A biochemical analysis of the interaction of DNA gyrase with the bacteriophage Mu, pSC101 and pBR322 strong gyrase sites: the role of DNA sequence in modulating gyrase supercoiling and biological activity

Replication of bacteriophage Mu DNA, a process requiring efficient synapsis of the prophage ends, takes place within the confines of the Escherichia coli nucleoid. Critical to ensuring rapid synapsis is the function of the SGS, a strong gyrase site, located at the centre of the Mu genome. Replacement of the SGS by the strong gyrase sites from pSC101 or pBR322 fails to support efficient prophage replication. To probe the unique SGS properties we undertook a biochemical analysis of the interaction of DNA gyrase with the Mu SGS, pSC101 and pBR322 sites. In binding and cleavage assays the order of efficacy was pSC101 > Mu SGS > pBR322. However, in supercoiling assays the Mu SGS (cloned into pUC19) exhibited a strong enhancement of gyrase-catalysed supercoiling over pUC19 alone; the pSC101 site showed none and the pBR322 site gave a moderate improvement. Most striking was the Mu SGS-dependent increase in processivity of the gyrase reaction. This highly processive supercoiling coupled with efficient binding may account for the unique biological properties of the SGS. The results emphasize the importance of the DNA substrate as an active component in modulating the gyrase supercoiling reaction, and in determining the biological roles of specialized gyrase sites.     

Replacement of the Bacteriophage Mu Strong Gyrase Site and Effect on Mu DNA Replication

The bacteriophage Mu strong gyrase site (SGS) is required for efficient replicative transposition and functions by promoting the synapsis of prophage termini. To look for other sites which could substitute for the SGS in promoting Mu replication, we have replaced the SGS in the middle of the Mu genome with fragments of DNA from various sources. A central fragment from the transposing virus D108 allowed efficient Mu replication and was shown to contain a strong gyrase site. However, neither the strong gyrase site from the plasmid pSC101 nor the major gyrase site from pBR322 could promote efficient Mu replication, even though the pSC101 site is a stronger gyrase site than the Mu SGS as assayed by cleavage in the presence of gyrase and the quinolone enoxacin. To look for SGS-like sites in the Escherichia coli chromosome which might be involved in organizing nucleoid structure, fragments of E. coli chromosomal DNA were substituted for the SGS: first, repeat sequences associated with gyrase binding (bacterial interspersed mosaic elements), and, second, random fragments of the entire chromosome. No fragments were found that could replace the SGS in promoting efficient Mu replication. These results demonstrate that the gyrase sites from the transposing phages possess unusual properties and emphasize the need to determine the basis of these properties.     

Genetic analysis of the strong gyrase site (SGS) of bacteriophage Mu: localization of determinants required for promoting Mu replication

The Mu strong gyrase site (SGS), located in the centre of the Mu genome, is required for efficient Mu replication, as it promotes synapsis of the prophage termini. Other gyrase sites tested, even very strong ones, were unable to substitute for the SGS in Mu replication. To determine the features required for its unique properties, a deletion analysis was performed on the SGS. For this analysis, we defined the 20 bp centred on the midpoint of the 4 bp staggered cleavage made by gyrase to be the 'core' and the flanking sequences to be the 'arms'. The deletion analysis showed that (i) approximately 40 bp of the right arm is required, in addition to core sequences, for both efficient Mu replication and gyrase cleavage; and (ii) the left arm was not required for efficient Mu replication, although it was required for efficient gyrase cleavage. These observations implicated the right arm as the unique feature of the SGS. The second observation showed that strong gyrase cleavage and Mu replication could be dissociated and suggested that even weak gyrase sites, if supplied with the right arm of the SGS, could promote Mu replication. Hybrid sites were constructed with gyrase sites that could not support efficient Mu replication. The SGS right arm was used to replace one arm of the strong pSC101 gyrase site or the weaker pBR322 site. The pSC101 hybrid site allowed efficient Mu replication, whereas the pBR322 hybrid site allowed substantial, but reduced, replication. Hence, it appears that optimal Mu replication requires a central strong gyrase site with the properties imparted by the right arm sequences. Possible roles for the SGS right arm in Mu replication are addressed.     

Dissection of the bacteriophage Mu strong gyrase site (SGS): significance of the SGS right arm in Mu biology and DNA gyrase mechanism

The bacteriophage Mu strong gyrase site (SGS), required for efficient phage DNA replication, differs from other gyrase sites in the efficiency of gyrase binding coupled with a highly processive supercoiling activity. Genetic studies have implicated the right arm of the SGS as a key structural feature for promoting rapid Mu replication. Here, we show that deletion of the distal portion of the right arm abolishes efficient binding, cleavage, and supercoiling by DNA gyrase in vitro. DNase I footprinting analysis of the intact SGS revealed an adenylyl imidodiphosphate-dependent change in protection in the right arm, indicating that this arm likely forms the T segment that is passed through the cleaved G segment during the supercoiling reaction. Furthermore, in an SGS derivative with an altered right-arm sequence, the left arm showed these changes, suggesting that the selection of a T segment by gyrase is determined primarily by the sequences of the arms. Analysis of the sequences of the SGS and other gyrase sites suggests that the choice of T segment correlates with which arm possesses the more extensive set of phased anisotropic bending signals, with the Mu right arm possessing an unusually extended set of such signals. The implications of these observations for the structure of the gyrase-DNA complex and for the biological function of the Mu SGS are discussed.     

The role of prophage-like elements in the diversity of Salmonella enterica serovars

The Salmonella enterica serovar Typhi CT18 (S.Typhi) chromosome harbours seven distinct prophage-like elements, some of which may encode functional bacteriophages. In silico analyses were used to investigate these regions in S.Typhi CT18, and ultimately compare these integrated bacteriophages against 40 other Salmonella isolates using DNA microarray technology. S.Typhi CT18 contains prophages that show similarity to the lambda, Mu, P2 and P4 bacteriophage families. When compared to other S.Typhi isolates, these elements were generally conserved, supporting a clonal origin of this serovar. However, distinct variation was detected within a broad range of Salmonella serovars; many of the prophage regions are predicted to be specific to S.Typhi. Some of the P2 family prophage analysed have the potential to carry non-essential "cargo" genes within the hyper-variable tail region, an observation that suggests that these bacteriophage may confer a level of specialisation on their host. Lysogenic bacteriophages therefore play a crucial role in the generation of genetic diversity within S.enterica.     

Inversions over the terminus region in Salmonella and Escherichia coli: IS200s as the sites of homologous recombination inverting the chromosome of Salmonella enterica serovar typhi

Genomic rearrangements (duplications and inversions) in enteric bacteria such as Salmonella enterica serovar Typhimurium LT2 and Escherichia coli K12 are frequent (10(-3) to 10(-5)) in culture, but in wild-type strains these genomic rearrangements seldom survive. However, inversions commonly survive in the terminus of replication (TER) region, where bidirectional DNA replication terminates; nucleotide sequences from S. enterica serovar Typhimurium LT2, S. enterica serovar Typhi CT18, E. coli K12, and E. coli O157:H7 revealed genomic inversions spanning the TER region. Assuming that S. enterica serovar Typhimurium LT2 represents the ancestral genome structure, we found an inversion of 556 kb in serovar Typhi CT18 between two of the 25 IS200 elements and an inversion of about 700 kb in E. coli K12 and E. coli O157:H7. In addition, there is another inversion of 500 kb in E. coli O157:H7 compared with E. coli K12. PCR analysis confirmed that all S. enterica serovar Typhi strains tested, but not strains of other Salmonella serovars, have an inversion at the exact site of the IS200 insertions. We conclude that inversions of the TER region survive because they do not significantly change replication balance or because they are part of the compensating mechanisms to regain chromosome balance after it is disrupted by insertions, deletions, or other inversions.     

The Mu strong gyrase-binding site promotes efficient synapsis of the prophage termini

A strong DNA gyrase-binding site (SGS) is located midway between the termini of the bacteriophage Mu genome and is required for efficient replicative transposition. We have proposed that the SGS promotes the efficient synapsis of the Mu prophage ends (an obligate early step in replicative transposition), and that it does so by helping to organize the prophage DNA into a supercoiled loop with the SGS at the apex of the loop and the prophage termini at the base. The positioning of the synapsing termini equidistant from the SGS is a key element in the proposed model. To test this proposal, we have constructed prophages with a second, internal right end and asked whether the natural, external right end or the internal right end is used for synapsis with the left end in the presence and absence of the SGS. In the presence of the central SGS, the natural, or outside, right end was used exclusively and very efficiently. In the absence of the central SGS, the internal right end was used preferentially and inefficiently: the efficiency of transposition decreased with increasing distance between the internal right end and the left end. Repositioning the SGS midway between the left end and an internal right end allowed highly efficient use of the internal right end. These results support a model in which gyrase can influence long-range DNA interactions to promote efficient synapsis of Mu prophage ends.     

A genetic study of Escherichia coli strains carrying Mu-lambda-Mu structures

We have studied the interaction of bacteriophages Mu and lambda after their simultaneous induction and the influence of lambda on Mu-dependent mobilization of the E. coli chromosome by the RP4 plasmid. Heterolysogenic E. coli strains carrying Mu-lambda-Mu structures were constructed (Faelen et al. 1975). The Mu and lambda prophages are linked in such structures, and the functions of some lambda genes are disturbed depending on the integration site. A study of the inhibition of Mu growth by lambda after their simultaneous induction was performed and the region of the lambda genome (R-H) which contains the gene(s) responsible for the inhibitory effect of lambda on Mu was identified. The efficiency of Mu-dependent mobilization of the bacterial chromosome by RP4 is shown to be an order of magnitude lower in strains with unlinked Mu and lambda and an order of magnitude higher in strains with some permutations of the lambda prophage than in the control Mu-monolysogenic E. coli strain. Thus the effect of Mu on mobilization depends on the localization of the lambda prophage and on the functioning of its genome within a Mu-lambda-Mu structure. It is presumed that the mobilization of the bacterial chromosome is stimulated by effective replication of the Mu genome starting from the ori site (origin of replication) of the lambda prophage within the Mu-lambda-Mu structure. We propose a model to explain the interaction of Mu and lambda in E. coli strains carrying Mu-lambda-Mu structures.     

Nucleotide sequences and organization of the genes for carotovoricin (Ctv) from Erwinia carotovora indicate that Ctv evolved from the same ancestor as Salmonella typhi prophage

Carotovoricin Er (CtvEr), which is produced by a plant soft rot disease causative agent, Erwinia carotovora subsp. carotovora Er, is a high-molecular-weight bacteriocin showing Myoviridae phage-tail-like morphology with contractile sheath and plural tail fibers. We determined the complete nucleotide sequences of CtvEr genes on the E. carotovora Er chromosome and report that CtvEr genes consist of lysis cassette, major and minor structural protein gene clusters. Four promoters were identified. The lysis gene cassette, which is composed of the genes for lysis enzyme and holin, was also identified and characterized. The nucleotide sequences and organization of the genes for CtvCGE, which is produced by E. carotovora strain CGE234-M403 with the morphology similar to CtvEr, were also determined and compared to that of CtvEr, and it was found that CtvCGE is almost identical to CtvEr except for tail fibers which are involved in the killing spectra of both bacteriocins. We also explain that the gene organization and the deduced amino acid sequences of both carotovoricins are very close to those of prophage, which is lysogenized in the chromosome on Salmonella enterica serovar Typhi CT18. These findings strongly suggest that Ctv evolved as a phage tail-like bacteriocin from a common ancestor with Salmonella typhi prophage.     

Early events in the replication of Mu prophage DNA.

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

Amplification of DNA at a prophage attachment site in Haemophilus influenzae.

The Escherichia coli plasmids pBR322 and pBR327 can be taken up by Haemophilus influenzae but do not replicate in this organism; however, integration of pBR into the H. influenzae chromosome was achieved by ligation to a fragment of the Haemophilus phage S2 that carried a phage attachment site (attP). Once these sequences were integrated, they could serve as sites of recombination and amplification for homologous (pBR or phage) DNA. Amplification appeared to occur in one of two prophage sites (attB) present in the H. influenzae chromosome. The extent of amplification was different in different cells and reflected the ability of these sequences to undergo rearrangement leading to the formation of a DNA ladder. The ladder was obtained by treatment of DNA with restriction enzymes that cut outside of the inserted DNA, i.e., did not cut in the repeat sequence, and represented different numbers of repeat elements. Reversed-field gel electrophoresis was instrumental in resolving amplified structures. Inasmuch as single-cell isolates gave rise to the same ladder structure, it was assumed that amplification was under regulatory control and that it reproduced the same equilibrium of repeat structures. Transformation of E. coli with the amplified H. influenzae DNA resulted in precise excision and replication of the original monomeric plasmids. This excision was independent of the recA and recBC genes.     

Integration of bacteriophage lambda into the cryptic lambdoid prophages of Escherichia coli.

Bacteriophage lambda missing its chromosomal attachment site will integrate into recA+ Escherichia coli K-12 and C at the sites of cryptic prophages. The specific regions in which these recombination events occur were identified in both lambda and the bacterial chromosomes. A NotI restriction site on the prophage allowed its physical mapping. This allowed us to identify the locations of Rac, Qin, and Qsr' cryptic prophages on the NotI map of E. coli K-12 and, by analogy, to identify the cryptic prophage in E. coli C as Qin. No new cryptic prophages were detected in E. coli K-12.     

A cell engineering strategy to enhance supercoiled plasmid DNA production for gene therapy

With the recent revival of the promise of plasmid DNA vectors in gene therapy, a novel synthetic biology approach was used to enhance the quantity, (yield), and quality of the plasmid DNA. Quality was measured by percentage supercoiling and supercoiling density, as well as improving segregational stability in fermentation. We examined the hypothesis that adding a Strong Gyrase binding Site (SGS) would increase DNA gyrase‐mediated plasmid supercoiling. SGS from three different replicons, (the Mu bacteriophage and two plasmids, pSC101 and pBR322) were inserted into the plasmid, pUC57. Different sizes of these variants were transformed into E. coli DH5α, and their supercoiling properties and segregational stability measured. A 36% increase in supercoiling density was found in pUC57‐SGS, but only when SGS was derived from the Mu phage and was the larger sized version of this fragment. These results were also confirmed at fermentation scale. Total percentage supercoiled monomer was maintained to 85–90%. A twofold increase in plasmid yield was also observed for pUC57‐SGS in comparison to pUC57. pUC57‐SGS displayed greater segregational stability than pUC57‐cer and pUC57, demonstrating a further potential advantage of the SGS site. These findings should augment the potential of plasmid DNA vectors in plasmid DNA manufacture. Biotechnol. Bioeng. 2016;113: 2064–2071. © 2016 The Authors. Biotechnology and Bioengineering Published by Wiley Periodicals, Inc.     

Diversity of genome structure in Salmonella enterica serovar Typhi populations

The genomes of most strains of Salmonella and Escherichia coli are highly conserved. In contrast, all 136 wild-type strains of Salmonella enterica serovar Typhi analyzed by partial digestion with I-CeuI (an endonuclease which cuts within the rrn operons) and pulsed-field gel electrophoresis and by PCR have rearrangements due to homologous recombination between the rrn operons leading to inversions and translocations. Recombination between rrn operons in culture is known to be equally frequent in S. enterica serovar Typhi and S. enterica serovar Typhimurium; thus, the recombinants in S. enterica serovar Typhi, but not those in S. enterica serovar Typhimurium, are able to survive in nature. However, even in S. enterica serovar Typhi the need for genome balance and the need for gene dosage impose limits on rearrangements. Of 100 strains of genome types 1 to 6, 72 were only 25.5 kb off genome balance (the relative lengths of the replichores during bidirectional replication from oriC to the termination of replication [Ter]), while 28 strains were less balanced (41 kb off balance), indicating that the survival of the best-balanced strains was greater. In addition, the need for appropriate gene dosage apparently selected against rearrangements which moved genes from their accustomed distance from oriC. Although rearrangements involving the seven rrn operons are very common in S. enterica serovar Typhi, other duplicated regions, such as the 25 IS200 elements, are very rarely involved in rearrangements. Large deletions and insertions in the genome are uncommon, except for deletions of Salmonella pathogenicity island 7 (usually 134 kb) from fragment I-CeuI-G and 40-kb insertions, possibly a prophage, in fragment I-CeuI-E. The phage types were determined, and the origins of the phage types appeared to be independent of the origins of the genome types.     

Nucleotide Sequences and Organization of the Genes for Carotovoricin (Ctv) from Erwinia carotovora Indicate That Ctv Evolved from the Same Ancestor as Salmonella typhi Prophage

Carotovoricin Er (CtvEr), which is produced by a plant soft rot disease causative agent, Erwinia carotovora subsp. carotovora Er, is a high-molecular-weight bacteriocin showing Myoviridae phage-tail-like morphology with contractile sheath and plural tail fibers. We determined the complete nucleotide sequences of CtvEr genes on the E. carotovora Er chromosome and report that CtvEr genes consist of lysis cassette, major and minor structural protein gene clusters. Four promoters were identified. The lysis gene cassette, which is composed of the genes for lysis enzyme and holin, was also identified and characterized. The nucleotide sequences and organization of the genes for CtvCGE, which is produced by E. carotovora strain CGE234-M403 with the morphology similar to CtvEr, were also determined and compared to that of CtvEr, and it was found that CtvCGE is almost identical to CtvEr except for tail fibers which are involved in the killing spectra of both bacteriocins. We also explain that the gene organization and the deduced amino acid sequences of both carotovoricins are very close to those of prophage, which is lysogenized in the chromosome on Salmonella enterica serovar Typhi CT18. These findings strongly suggest that Ctv evolved as a phage tail-like bacteriocin from a common ancestor with Salmonella typhi prophage.     

A third family of allelic hsd genes in Salmonella enterica: sequence comparisons with related proteins identify conserved regions implicated in restriction of DNA

Salmonella enterica serovar blegdam has a restriction and modification system encoded by genes linked to serB . We have cloned these genes, putative alleles of the hsd locus of Escherichia coli  K-12, and confirmed by the sequence similarities of flanking DNA that the hsd genes of S. enterica serovar blegdam have the same chromosomal location as those of E. coli K-12 and Salmonella enterica serovar typhimurium LT2. There is, however, no obvious similarity in their nucleotide sequences, and while the gene order in S. enterica serovar blegdam is serB hsdM , S and R , that in E. coli K-12 and S. enterica serovar typhimurium LT2 is serB hsdR , M and S . The hsd genes of S. enterica serovar blegdam identify a third family of serB -linked hsd genes (type ID). The polypeptide sequence predicted from the three hsd genes show some similarities (18–50% identity) with the polypeptides of known and putative type I restriction and modification systems; the highest levels of identity are with sequences of Haemophilus influenzae Rd. The HsdM polypeptide has the motifs characteristic of adenine methyltransferases. Comparisons of the HsdR sequence with those for three other families of type I systems and three putative HsdR polypeptides identify two highly conserved regions in addition to the seven proposed DEAD-box motifs.     

Activation of prophage eib genes for immunoglobulin-binding proteins by genes from the IbrAB genetic island of Escherichia coli ECOR-9

Four distinct Escherichia coli immunoglobulin-binding (eib) genes, each of which encodes a surface-exposed protein that binds immunoglobulins in a nonimmune manner, are carried by separate prophages in E. coli reference (ECOR) strain ECOR-9. Each eib gene was transferred to test E. coli strains, both in the form of multicopy recombinant plasmids and as lysogenized prophage. The derived lysogens express little or no Eib protein, in sharp contrast to the parental lysogen, suggesting that ECOR-9 has an expression-enhancing activity that the derived lysogens lack. Supporting this hypothesis, we cloned from ECOR-9 overlapping genes, ibrA and ibrB (designation is derived from "immunoglobulin-binding regulator"), which together activated eib expression in the derived lysogens. The proteins encoded by ibrA and ibrB are very similar to uncharacterized proteins encoded by genes of Salmonella enterica serovar Typhi and E. coli O157:H7 (in a prophage-like element of the Sakai strain and in two O islands of strain EDL933). The genomic segment containing ibrA and ibrB has been designated the IbrAB island. It contains regions of homology to the Shiga toxin-converting prophage, Stx2, as well as genes homologous to phage antirepressor genes. The left boundary between the IbrAB island and the chromosomal framework is located near min 35.8 of the E. coli K-12 genome. Homology to IbrAB was found in certain other ECOR strains, including the other five eib-positive strains and most strains of the phylogenetic group B2. Sequencing of a 1.1-kb portion of ibrAB revealed that the other eib-positive strains diverge by 相似文献   

Mu-induced deletions and mutations of Erwinia carotovora chromosomes, including resident prophages E105 and 59]

The plasmid RP4::Mu cts62 in stably inherited by Erwinia carotovora 268 strain. Under the conditions of thermoinduction bacteriophage Mu is segregated and completely eliminated more intensively than in Escherichia coli cells. At thermoinduction the transposition of bacteriophage Mu cts62 into different chromosomal sites takes place, causing the induction of chlorate resistant and auxotrophic mutants with the frequency of 10(-4). Two clones deficient in production of 2 of the 4 resident prophages of Erwinia carotovora 268 strain were found among Mu-induced mutants. The deleted prophages are E105 and 59. DNA-DNA hybridization has revealed the complete and partial deletions of bacteriophage E105 with the level of L-asparaginase production in the cells remaining intact. The damage of the prophage 59 is probably caused by point mutations or short deletions.     

Subclassification 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.