and their orientation allows the lambda genome to be inserted into other chromosomes, resulting in a lambda prophage flanked by the Mu c and S sequences. These phages provide a means to isolate cells containing fusions of the lac operon to other genes in vivo in a single step. In lambda placMu50, the lacZ and lacY genes, lacking a promoter, were located adjacent to the Mu S sequence. Insertion of lambda placMu50 into a gene in the proper orientation created an operon fusion in which lacZ and lacY were expressed from the promoter of the target gene. We also introduced a gene, kan, which confers kanamycin resistance, into lambda placMu50 and lambda placMu1, an analogous phage for constructing lacZ protein fusions (Bremer et al., J. Bacteriol. 158:1084-1093, 1984). The kan gene, located between the cIII and ssb genes of lambda, permitted cells containing insertions of these phages to be selected independently of their Lac phenotype.

Preferential binding of bacteriophage Mu repressor to supercoiled Mu DNA

It was shown, using a relatively simple assay, that Mu repressor, cI, binds specifically to a region which spans the leftmost HindIII cleavage site on the phage genome. This extends the observations of Kwoh and Zipser [Nature (London) 277, 489-491 (1979)], who were able to define a binding region to the left of this site. These results provide support for the idea that the eight blocks of repeated DNA sequences, which also span the HindIII cleavage site, are involved in repressor binding. These results also indicate that cI repressor has a marked preference for supercoiled DNA.

Regulation of Mu transposition. I. Localization of the presumed recognition sites for HimD and Ner functions controlling bacteriophage Mu transcription

The Escherichia coli HimD function (also known as Hip) is essential for Mu development (Miller and Friedman, 1977). We show that the role of HimD is to stimulate early transcription of Mu DNA, probably by acting as a subunit of integration host factor (IHF) and binding at a site located approx. 70 bp upstream from the start of the early transcription. HimD-independent phages were isolated. These mutant phages carry a promoter-up mutation in the Pribnow-box of the early promoter. Early Mu transcription is negatively regulated by the repressor (c gene product) and the Ner proteins. Mutants were isolated which are insensitive to the overproduction of Ner by multicopy plasmids, which normally inhibits Mu development. The mutations that map close to the startpoint of the early transcription reveal a structure which is presumably the Ner recognition site.

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.

Lambda placMu: a transposable derivative of bacteriophage lambda for creating lacZ protein fusions in a single step

We isolated a plaque-forming derivative of phage lambda, lambda placMu1 , that contains sequences from bacteriophage Mu enabling it to integrate into the Escherichia coli chromosome by means of the Mu transposition system. The Mu DNA carried by this phage includes both attachment sites as well as the cI, ner (cII), and A genes. Lambda placMu1 also contains the lacZ gene, deleted for its transcription and translation initiation signals, and the lacY gene of E. coli, positioned next to the terminal 117 base pairs from the S end of Mu. Because this terminal Mu sequence is an open reading frame fused in frame to lacZ, the phage can create lacZ protein fusions in a single step when it integrates into a target gene in the proper orientation and reading frame. To demonstrate the use of this phage, we isolated lacZ fusions to the malB locus. These showed the phenotypes and regulation expected for malB fusions and could be used to isolate specialized transducing phages carrying the entire gene fusion as well as an adjacent gene (malE). They were found to be genetically stable and rarely (less than 10(-7] gave rise to secondary Lac+ insertions. We also isolated insertions into high-copy-number plasmids. The physical structure of these phage-plasmid hybrids was that expected from a Mu-dependent insertion event, with the lambda placMu prophage flanked by the Mu attachment sites. Lac+ insertions into a cloned recA gene were found at numerous positions and produced hybrid proteins whose sizes were correlated with the position of the fusions in recA.

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.

Predominant integration end products of infecting bacteriophage Mu DNA are simple insertions with no preference for integration of either Mu DNA strand

The integration of 32P-labeled infecting Mu DNA into the Escherichia coli chromosome was investigated. Cleavage of the integrated Mu DNA with restriction endonuclease EcoRI, which cuts twice in the Mu genome, liberated the internal EcoRI fragment but not the left and right end fragments. The ends of the Mu genome became fused with host DNA at a variety of locations generating a smear of radioactive DNA fragments following cleavage with EcoRI. The predominant integration end products of infecting Mu DNA molecules are therefore generated by a mechanism which results in simple insertions and not cointegrates. Since predominantly simple insertions are found after infection (during lysogenization or lytic growth) but not after prophage induction, the transposition mode which is utilized appears to be a function of the source of the transposing DNA. Use of the integrated, 32P-labeled Mu DNA as a hybridization probe with the separated strands of Mu DNA or lambda phages carrying various regions of Mu showed no strand preference in the integration process. Both labeled DNA strands at both ends of the Mu genome were integrated. These results suggest the lack of a site-specific recombination site in the genome; the simple insertions which are the end products of Mu DNA integration following infection appear to be generated by a separate pathway rather than by the resolution of cointegrate structures.

AvaII and BglI restriction maps of bacteriophage Mu

The AvaII and BglI restriction maps of bacteriophage Mu were derived by restriction analysis of a series of plasmid clones containing segments of Mu DNA which, in combination, covered the entire Mu genome. The plasmids analyzed included pKN36, pKN54, pKN62, pKN50, pKN35, pKN27, pKN48, pKN82, and pKN56 from the collection of W. Schumann and E. G. Bade, and pCM02, a newly constructed plasmid containing the rightmost internal EcoRI-PstI fragment of Mu DNA. BglI cuts Mu DNA at 23 sites, producing 24 fragments which range in size from 0.05 kb up to the approximately 7-kb fragment derived from the right end. AvaII cuts Mu DNA at 17 sites (including 2 within the G segment), producing fragments which range in size from 0.17 to 8.9 kb. The derived maps were confirmed by results of hybridization of 32P-labeled, nick-translated plasmid DNA to AvaII- and BglI-digested Mu DNAs. Evidence for modification of one of the AvaII sites in E. coli was obtained.

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.

Use of lambda pMu bacteriophages to isolate lambda specialized transducing bacteriophages carrying genes for bacterial chemotaxis

A general method for constructing lambda specialized transducing phages is described. The method, which is potentially applicable to any gene of Escherichia coli, is based on using Mu DNA homology to direct the integration of a lambda pMu phage near the genes whose transduction is desired. With this method we isolated a lambda transducing phage carrying all 10 genes in the che gene cluster (map location, 41.5 to 42.5 min). The products of the cheA and tar genes were identified by using transducing phages with amber mutations in these genes. It was established that tar codes for methyl-accepting chemotaxis protein II (molecular weight, 62,000) and that cheA codes for two polypeptides (molecular weights, 76,000 and 66,000). Possible origins of the two cheA polypeptides are discussed.

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.

Restriction endonuclease BamHI cleaves bacteriophage Mu DNA within cistrons E and F

We have cleaved phage Mu DNA with restriction endonucleases EcoRI and BamHI and have cloned three specific DNA fragments from the middle of the Mu genome into vector plasmid pBR322. By marker rescue experiments, we have determined that the two BamHI cleavage sites in Mu DNA occur within cistrons E and F.

Isolation and characterization of lambda specialized transducing bacteriophages carrying Klebsiella pneumoniae nif genes

Seve lambda dnif specialized transducing bacteriophages were isolated from Escherichia coli strains containing plasmids carrying the his-nif region of Klebsiella pneumoniae. These phages collectively carry deoxyribonucleic acid for all of the genes in the nif regulon and adjacent deoxyribonucleic acid of K. pneumoniae. The phages were isolated by using Mu insertions in the nif region to direct the integration of lambda pMu phages in nif via formation of lambda pMu-Mu dilysogens which, upon induction, yielded lambda dnif phages. This procedure should be generally applicable for isolating lambda specialized transducing phages carrying genes from E. coli or other bacteria.

Thermo-inducible expression of cloned early genes of bacteriophage Mu

An EcoRI fragment, containing approx. 5100 base pairs (bp) of the immunity-end of bacteriophage Mu, was inserted into the multicopy plasmid pMB9 by in vitro recombination. The expression of early Mu genes, located on the cloned fragment, is thermo-inducible because of the presence of the ts mutation in gene c. The isolation of a transformant harbouring the recombinant plasmid, pGP1, was possible only when expression of Mu genes was prevented. pGP1 can be maintained at 28 degrees C at high copy number, but at 42 degrees C the pGP1 containing cells are killed due to the expression of the kil gene of Mu. The following Mu genes are present on pGP1: the ner gene, the integration and replication genes A and B, the cim gene, and the kil gene. pGP1 containing cells do not show Gam and Sot activity at 42 degrees C, therefore the leftmost EcoRI site on the Mu DNA is located between genes kil and gam or sot, or within the gam or sot gene.

Mu insertion duplicates a 5 base pair sequence at the host inserted site

Nucleotide sequences were analyzed across the two ends of lysogenic Mu DNA. These ends were cloned separately in lambdapMu hybrid particles that derived from a single Mu lysogen in the lac Z part of lambdaplac5. The obtained data imply that Mu lysogenization was associated with the duplication of 5 base pairs present in lac DNA at the Mu insertion site. As a result of this duplication, Mu DNA is flanked by two copies of five identical base pairs oriented as direct repeats. A similar conclusion has been obtained independently by other investigators with the use of a different Mu lysogen (D. Kamp and R. Kahmann, personal communication). Thus Mu insertion seems to have a striking similarity to typical IS-mediated insertions that were found to be associated with a short DNA duplication at the target site.

Nucleotide sequences at the ends of bacteriophage Mu DNA

The nucleotide sequences were analysed at the two ends of bacteriophage Mu DNA. Such analyses reveal the existence of a short stretch of common sequences that are located at the termini and are orientated as inverted repeats. They also confirm that the heterogeneous bacterial DNA covalently bound to the ends of vegetative Mu DNA is totally removed during lysogenisation.