The pCLIP plasmids: versatile cloning vectors based on the bacteriophage lambda origin of replication

chi sequences switch the RecBCD helicase-nuclease complex from degradative to replicative modes during the completion of DNA replication

Accurately completing DNA replication when two forks converge is essential to genomic stability. The RecBCD helicase-nuclease complex plays a central role in completion by promoting resection and joining of the excess DNA created when replisomes converge. chi sequences alter RecBCD activity and localize with cross-over hotspots during sexual events in bacteria, yet their functional role during chromosome replication remains unknown. Here, we use two-dimensional agarose gel analysis to show that chi induces replication on substrates containing convergent forks. The induced-replication is processive, but uncoupled with respect to leading and lagging strand synthesis, and can be suppressed by ter sites which limit replisome progression. Our observations demonstrate that convergent replisomes create a substrate that is processed by RecBCD, and that chi, when encountered, switches RecBCD from a degradative to replicative function. We propose that chi serves to functionally differentiate DNA ends created during completion, which require degradation, from those created by chromosomal double-strand breaks, which require resynthesis.

RecBCD, SbcCD and ExoI process a substrate created by convergent replisomes to complete DNA replication

The accurate completion of DNA replication on the chromosome requires RecBCD and structure specific SbcCD and ExoI nucleases. However, the substrates and mechanism by which this reaction occurs remains unknown. Here we show that these completion enzymes operate on plasmid substrates containing two replisomes, but are not required for plasmids containing one replisome. Completion on the two-replisome plasmids requires RecBCD, but does not require RecA and no broken intermediates accumulate in its absence, indicating that the completion reaction occurs normally in the absence of any double-strand breaks. Further, similar to the chromosome, we show that when the normal completion reaction is prevented, an aberrant RecA-mediated recombination process leads to amplifications that drive most of the instabilities associated with the two-replisome substrates. The observations imply that the substrate SbcCD, ExoI and RecBCD act upon in vivo is created specifically by two convergent replisomes, and demonstrate that the function of RecBCD in completing replication is independent of double-strand break repair, and likely promotes joining of the strands of the convergent replication forks.

Xenobiotic Compounds Degradation by Heterologous Expression of a Trametes sanguineus Laccase in Trichoderma atroviride

Fungal laccases are enzymes that have been studied because of their ability to decolorize and detoxify effluents; they are also used in paper bleaching, synthesis of polymers, bioremediation, etc. In this work we were able to express a laccase from Trametes (Pycnoporus) sanguineus in the filamentous fungus Trichoderma atroviride. For this purpose, a transformation vector was designed to integrate the gene of interest in an intergenic locus near the blu17 terminator region. Although monosporic selection was still necessary, stable integration at the desired locus was achieved. The native signal peptide from T. sanguineus laccase was successful to secrete the recombinant protein into the culture medium. The purified, heterologously expressed laccase maintained similar properties to those observed in the native enzyme (Km and kcat and kcat/km values for ABTS, thermostability, substrate range, pH optimum, etc). To determine the bioremediation potential of this modified strain, the laccase-overexpressing Trichoderma strain was used to remove xenobiotic compounds. Phenolic compounds present in industrial wastewater and bisphenol A (an endocrine disruptor) from the culture medium were more efficiently removed by this modified strain than with the wild type. In addition, the heterologously expressed laccase was able to decolorize different dyes as well as remove benzo[α]pyrene and phenanthrene in vitro, showing its potential for xenobiotic compound degradation.

Isolation, characterization, and complete genome analysis of P1312, a thermostable bacteriophage that infects Thermobifida fusca

Thermobifida fusca is a moderately thermophilic and cellulolytic actinobacterium. It is of particular interest due to its ability to not only produce a variety of biotechnologically relevant enzymes but also serve as an alternative host for metabolic engineering for the production of valuable chemicals from lignocellulosic agricultural wastes. No bacteriophage that infects T. fusca has been reported, despite its potential impacts on the utilization of T. fusca. In this study, an extremely thermostable bacteriophage P1312 that infects T. fusca was isolated from manure compost. Electron microscopy showed that P1312 has an icosahedral head and a long flexible non-contractile tail, a characteristic of the family Siphoviridae. P1312 has a double-stranded DNA genome of 60,284 bp with 93 potential ORFs. Thirty-one ORFs encode proteins having putative biological functions. The genes involved in phage particle formation cluster together in a region of approximately 16 kb, followed by a segment containing genes presumably for DNA degradation/modification and cell wall disruption. The genes required for DNA replication and transcriptional control are dispersed within the rest of the genome. Phylogenetic analysis of large terminase subunit suggests that P1312 is a headful packaging phage containing a chromosome with circularly permuted direct terminal repeats.

ppGpp-dependent negative control of DNA replication of Shiga toxin-converting bacteriophages in Escherichia coli

The pathogenicity of enterohemorrhagic Escherichia coli (EHEC) strains depends on the production of Shiga toxins that are encoded on lambdoid prophages. Effective production of these toxins requires prophage induction and subsequent phage replication. Previous reports indicated that lytic development of Shiga toxin-converting bacteriophages is inhibited in amino acid-starved bacteria. However, those studies demonstrated that inhibition of both phage-derived plasmid replication and production of progeny virions occurred during the stringent as well as the relaxed response to amino acid starvation, i.e., in the presence as well as the absence of high levels of ppGpp, an alarmone of the stringent response. Therefore, we asked whether ppGpp influences DNA replication and lytic development of Shiga toxin-converting bacteriophages. Lytic development of 5 such bacteriophages was tested in an E. coli wild-type strain and an isogenic mutant that does not produce ppGpp (ppGpp(0)). In the absence of ppGpp, production of progeny phages was significantly (in the range of an order of magnitude) more efficient than in wild-type cells. Such effects were observed in infected bacteria as well as after prophage induction. All tested bacteriophages formed considerably larger plaques on lawns formed by ppGpp(0) bacteria than on those formed by wild-type E. coli. The efficiency of synthesis of phage DNA and relative amount of lambdoid plasmid DNA were increased in cells devoid of ppGpp relative to bacteria containing a basal level of this nucleotide. We conclude that ppGpp negatively influences the lytic development of Shiga toxin-converting bacteriophages and that phage DNA replication efficiency is limited by the stringent control alarmone.

Replication of plasmids derived from Shiga toxin-converting bacteriophages in starved Escherichia coli

The pathogenicity of Shiga toxin-producing Escherichia coli (STEC) depends on the expression of stx genes that are located on lambdoid prophages. Effective toxin production occurs only after prophage induction, and one may presume that replication of the phage genome is important for an increase in the dosage of stx genes, positively influencing their expression. We investigated the replication of plasmids derived from Shiga toxin (Stx)-converting bacteriophages in starved E. coli cells, as starvation conditions may be common in the intestine of infected humans. We found that, unlike plasmids derived from bacteriophage λ, the Shiga toxin phage-derived replicons did not replicate in amino acid-starved relA(+) and relA(-) cells (showing the stringent and relaxed responses to starvation, respectively). The presence of the stable fraction of the replication initiator O protein was detected in all tested replicons. However, while ppGpp, the stringent response effector, inhibited the activities of the λ P(R) promoter and its homologues from Shiga toxin-converting bacteriophages, these promoters, except for λ P(R), were only weakly stimulated by the DksA protein. We suggest that this less efficient (relative to λ) positive regulation of transcription responsible for transcriptional activation of the origin contributes to the inhibition of DNA replication initiation of Shiga toxin-converting bacteriophages in starved host cells, even in the absence of ppGpp (as in starved relA(-) hosts). Possible clinical implications of these results are discussed.

Precise targeted integration by a chimaeric transposase zinc-finger fusion protein

Transposons of the Tc1/mariner family have been used to integrate foreign DNA stably into the genome of a large variety of different cell types and organisms. Integration is at TA dinucleotides located essentially at random throughout the genome, potentially leading to insertional mutagenesis, inappropriate activation of nearby genes, or poor expression of the transgene. Here, we show that fusion of the zinc-finger DNA-binding domain of Zif268 to the C-terminus of ISY100 transposase leads to highly specific integration into TA dinucleotides positioned 6-17 bp to one side of a Zif268 binding site. We show that the specificity of targeting can be changed using Zif268 variants that bind to sequences from the HIV-1 promoter, and demonstrate a bacterial genetic screen that can be used to select for increased levels of targeted transposition. A TA dinucleotide flanked by two Zif268 binding sites was efficiently targeted by our transposase-Zif268 fusion, suggesting the possibility of designer 'Z-transposases' that could deliver transgenic cargoes to chosen genomic locations.

Modulation of lambda plasmid and phage DNA replication by Escherichia coli SeqA protein

SeqA protein, a main negative regulator of the replication initiation of the Escherichia coli chromosome, also has several other functions which are still poorly understood. It was demonstrated previously that in seqA mutants the copy number of another replicon, the lambda plasmid, is decreased, and that the activity of the lambda p(R) promoter (whose function is required for stimulation of ori lambda) is lower than that in the wild-type host. Here, SeqA-mediated regulation of lambda phage and plasmid replicons was investigated in more detail. No significant influence of SeqA on ori lambda-dependent DNA replication in vitro was observed, indicating that a direct regulation of lambda DNA replication by this protein is unlikely. On the other hand, density-shift experiments, in which the fate of labelled lambda DNA was monitored after phage infection of host cells, strongly suggested the early appearance of sigma replication intermediates and preferential rolling-circle replication of phage DNA in seqA mutants. The directionality of lambda plasmid replication in such mutants was, however, only slightly affected. The stability of the heritable lambda replication complex was decreased in the seqA mutant relative to the wild-type host, but a stable fraction of the lambda O protein was easily detectable, indicating that such a heritable complex can function in the mutant. To investigate the influence of seqA gene function on heritable complex- and transcription-dependent lambda DNA replication, the efficiency of lambda plasmid replication in amino acid-starved relA seqA mutants was measured. Under these conditions, seqA dysfunction resulted in impairment of lambda plasmid replication. These results indicate that unlike oriC, SeqA modulates lambda DNA replication indirectly, most probably by influencing the stability of the lambda replication complex and the transcriptional activation of ori lambda.

Plasmids derived from Gifsy-1/Gifsy-2, lambdoid prophages contributing to the virulence of Salmonella enterica serovar Typhimurium: implications for the evolution of replication initiation proteins of lambdoid phages and enterobacteria

Gifsy-1 and Gifsy-2 are lambdoid prophages which contribute to the virulence of Salmonella enterica serovar Typhimurium. The nucleotide sequence of the replication region of both prophages is identical, and similar in organization to the replication region of bacteriophage lambda. To investigate the replication of the Gifsy phages and the relationship between Gifsy and host chromosome replication, a plasmid which contained all the genes and regulatory sequences required for autonomous replication in bacterial cells was constructed. This plasmid, pGifsy, was stably maintained in Escherichia coli cells. The helicase loader of the Gifsy phages is very similar to the DnaC protein of the host, a feature characteristic of a large group of prophages common in the sequenced genomes of pathogenic enterobacteria. This DnaC-like protein showed no similarity to the helicase loader of bacteriophage lambda and closely related phages. Interestingly, unlike plasmids derived from bacteriophage lambda (lambda plasmids), pGifsy did not require a gene encoding the putative helicase loader for replication, although deletion of this gene resulted in a decrease in plasmid copy number. Under these conditions, it was shown that the plasmid utilized the helicase loader coded by the host. On the other hand, the viral protein could not substitute for DnaC in bacterial chromosome replication. The results of the current study support the hypothesis that the enterobacterial helicase loader is of viral origin. This hypothesis explains why the gene for DnaC, the protein central to both replication initiation and replication restart in E. coli, is present in the genomes of Escherichia, Shigella, Salmonella and Buchnera, but not in the genomes of related enterobacteria.

In vitro transposition of ISY100, a bacterial insertion sequence belonging to the Tc1/mariner family

The Synechocystis sp. PCC6803 insertion sequence ISY100 (ISTcSa) belongs to the Tc1/mariner/IS630 family of transposable elements. ISY100 transposase was purified and shown to promote transposition in vitro. Transposase binds specifically to ISY100 terminal inverted repeat sequences via an N-terminal DNA-binding domain containing two helix–turn–helix motifs. Transposase is the only protein required for excision and integration of ISY100. Transposase made double-strand breaks on a supercoiled DNA molecule containing a mini-ISY100 transposon, cleaving exactly at the transposon 3′ ends and two nucleotides inside the 5′ ends. Cleavage of short linear substrates containing a single transposon end was less precise. Transposase also catalysed strand transfer, covalently joining the transposon 3′ end to the target DNA. When a donor plasmid carrying a mini-ISY100 was incubated with a target plasmid and transposase, the most common products were insertions of one transposon end into the target DNA, but insertions of both ends at a single target site could be recovered after transformation into Escherichia coli. Insertions were almost exclusively into TA dinucleotides, and the target TA was duplicated on insertion. Our results demonstrate that there are no fundamental differences between the transposition mechanisms of IS630 family elements in bacteria and Tc1/mariner elements in higher eukaryotes.

Interplay between DnaA and SeqA proteins during regulation of bacteriophage lambda pR promoter activity

DnaA and SeqA proteins are main regulators (positive and negative, respectively) of the chromosome replication in Escherichia coli. Nevertheless, both these replication regulators were found recently to be also transcription factors. Interestingly, both DnaA and SeqA control activity of the bacteriophage lambdap(R) promoter by binding downstream of the transcription start site, which is unusual among prokaryotic systems. Here we asked what are functional relationships between these two transcription regulators at one promoter region. Both in vivo and in vitro studies revealed that DnaA and SeqA can activate the p(R) promoter independently and separately rather than in co-operation, however, increased concentrations of one of these proteins negatively influenced the transcription stimulation mediated by the second regulator. This may suggest a competition between DnaA and SeqA for binding to the p(R) regulatory region. The physiological significance of this DnaA and SeqA-mediated regulation of p(R) is demonstrated by studies on lambda plasmid DNA replication in vivo.

Differential effects of Kid toxin on two modes of replication of lambdoid plasmids suggest that this toxin acts before, but not after, the assembly of the replication complex

Kid is a small protein that is encoded by plasmid R1. It is a toxin that belongs to a killer system that ensures the stability of the plasmid in host cells. The results of previous studies have suggested that Kid is an inhibitor of DNA replication, possibly acting at the onset of initiation. Here, the authors tested the effects of Kid on orilambda-intitiated and oriJ-initiated replication, which may be driven by both the newly assembled replication complex and the heritable complex. It was found that Kid inhibits only replication that is driven by the newly assembled replication complex. The authors also report that Kid inhibits ColE1-like plasmid replication in vivo, in agreement with the previously reported inhibition of ColE1 during in vitro replication. It is proposed that the Kid toxin acts at the level of replication either by preventing de novo assembly of the replication complex or by impairing the functional interactions of the replication complex at the initiation stage.

Composition of the lambda plasmid heritable replication complex

Previous studies indicated during replication of plasmids derived from bacteriophage lambda (the so-called lambda plasmids), that, once assembled, replication complex can be inherited by one of the two daughter plasmid copies after each replication round, and may function in subsequent replication rounds. It seems that similar processes occur during replication of other DNA molecules, including chromosomes of the yeast Saccharomyces cerevisiae. However, apart from some suggestions based on genetic experiments, composition of the lambda heritable replication complex remains unknown. In amino acid-starved Escherichia coli relA mutants, replication of lambda plasmid DNA is carried out exclusively by the heritable replication complex as assembly of new complexes is impaired due to inhibition of protein synthesis. Here, using a procedure based on in vivo cross-linking, cell lysis, immunoprecipitation with specific sera, de-cross-linking and PCR analysis, we demonstrate that the lambda heritable replication complex consists of O, P, DnaB and, perhaps surprisingly, DnaK proteins.

Stress responses and replication of plasmids in bacterial cells

Plasmids, DNA (or rarely RNA) molecules which replicate in cells autonomously (independently of chromosomes) as non-essential genetic elements, play important roles for microbes grown under specific environmental conditions as well as in scientific laboratories and in biotechnology. For example, bacterial plasmids are excellent models in studies on regulation of DNA replication, and their derivatives are the most commonly used vectors in genetic engineering. Detailed mechanisms of replication initiation, which is the crucial process for efficient maintenance of plasmids in cells, have been elucidated for several plasmids. However, to understand plasmid biology, it is necessary to understand regulation of plasmid DNA replication in response to different environmental conditions in which host cells exist. Knowledge of such regulatory processes is also very important for those who use plasmids as expression vectors to produce large amounts of recombinant proteins. Variable conditions in large-scale fermentations must influence replication of plasmid DNA in cells, thus affecting the efficiency of recombinant gene expression significantly. Contrary to extensively investigated biochemistry of plasmid replication, molecular mechanisms of regulation of plasmid DNA replication in response to various environmental stress conditions are relatively poorly understood. There are, however, recently published studies that add significant data to our knowledge on relations between cellular stress responses and control of plasmid DNA replication. In this review we focus on plasmids derived from bacteriophage lambda that are among the best investigated replicons. Nevertheless, recent results of studies on other plasmids are also discussed shortly.

The double mechanism of incompatibility between lambda plasmids and Escherichia coli dnaA(ts) host cells

For plasmids derived from bacteriophage lambda, the initiation of bidirectional DNA replication from orilambda depends on the stimulation of transcription from the p(R) promoter by the host replication initiator protein DnaA. Certain Escherichia coli dnaA(ts) mutants cannot be transformed by wild-type lambda plasmids even at the temperature permissive to cell growth. This plasmid-host incompatibility appeared to be due to inefficient stimulation of transcription from the p(R) promoter by the mutant DnaA protein. This paper shows that there is a second mechanism for the incompatibility between lambda plasmids and dnaA(ts) hosts, exemplified in this study by the dnaA46 mutant. This is based on the competition between the lambda P protein and the host DnaA and DnaC proteins for DnaB helicase. Both mechanisms must be operative for the incompatibility.

SeqA, the Escherichia coli origin sequestration protein, is also a specific transcription factor

The SeqA protein is a negative regulator of initiation of DNA replication in the Escherichia coli chromosome. Here, we demonstrate that SeqA stimulates transcription from the bacteriophage lambda pR promoter both in vivo and in vitro. The activity of the lambda pL promoter was found not to be affected by this protein. SeqA-mediated stimulation of pR was dependent on the state of template methylation: transcription was activated on fully methylated and hemimethylated templates but not on an unmethylated template. Using electrophoretic mobility shift assay and electron microscopy, we demonstrated that SeqA interacts specifically with a pR promoter region located on both fully methylated and hemimethylated DNA molecules, but not on unmethylated DNA. The activity of SeqA was found to affect the initiation of lambda plasmid replication positively in vivo, probably via pR-dependent expression of lambda replication genes and transcriptional activation of ori lambda. We conclude that, apart from its function in the control of DNA replication, SeqA is also a specific transcription factor.

Replication of oriJ-based plasmid DNA during the stringent and relaxed responses of Escherichia coli

The oriJ-based plasmids contain the origin of DNA replication from the cryptic Rac prophage, present in the chromosomes of most Escherichia coli K-12 strains. The organization of the oriJ replication region resembles that of the bacteriophage lambda, although sequence similarity is small. Here we investigated the regulation of replication of the oriJ-based plasmid in E. coli relA(+) and relA(-) hosts during amino acid starvation and limitation, i.e., during the stringent and relaxed responses. We found that, contrary to plasmids derived from phage lambda, replication of the oriJ-based plasmid proceeds efficiently during both stringent and relaxed responses. On the other hand, density shift experiments and measurement of the stability of a putative replication initiator protein (the lambda O protein homologue) suggest that this replication may be carried out by the heritable replication complex, as previously demonstrated for lambda plasmids. We demonstrate that contrary to bacteriophage lambda p(R) promoter, an analogous promoter from the oriJ region is activated rather than inhibited at increased ppGpp levels. We propose that various responses of these promoters (p(R) and p(R-Rac), which are necessary for transcriptional activation of orilambda and perhaps oriJ, respectively) to ppGpp are responsible for differences in the replication regulation between orilambda- and oriJ-based plasmids during the stringent response.

Architecture of the Streptomyces lividans DnaA protein-replication origin complexes

The Streptomyces oriC region contains two clusters of 19 DnaA boxes separated by a spacer (134 bp). The Streptomyces DnaA protein consists, like all other DnaA proteins, of four domains: domain III and the carboxyterminal part (domain IV) are responsible for binding of ATP and DNA, respectively. Binding of the DnaA protein to the entire oriC region analysed by electron microscopy showed that the DnaA protein forms separate complexes at each of the clusters of DnaA boxes, but not at the spacer separating them. In vivo mutational analysis revealed that the number of DnaA boxes and the presence of the spacer linking both groups of DnaA boxes seem to be important for a functional Streptomyces origin. We suggest that the arrangement of DnaA boxes allows the DNA-bound DnaA protein to induce bending and looping of the oriC region. As it was shown by electrophoretic mobility shift assay and "one hybrid system", two domains, I and III, facilitate interactions between DnaA molecules. We postulate that domain I and domain III could be involved in cooperativity at distant and at closely spaced DnaA boxes, respectively. The long domain II extends the range over which N termini (domain I) of DNA-bound DnaA protein can form dimers. Thus, interactions between DnaA molecules may bring two clusters of DnaA boxes separated by the spacer into functional contact by loop formation. Removal of the spacer region or deletion of domains I and II resulted, respectively, in nucleoprotein complexes which are not fully developed, or huge nucleoprotein aggregates.

The N-terminus promotes oligomerization of the Escherichia coli initiator protein DnaA

Initiation of chromosome replication in Escherichia coli is governed by the interaction of the initiator protein DnaA with the replication origin oriC. Here we present evidence that homo-oligomerization of DnaA via its N-terminus (amino acid residues 1-86) is also essential for initiation. Results from solid-phase protein-binding assays indicate that residues 1-86 (or 1-77) of DnaA are necessary and sufficient for self interaction. Using a 'one-hybrid-system' we found that the DnaA N-terminus can functionally replace the dimerization domain of coliphage lambda cl repressor: a lambdacl-DnaA chimeric protein inhibits lambda plasmid replication as efficiently as lambdacI repressor. DnaA derivatives with deletions in the N-terminus are incapable of supporting chromosome replication from oriC, and, conversely, overexpression of the DnaA N-terminus inhibits initiation in vivo. Together, these results indicate that (i) oligomerization of DnaA N-termini is essential for protein function during initiation, and (ii) oligomerization does not require intramolecular cross-talk with the nucleotide-binding domain III or the DNA-binding domain IV. We propose that E. coli DnaA is composed of largely independent domains - or modules - each contributing a partial, though essential, function to the proper functioning of the 'holoprotein'.

Random inheritance of the replication complex by one of two daughter lambda plasmid copies after a replication round in Escherichia coli

There are two pathways for replication of plasmids derived from bacteriophage lambda (so-called lambda plasmids) in Escherichia coli. One pathway is based on the assembly of the new replication complex at ori lambda, and the second requires activity of the replication complex inherited by one of two daughter plasmid copies after each replication round. Although these two replication pathways proceed at the same time in the host cell, we previously found conditions for specific elimination of the pathway based on the assembly of the new replication complex; thus, replication is restricted to that carried out by the heritable replication complex. These conditions are (i) the relaxed response to amino acid starvation and (ii) temperature upshift of the culture of cells harboring the lambda crotsPts1 plasmid. Here we asked whether the replication complex is inherited randomly by one of two daughter plasmid copies or whether the inheritance is preferred by one particular copy, that containing the parental DNA r strand or that bearing the l strand. We performed density shift experiments which allowed us to separate plasmid DNA molecules replicated by the heritable replication complex from those devoid of the replication complex and therefore not able to replicate. Then, [3H]thymidine-labelled plasmid DNA strands were separated and hybridized to membrane-bound ssDNA containing a fragment of either the r or l strand of lambda DNA. We found roughly equal efficiency of hybridization to both r and l strands in all experimental systems used. Therefore, we conclude that the lambda replication complex is randomly inherited by one of two daughter plasmid copies rather than preferentially inherited by either the copy carrying the parental r strand or that containing the l strand.

Polyadenylation of oop RNA in the regulation of bacteriophage lambda development

We have shown that Escherichia coli pcnB mutants are lysogenized by bacteriophage lambda with lower efficiency as compared to the pcnB+ strains. Our genetic analysis revealed that expression of the lambda cII gene is decreased in the pcnB mutants. However, using various lacZ fusions we demonstrated that neither activities of pL and pR promoters nor transcription termination at tR1 were significantly impaired in the pcnB- host. On the other hand, we found that oop RNA, an antisense RNA for cII expression, is involved in this regulation. Primer protection experiments revealed that oop RNA was polyadenylated and that this polyadenylation was impaired in the pcnB mutant. We found that the oop RNA was more abundant in the pcnB mutant than in the pcnB+ strain. Furthermore, we showed that activity of the pO promoter was not stimulated in the pcnB mutant. Such findings indicated that degradation of oop RNA in the pcnB strain was slower because of inefficient polyadenylation, which could lead to more effective inhibition of cII expression by the antisense oop RNA, resulting in less efficient lysogenization of the host. The oop RNA was found previously to play a role in phage lambda development only under conditions of overproduction of this transcript. Here we demonstrate for the first time, the physiological function of oop RNA in lambda development, confirming that this short transcript plays an important role in the negative regulation of cII gene expression during lambda infection. Moreover, polyadenylation of oop RNA is one of very few known examples of specific RNA polyadenylation by PAP I in prokaryotic cells and its role in gene expression regulation.

DnaA-stimulated transcriptional activation of orilambda: Escherichia coli RNA polymerase beta subunit as a transcriptional activator contact site

We present evidence that Escherichia coli RNA polymerase beta subunit may be a transcriptional activator contact site. Stimulation of the activity of the pR promoter by DnaA protein is necessary for replication of plasmids derived from bacteriophage lambda. We found that DnaA activates the pR promoter in vitro. Particular mutations in the rpoB gene were able to suppress negative effects that certain dnaA mutations had on the replication of lambda plasmids; this suppression was allele-specific. When a potential DnaA-binding sequence located several base pairs downstream of the pR promoter was scrambled by in vitro mutagenesis, the pR promoter was no longer activated by DnaA both in vivo and in vitro. Therefore, we conclude that DnaA may contact the beta subunit of RNA polymerase during activation of the pR promoter. A new classification of prokaryotic transcriptional activators is proposed.

Structure-function correlations in the XerD site-specific recombinase revealed by pentapeptide scanning mutagenesis

Xer-mediated site-specific recombination contributes to the stability of circular chromosomes in bacteria by resolving plasmid multimers and chromosome dimers to monomers prior to cell division. Two related site-specific recombinases, XerC and XerD, each catalyse one pair of strand exchange during Xer recombination. In order to relate the recently determined structure of XerD to its function, the XerD protein was subjected to pentapeptide scanning mutagenesis, which leads to a variable five amino acid cassette being introduced randomly into the target protein. This has allowed identification of regions of XerD involved in specific DNA binding, in communicating with the partner recombinase, XerC, and in catalysis and its control. The C-terminal domain of XerD, comprising two-thirds of the protein, contains the catalytic active site and comprises ten alpha helices (alphaE to alphaN) and a beta hairpin. A flexible linker connects this domain to the N-terminal domain that comprises four alpha helices (alphaA to alphaD). Pentapeptide insertions into alphaB, alphaD, alphaG, or alphaJ interfered with DNA binding. Helices alphaG and alphaJ comprise a pseudo helix-turn-helix DNA binding motif that may provide specificity of recombinase binding. An insertion in alphaL, adjacent to an active site arginine residue, led to loss of cooperative interactions between XerC and XerD and abolished recombination activity. Other insertions close to active site residues also abolished recombination activity. Proteins with an insertion in the beta hairpin turn bound DNA, interacted cooperatively with XerC and had a phenotype that is consistent with the protein being defective in XerD catalysis. This beta hairpin appears to be highly conserved in related proteins. Insertions at a number of dispersed locations did not impair XerD catalytic activity or DNA binding, but failed to allow XerC catalysis in vivo, indicating that several sites of interaction between XerD and XerC may be important for activation of XerC catalysis by XerD.

Replication and amplification of lambda plasmids in Escherichia coli during amino acid starvation and limitation

It was demonstrated previously that replication of plasmids derived from bacteriophage lambda (so-called lambda plasmids) is inhibited in wild-type Escherichia coli cells starved for isoleucine and arginine whereas it proceeds under the same conditions in relA mutants. Since replication of other replicons during the stringent or relaxed response depends on the nature of the deprived amino acid, we investigated replication of lambda plasmids in E. coli relA+ and relA- strains starved for different amino acids. We found that replication of lambda plasmids is generally inhibited during the stringent, but not relaxed, response. Differences between cells starved for different amino acids, although reproducible, were not dramatic. Amino acid starvation was previously proposed as a method for amplification of lambda plasmid DNA in vivo. We found that during amino acid limitation lambda plasmids replicate more extensively in the relA mutants than during amino acid starvation. The efficiency of plasmid DNA amplification was found to be dependent on the kind of limited amino acid; in relA- bacteria limited for leucine we observed about 10-fold plasmid amplification. Some lambda plasmid replication was also found under these conditions in the relA+ host. The mechanism of the stringent control of lambda plasmid DNA replication has already been proposed. Here the possible mechanism of the regulation of lambda plasmid replication during amino acid limitation is presented.

Allele specificity of the Escherichia coli dnaA gene function in the replication of plasmids derived from phage lambda

We demonstrate a variation in the effects of seven alleles of the Escherichia coli dnaA gene, which cause temperature sensitivity of initiation of chromosomal replication, on the replication of lambda phage-derived plasmids at 30 degrees C. These mutants showed no allele specificity of dnaA function in replication of either of two lambda pi plasmids studied. On the other hand, the inability of the lambda P+ plasmid to replicate in dnaA508, 46 and 204 cells, in dnaB (groP A15) or in cells that are temperature sensitive for the chaperone genes dnaK756, dnaJ259 and grpE280 at 30 degrees C was suppressible by a single pi mutatation. This suggests that it is a common property of the pi protein, probably its weaker interaction with DnaB helicase, that is responsible for the suppression. One can also conclude that the DnaA-regulated transcriptional activation of ori lambda acts at the step, in which all these gene products cooperate, i.e. during preprimosome loading and chaperone-mediated release of DnaB from P protein inhibition.

The cbpA chaperone gene function compensates for dnaJ in lambda plasmid replication during amino acid starvation of Escherichia coli

We found previously that lambda plasmid DNA replication in amino acid-starved Escherichia coli relA mutants (i.e., during the relaxed response), which is carried out by the inherited replication complex, is dependent on functions of DnaK and GrpE molecular chaperones but proceeds in a dnaj mutant at a nonpermissive temperature. Here we demonstrate that this replication is inhibited when functions of both dnaJ and cbpA are impaired. In complete media, the growth of the lambda pi A66 phage (capable of replicating in E. coli dnaJ, dnaK, and grpE missense mutants at 30 degrees C), as well as efficiency of transformation by the lambda pi A66 plasmid, is significantly decreased in a dnaJ259 cbpA::kan double mutant. These results strengthen the proposal of other authors (C. Ueguchi, M. Kakeda, H. Yamada, and T. Mizuno, Proc. Natl. Acad. Sci. USA 91:1054-1058, 1994; C. Ueguchi, T. Shiozawa, M. Kakeda, H. Yamada, and T. Mizuno, J. Bacteriol. 177:3894-3896, 1995; and T. Yamashino, M. Kakeda, C. Ueguchi, and T. Mizuno, Mol. Microbiol. 13:475-483, 1994) that the cbpA gene product is a functional analog of the DnaJ chaperone in E. coli.

Transposase is the only nematode protein required for in vitro transposition of Tc1

The Tc1 element of Caenorhabditis elegans is a member of the most widespread class of DNA transposons known in nature. Here, we describe efficient and precise transposition of Tc1 in a cell-free system. Tc1 appears to jump by a cut-and-paste mechanism of transposition. The terminal 26 bp of the Tc1 terminal repeats together with the flanking TA sequence are sufficient for transposition. The target site choice in vitro is similar to that in vivo. Transposition is achieved with an extract prepared from nuclei of transgenic nematodes that overexpress Tc1 transposase but also by recombinant transposase purified from Escherichia coli. The simple reaction requirements explain why horizontal spread of Tc1/mariner transposons can occur. They also suggest that Tcl may be a good vector for transgenesis of diverse animal species.

Amplification of lambda plasmids in Escherichia coli relA mutants

It was previously demonstrated that, contrary to wild-type stringent (rel+) strains of Escherichia coli, in amino acid-starved relaxed (relA) mutants the replication of lambda plasmid proceeds for several hours. The replication leads to amplification of lambda plasmid DNA. Here, the conditions for this amplification have been optimized. The amplification efficiency depends on the temperature as well as on the nature of amino acid starvation, but it is only little or totally not dependent on the pH value of the medium in a range from 6.0 to 8.0. It seems that the most efficient amplification can be achieved by overnight cultivation of E. coli relA arg strain harbouring lambda plasmid at 36-39 degrees C in minimal medium containing Casamino acids. Under these conditions, the copy number of lambda plasmid increases from about 40 to about 300 per cell giving greater than 7-fold amplification.

Plasmid and host functions required for lambda plasmid replication carried out by the inherited replication complex

We have shown previously that in amino acid-starved, relaxed (rel-) mutants of Escherichia coli replication of the lambda plasmid occurs via the lambda O-containing replication complex (RC) that was assembled prior to the onset of amino acid starvation and is inherited by one of the two daughter plasmid circles in each replication cycle. This replication is regulated neither by binding of the lambda O initiator to ori lambda, nor by the lambda Cro-mediated repression. Here we show that it is dependent on both RNA polymerase and DnaA functions, which is consistent with our recent finding that transcriptional activation of ori lambda is under the control of DnaA. In the system studied, DnaA-regulated transcriptional activation of ori lambda seems to be the only rate-limiting process. The lambda plasmid replication mediated by the inherited RC appeared to be independent of the functions of lambda P and DnaJ required in RC assembly In vitro experiments performed by others suggest that DnaJ first binds to the ori lambda-bound lambda O-lambda P-DnaB pre-primosome and subsequently lambda P complexed with DnaJ is preferentially recognized by DnaK-GrpE; chaperone-mediated rearrangement of this structure relieves DnaB helicase of lambda P inhibition. Recently we proposed that this process is directly coupled to the insertion of the pre-primosome between DNA strands transiently separated by transcription. This last-mentioned process may be required in lambda plasmid replication mediated by the inherited RC, which appeared in turn to be dependent on DnaK and GrpE functions.