Analysis of the lambdoid prophage element e14 in the E. coli K-12 genome

Background  

Many sequenced bacterial genomes harbor phage-like elements or cryptic prophages. These elements have been implicated in pathogenesis, serotype conversion and phage immunity. The e14 element is a defective lambdoid prophage element present at 25 min in the E. coli K-12 genome. This prophage encodes important functional genes such as lit (T4 exclusion), mcrA (modified cytosine restriction activity) and pin (recombinase).     

The origin of Q-independent derivatives of phage lambda

Summary qsr (Q-independent) phages are characterised by the replacement of the region of the genome that contains Q, S, R, and the late gene promoter, P_R, with host-derived DNA that codes for functions analogous to those deleted. Restriction endonuclease analysis and DNA/DNA hybridisation methods have been used to show that p4 and qin A 3, two such Q-independent phages, are the product of recombination between and a defective lambdoid prophage (the qsr prophage) located at an as yet unidentified site in the E. coli K 12 chromosome. The qsr prophage is distinct from the defective lambdoid prophage Rac (Kaiser and Murray 1979). In the E. coli K 12 strain AB1157 from which qsr phages cannot be generated, the qsr prophage has suffered an internal deletion. That the qsr prophage appears not to carry a full complement of essential late genes suggests one explanation for its apparently defective nature.     

Characterization of the cryptic lambdoid prophage DLP12 of Escherichia coli and overlap of the DLP12 integrase gene with the tRNA gene argU.

The argU (dnaY) gene of Escherichia coli is located, in clockwise orientation, at 577.5 kilobases (kb) on the chromosome physical map. There was a cryptic prophage spanning the 2 kb immediately downstream of argU that consisted of sequences similar to the phage P22 int gene, a portion of the P22 xis gene, and portions of the exo, P, and ren genes of bacteriophage lambda. This cryptic prophage was designated DLP12, for defective lambdoid prophage at 12 min. Immediately clockwise of DLP12 was the IS3 alpha 4 beta 4 insertion element. The argU and DLP12 int genes overlapped at their 3' ends, and argU contained sequence homologous to a portion of the phage P22 attP site. Additional homologies to lambdoid phages were found in the 25 kb clockwise of argU. These included the cryptic prophage qsr' (P. J. Highton, Y. Chang, W. R. Marcotte, Jr., and C. A. Schnaitman, J. Bacteriol. 162:256-262, 1985), a sequence homologous to a portion of lambda orf-194, and an attR homolog. Inasmuch as the DLP12 att int xis exo P/ren region, the qsr' region, and homologs of orf-194 and attR were arranged in the same order and orientation as the lambdoid prophage counterparts, we propose that the designation DLP12 be applied to all these sequences. This organization of the DLP12 sequences and the presence of the argU/DLP12 int pair in several E. coli strains and closely related species suggest that DLP12 might be an ancestral lambdoid prophage. Moreover, the presence of similar sequences at the junctions of DLP12 segments and their phage counterparts suggests that a common mechanism could have transferred these DLP12 segments to more recent phages.     

Sub classification and targeted characterization of prophage-encoded two-component cell lysis cassette

Bacteriophage induced lysis of host bacterial cell is mediated by a two component cell lysis cassette comprised of holin and lysozyme. Prophages are integrated forms of bacteriophages in bacterial genomes providing a repertoire for bacterial evolution. Analysis using the prophage database ( http://bicmku.in:8082 ) constructed by us showed 47 prophages were associated with putative two component cell lysis genes. These proteins cluster into four different subgroups. In this process, a putative holin (essd) and endolysin (ybcS), encoded by the defective lambdoid prophage DLP12 was found to be similar to two component cell lysis genes in functional bacteriophages like p21 and P1. The holin essd was found to have a characteristic dual start motif with two transmembrane regions and C-terminal charged residues as in class II holins. Expression of a fusion construct of essd in Escherichia coli showed slow growth. However, under appropriate conditions, this protein could be over expressed and purified for structure function studies. The second component of the cell lysis cassette, ybcS, was found to have an N-terminal SAR (Signal Arrest Release) transmembrane domain. The construct of ybcS has been over expressed in E. coli and the purified protein was functional, exhibiting lytic activity against E. coli and Salmonella typhi cell wall substrate. Such targeted sequence-structure-function characterization of proteins encoded by cryptic prophages will help understand the contribution of prophage proteins to bacterial evolution.     

Defective prophages of bacteriophage Mu

Summary A method is described for the isolation of thermoinducible defective Mu lysogens. Four of these defective lysogens were studied more extensively. By marker-rescue experiments it was shown that the strain harbouring the smallest defective prophage contains the immunity gene cts and the genes A and B; the strain with the largest defective prophage still contains all the known essential genes of Mu, A to S (see Fig. 1).After induction at 43° C all the defective lysogens are killed, whereas no lysis occurs.Although in all the thermoinducible defective lysogens the A and B gene products could be demonstrated by complementation, these gene products are not responsible for the killing of the host, suggesting the presence of another unknown early gene product of Mu. The level of complementation of a mutation in gene A is reduced by the presence in the cell of another defective Mu prophage containing the G part of Mu. This effect on A gene complementation is markedly enhanced when the defective prophage, containing the G part, is located on an episome instead of on the chromosome. Complementation of late genes by a defective prophage located on the chromosome, is extremely low or undetectable. A stimulation of complementation by a factor of 10 to 40 was found when the same defective prophage was situated on a F factor. A possible explanation for this episome effect will be discussed.     

Ant-mediated transactivation of early genes in Salmonella prophage P22 by superinfecting virulent P22 mutants

Summary The virulent mutants P22 vir B vy and P22 vy mutants, both insensitive to mnt-repressor, transactivate the early genes of a P22 prophage. The transactivation of early P22 prophage genes depends strictly on the expression of gene ant (antirepressor-protein) by the superinfecting P22 mutant and therefore occurs by derepression.     

Nucleotide sequence of the region encompassing the int gene of a cryptic prophage and the dna Y gene flanked by a curved DNA sequence of Escherichia coli K12

Summary The nucleotide sequence of a 2.5 kb region encompassing a curved DNA segment (BENT-9) randomly cloned from the total Escherichia coli chromosome was determined. This region was found to contain the dnaY gene encoding a transfer RNA. The curved DNA structure was demonstrated to be located just upstream of the dnaY promoter. The results of sequencing further revealed that the int gene of a cryptic prophage, qsr, which has been shown to be present in the E. coli genome, is located next to the dnaY gene.     

Regional replication of the bacterial chromosome induced by derepression of prophage lambda

Summary We have demonstrated previously by DNA-DNA hybridization that induction of phage with wild type O and P genes results in an increase of bacterial DNA in the chromosomal region adjacent to the left of the prophage, that is a segment between gal and att (gal DNA) (Imae and Fukasawa, 1970). Evidence is presented in this report that such an increase of bacterial DNA is also seen in the region to the right of the prophage; a segment between bio and att (bio DNA). We postulate therefore that the bidirectional replication of DNA extends beyond the prophage and copies the neighboring host DNA until the prophage is excised. The model is verified by making use of excision-defective phages. The synthesis of gal DNA (or bio DNA) slows down to a halt within 40 min after the induction in the normal lysogens. The results are attributed to the prophage excision: (1) In lysogens for int, synthesis of the bacterial DNA continues for longer times. (2) The synthesis of the bacterial DNA slows down to a halt in lysogens for xis or b2 as in the control. However DNA synthesis also slows down in parallel so that the amount of the bacterial DNA relative to that of DNA synthesized by a given time stays constant from 20 min to 80 min. During that time the relative amount of the bacterial DNA rapidly decreases in the normal lysogen.The first article of this series is in J. molec. Biol. 54, 585 (1970).     

RexAB proteins of bacteriophage lambda enhance the effect of photolyase-dimer complexes on lacZ gene expression in Escherichia coli.

Summary Expression of the lacZ gene in Escherichia coli is inactivated by exposure to ultraviolet light (UV). Inactivation is exceptionally effective when cells contain amplified levels of DNA photolyase (which forms complexes with pyrimidine dimers in the absence of light for actual photoreversal) and a prophage. Without amplified photolyase, the prophage or both, inactivation rates are similar and much lower. UV-inactivation of lacZ gene expression in the presence of both amplified photolyase and is even more effective if cI857 is used in place of the wildtype prophage but is wholly unexceptional if the prophage carries defects in the genes rexA or rexB. When Rex AB proteins are provided by expression from a plasmid and the cell also contains amplified photolyase, exceptional inactivation rates again obtain; in fact inactivation is most effective under these conditions. The data are considered to reveal a role for Rex AB proteins, which mediate superinfection exclusion, in the exceptional inactivation of gene expression by photolyase bound to pyrimidine dimers in DNA. Photolyase-dimer complexes may mimic the structure of certain complexes that arise during phage development and thus influence Rex A and/or B proteins, thereby shutting down cell metabolism.     

Physical characterisation of the "Rac prophage" in E. coli K12.

Summary We confirm the hypothesis of Low (1973) that many E. coli K 12 strains contain a prophage (the Rac prophage) located a few minutes clockwise of the trp operon on the genetic map. We have used restriction endonucleases and ³²P-labelled probes to construct a physical map of this prophage. Some E. coli K 12 strains, including AB1157, have lost the entire prophage, apparently by a specific deletion. This is consistent with prophage excision by site-specific recombination. reverse (rev) phages (Zissler et al., 1971) are recombination proficient derivatives of phage in which the phage recombination functions have been replaced by analogous functions (RecE) derived from the host chromosome (Gottesman et al., 1974; Gillen et al., 1977). Our data support the origin of rev phages by recombination between and the Rac prophage following excision of the Rac prophage from the E. coli chromosome.Important experimental data are included in the Figure legends.     

A Protein Similarity Approach For Detecting Prophage Regions In Bacterial Genomes

Background  

Numerous completely sequenced bacterial genomes harbor prophage elements. These elements have been implicated in increasing the virulence of the host and in phage immunity. The e14 element is a defective lambdoid prophage element present at 25 min in the Escherichia coli K-12 genome. e14 is a well-characterized prophage element and has been subjected to in-depth bioinformatic analysis.     

Prophage inactivation in recB-proficient Escherichia coli K12 (lambda) lysogens after ultraviolet irradiation

Summary If ultraviolet irradiated, -lysogenic Escherichia coli K12 bacteria are incubated for 4 to 6 h at 30° C, prophage becomes inactive in the non-surviving cells. This was demonstrated by the use of cIts857ind1 prophage which can be induced by heat but not by ultraviolet light. An analysis with various bacterial mutants showed that RecBC recombination enzyme is required in conjunction with RecA protein for prophage inactivation.     

Regulatory and structural properties differentiating the chromosomal and the bacteriophage-associated <Emphasis Type="Italic">Escherichia coli</Emphasis> O157:H7 Cu,Zn Superoxide Dismutases

Background  

Highly virulent enterohemorrhagic Escherichia coli O157:H7 strains possess three sodC genes encoding for periplasmic Cu, Zn superoxide dismutases: sodC, which is identical to the gene present in non-pathogenic E. coli strains, and sodC-F1 and sodC-F2, two nearly identical genes located within lambdoid prophage sequences. The significance of this apparent sodC redundancy in E. coli O157:H7 has not yet been investigated.     

Regional replication of the bacterial chromosome induced by derepression of prophage lambda

Summary Derepression of prophage in E. coli strain K12 results in constitutive synthesis of the enzymes directed by the nearby bacterial operon, gal (escape synthesis). Phage 82 fails to cause escape synthesis despite that it lysogenizes the strain K12 at the site identical to that of on the host chromosome. The reason for the observed difference between 82 and is studied in the light of the recent finding that escape synthesis in -lysogen is closely associated to phage-promoted replication of bacterial chromosome contiguous to the prophage including gal operon (escape replication). Excision-defective mutants from 82, 82int or 82xis, do initiate escape synthesis, suggesting that the prophage 82 is normally excised too quickly after induction to allow sufficient escape replication. In support of this, much more DNA hybridizable to bacterial DNA contained in gal accumulates after induction of 82int than after induction of 82. Studies with various hybrid phages between 82 and have suggested: 1. The occurrence of gal escape synthesis depends on the nature of the region between b2 and N in the map. 2. Regions of the 82 genome on both sides of the attachment site contribute independently to prevent gal escape synthesis. Implications of these results are discussed with regard to the factors involved in the prophage excision.The IIIrd article of this series is in Molec. Gen. Genet. 159, 185–190 (1978)     

Integration of bacteriophages lambda and phi 80 in wild-type Escherichia coli at secondary attachment sites. I. Formation of secondary lysogens

Summary The family of lambdoid phages displays a varying specificity of integration into the host chromosome. The phage DNA failed to get inserted at the secondary site(s) of the gal operon (frequency <2.6x10^-8) in the presence of the primary (normal) att site. By contrast, 80 and the att80 hybrid (x80) became integrated into wild-type Escherichia coli at at least two secondary att sites of the btuB locus, and the latter near purE and purC as well (frequency 2x10^-3-10^-4). The integration of 80 and att80 into btuB occurred with about the same frequency as in cells in which the normal insertion site had been deleted (0.7-4.0x10^-6). An analysis of the secondary lysogens with the prophage in btuB showed them to be polylysogens; the additional prophage(s) was found at the primary att site. We also failed to observe the integration into other loci of 80 and att80 with the formation of secondary monolysogens (frequency <0.0035 at MOI-10^-3 or 10). It is presumed that these prophages become integrated at secondary att sites only if the primary site is occupied.Abbreviations MOI multiplicity of infection (PFU/cell) - PFU plaque-forming unit - TP transducing phage - P1/HfrH P1vir multiplied on HfrH - Rif-R rifampin-resistance - Int int protein