AvaII and BglI restriction maps of bacteriophage Mu

Bio-array images processing and genetic networks modelling

The new tools available for gene expression studies are essentially the bio-array methods using a large variety of physical detectors (isotopes, fluorescent markers, ultrasounds...). Here we present first rapidly an image-processing method independent of the detector type, dealing with the noise and with the peaks overlapping, the peaks revealing the detector activity (isotopic in the presented example), correlated with the gene expression. After this primary step of bio-array image processing, we can extract information about causal influence (activation or inhibition) a gene can exert on other genes, leading to clusters of genes co-expression in which we extract an interaction matrix M and an associated interaction graph G explaining the genetic regulatory dynamics correlated to the studied tissue function. We give two examples of such interaction matrices and graphs (the flowering genetic regulatory network of Arabidopsis thaliana and the lytic/lysogenic operon of the phage Mu) and after some theoretical rigorous results recently obtained concerning the asymptotic states generated by the genetic networks having a given interaction matrix and reciprocally concerning the minimal (in the sense of having a minimal number of non-zero coefficients) matrices having given stationary stable states.

Discovery of the tail tube gene of bacteriophage Mu and sequence analysis of the sheath and tube genes

The nucleotide sequence was determined for 2.75 kbp of phage Mu DNA encoding the contractile tail sheath protein L. N-terminal sequence analysis of Mu tail tube and sheath proteins identified the open reading frame just downstream of gene L as the tube gene. This clustering and order of the sheath and tube genes appear to be common among the myoviridae. Database homology searches revealed high similarity between the Mu sheath and tube proteins and two proteins in a Haemophilus influenzae Mu-like prophage, suggesting that they are the sheath and tube proteins of that prophage.

Identification and characterization of the terminators of the lys and P transcripts of bacteriophage Mu

Transcription during the lytic cycle of phage Mu occurs in three phases: early, middle, and late. Late transcription requires the Mu C protein and initiates at four promoters: Plys, PI, PP, and Pmom. Northern blot analysis of total RNA isolated 30 min after heat induction of Mu cts lysogens demonstrated that the full-length lys and P transcripts were approximately 7.6 and 6.3 kb long, respectively. The 3' ends of the lys and P transcripts were further localized by S1 nuclease mapping to intergenic regions between G and I and between U and U' in both the G(+) and G(-) orientations of the invertible G segment, respectively. As expected, when DNA fragments containing these termination regions were cloned into plasmids between Pgal and the galK gene, they showed efficient termination activity, even in a Rho-deficient background. Deletion analysis indicated that efficient termination required the presence of potential RNA stem-loop structures immediately preceding the RNA 3' ends. For the P transcript from phage with the G(-) orientation, full termination activity required both the region containing the stem-loop structure and upstream sequences. Taken together, these results suggest that the transcription termination sites of the lys and P transcripts are Rho-independent terminators.

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.

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.

Localization and regulation of bacteriophage Mu promoters

Mu promoters active during the lytic cycle were located by isolating RNA at various times after induction of Mu prophages, radiolabeling it by capping in vitro, and hybridizing it to Mu DNA fragments on Southern blots. Signals were detected from four new promoters in addition to the previously characterized Pe (early), PcM (repressor), and Pmom (late) promoters. A major signal upstream of C was first observed at 12 min and intensified thereafter with RNA from cts and C amber but not replication-defective prophages; these characteristics indicate that this signal arises from a middle promoter, which we designate Pm. With 20- and 40-min RNA, four additional major signals originated in the C-lys, F-G-I, N-P, and com-mom regions. These signals were missing with RNA from C amber and replication-defective prophages and therefore reflected the activity of late promoters, one of which we presume was Pmom. Uninduced lysogens showed weak signals from five regions, one from the early regulatory region, three between genes B and lys, and one near the late genes K, L, and M. The first of these probably resulted from PcM activity; the others remain to be identified.

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.

Mutants of Escherichia coli defective for replicative transposition of bacteriophage Mu

We isolated 142 Hir- (host inhibition of replication) mutants of an Escherichia coli K-12 Mu cts Kil- lysogen that survived heat induction and the killing effect of Mu replicative transposition. All the 86 mutations induced by insertion of Tn5 or a kanamycin-resistant derivative of Tn10 and approximately one-third of the spontaneous mutations were found by P1 transduction to be linked to either zdh-201::Tn10 or Tn10-1230, indicating their location in or near himA or hip, respectively. For a representative group of these mutations, complementation by a plasmid carrying the himA+ gene or by a lambda hip+ transducing phage confirmed their identification as himA or hip mutations, respectively. Some of the remaining spontaneously occurring mutations were located in gyrA or gyrB, the genes encoding DNA gyrase. Mutations in gyrA were identified by P1 linkage to zei::Tn10 and a Nalr gyrA allele; those in gyrB were defined by linkage to tna::Tn10 and to a gyrB(Ts) allele. In strains carrying these gyrA or gyrB mutations, pBR322 plasmid DNA exhibited altered levels of supercoiling. The extent of growth of Mu cts differed in the various gyrase mutants tested. Phage production in one gyrA mutant was severely reduced, but it was only delayed and slightly reduced in other gyrA and gyrB mutants. In contrast, growth of a Kil- Mu was greatly reduced in all gyrase mutant hosts tested.

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.

The sequence and mom-transactivation function of the C gene of bacteriophage Mu

The mom gene of bacteriophage Mu encodes a DNA modification function. The gene is regulated on the transcriptional level by Dam-specific methylation and a trans-acting Mu function, and on a post-transcriptional level by the product of gene com. The gene encoding the transactivator has been cloned and mapped. By complementation analysis the activation function (also designated Dad) was shown to be the product of gene C. Transactivation of the mom promoter was shown in the following assay: the mom promoter and N-terminal part of com were fused in frame to lacZ. Cells containing such fusion plasmids were infected with M13 clones expressing C in the presence of IPTG and XGal. Successful transactivation results in the formation of blue plaques. Moreover, we have determined the sequence of gene C and found that it has a coding capacity of 140 amino acids. The promoter for C (pc) is likely to be located at least 0.5 kb upstream from the gene. A transcription terminator is found directly downstream from the C-coding region.

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.

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.