Genetic requirements of phage lambda red-mediated gene replacement in Escherichia coli K-12

Pathway construction and metabolic engineering for fermentative production of β-alanine in Escherichia coli

β-Alanine is a naturally occurring β-amino acid that has been widely applied in the life and health field. Although microbial fermentation is a promising method for industrial production of β-alanine, an efficient microbial cell factory is still lacking. In this study, a new metabolically engineered Escherichia coli strain for β-alanine production was developed through a series of introduction, deletion, and overexpression of genes involved in its biosynthesis pathway. First, the L-aspartate a-decarboxylase gene, BtADC, from Bacillus tequilensis, with higher catalytic activity to produce β-alanine from aspartate, was constitutively expressed in E. coli, leading to an increased production of β-alanine up to 2.76 g/L. Second, three native aspartate kinase genes, akI, akII, and akIII, were knocked out to promote the production of β-alanine to a higher concentration of 4.43 g/L by preventing from bypass loss of aspartate. To increase the amount of aspartate, the native AspC gene was replaced with PaeAspDH, a L-aspartate dehydrogenase gene from Pseudomonas aeruginosa, accompanied with the overexpression of the native AspA gene, to further improve the production level of β-alanine to 9.27 g/L. Last, increased biosynthesis of oxaloacetic acid (OAA) was achieved by a combination of overexpression of the native PPC, introduction of CgPC, a pyruvate decarboxylase from Corynebacterium glutamicum, and deletion of ldhA, pflB, pta, and adhE in E. coli, to further enhance the production of β-alanine. Finally, the engineered E. coli strain produced 43.12 g/L β-alanine in fed-batch fermentation. Our study will lay a solid foundation for the promising application of β-alanine in the life and health field. KEY POINTS: • Overexpression of BtADC resulted in substantial accumulation of β-alanine. • The native AspC was replaced with PaeAspDH to catalyze the transamination of OAA. • Deletion of gluDH prevented from losing carbon flux in TCA recycle. • A 43.12-g/L β-alanine production in fed-batch fermentation was achieved. Graphical abstract.

Evolutionary potential, cross-stress behavior and the genetic basis of acquired stress resistance in Escherichia coli

Escherichia coli cells were evolved over 500 generations and profiled in four abiotic stressors to observe several cases of emerging cross-stress behavior whereby adaptation to one stressful environment provided fitness advantage when exposed to a second stressor.

Cross-stress dependencies were found to be ubiquitous, highly interconnected and can emerge within short timeframes.

Several targets were implicated in adaptation and cross-stress protection, including genes related to iron transport and flagella.

Adaptation in a first stress can lead to higher fitness to a second stress when compared with cells adapted only in the latter environment.

Adaptation to any specific stress and the growth media was found to be generally independent.

Bacterial populations have a remarkable capacity to cope with extreme environmental fluctuations in their natural environments. In certain cases, adaptation to one stressful environment provides a fitness advantage when cells are exposed to a second stressor, a phenomenon that has been coined as cross-stress protection. A tantalizing question in bacterial physiology is how the cross-stress behavior emerges during evolutionary adaptation and what the genetic basis of acquired stress resistance is. To address these questions, we evolved Escherichia coli cells over 500 generations in five environments that include four abiotic stressors. Through growth profiling and competition assays, we identified several cases of positive and negative cross-stress behavior that span all strain–stress combinations. Resequencing the genomes of the evolved strains resulted in the identification of several mutations and gene amplifications, whose fitness effect was further assessed by mutation reversal and competition assays. Transcriptional profiling of all strains under a specific stress, NaCl-induced osmotic stress, and integration with resequencing data further elucidated the regulatory responses and genes that are involved in this phenomenon. Our results suggest that cross-stress dependencies are ubiquitous, highly interconnected, and can emerge within short timeframes. The high adaptive potential that we observed argues that bacterial populations occupy a genotypic space that enables a high phenotypic plasticity during adaptation in fluctuating environments.

Involvement of Escherichia coli DNA Replication Proteins in Phage Lambda Red-Mediated Homologous Recombination

The Red recombination system of bacteriophage lambda is widely used for genetic engineering because of its ability to promote recombination between bacterial chromosomes or plasmids and linear DNA species introduced by electroporation. The process is known to be intimately tied to replication, but the cellular functions which participate with Red in this process are largely unknown. Here two such functions are identified: the GrpE-DnaK-DnaJ chaperone system, and DNA polymerase I. Mutations in either function are found to decrease the efficiency of Red recombination. grpE and dnaJ mutations which greatly decrease Red recombination with electroporated DNA species have only small effects on Red-mediated transduction. This recombination event specificity suggests that the involvement of GrpE-DnaJ-DnaK is not simply an effect on Red structure or stability.

Genetic manipulation of pathogenicity loci in non-Typhimurium Salmonella

The traditional genetic tools used in Salmonella enterica serovar Typhimurium rely heavily on a high-transducing mutant of bacteriophage P22. P22 recognizes its hosts by the structure of their O-antigens, which vary among serovars of Salmonella; therefore, it cannot be used in most non-Typhimurium Salmonella, including the majority of those causing food-borne illnesses in both humans and livestock. Bacteriophage P1 infects a variety of enteric bacteria, including galE mutants of serovar Typhimurium; however, the degree to which the presence of coimmune prophages, the lack of required attachment sites or the lack of host factors act as barriers to using phage P1 in natural isolates of Salmonella is unknown. Here, we show that recombineering can be used to make virtually any serovar of Salmonella susceptible to P1 infection; as a result, P1 can be utilized for facile genetic manipulation of non-Typhimurium Salmonella, including movement of very large pathogenicity islands. A toolkit for easy manipulation of non-Typhimurium serovars of Salmonella is described.

Single-stranded heteroduplex intermediates in lambda Red homologous recombination

Background

The Red proteins of lambda phage mediate probably the simplest and most efficient homologous recombination reactions yet described. However the mechanism of dsDNA recombination remains undefined.

Results

Here we show that the Red proteins can act via full length single stranded intermediates to establish single stranded heteroduplexes at the replication fork. We created asymmetrically digestible dsDNA substrates by exploiting the fact that Redα exonuclease activity requires a 5' phosphorylated end, or is blocked by phosphothioates. Using these substrates, we found that the most efficient configuration for dsDNA recombination occurred when the strand that can prime Okazaki-like synthesis contained both homology regions on the same ssDNA molecule. Furthermore, we show that Red recombination requires replication of the target molecule.

Conclusions

Hence we propose a new model for dsDNA recombination, termed 'beta' recombination, based on the formation of ssDNA heteroduplexes at the replication fork. Implications of the model were tested using (i) an in situ assay for recombination, which showed that recombination generated mixed wild type and recombinant colonies; and (ii) the predicted asymmetries of the homology arms, which showed that recombination is more sensitive to non-homologies attached to 5' than 3' ends. Whereas beta recombination can generate deletions in target BACs of at least 50 kb at about the same efficiency as small deletions, the converse event of insertion is very sensitive to increasing size. Insertions up to 3 kb are most efficiently achieved using beta recombination, however at greater sizes, an alternative Red-mediated mechanism(s) appears to be equally efficient. These findings define a new intermediate in homologous recombination, which also has practical implications for recombineering with the Red proteins.

Vibrio cholerae LexA coordinates CTX prophage gene expression

The filamentous bacteriophage CTX Phi transmits the cholera toxin genes by infecting and lysogenizing its host, Vibrio cholerae. CTX Phi genes required for virion production initiate transcription from the strong P(A) promoter, which is dually repressed in lysogens by the phage-encoded repressor RstR and the host-encoded SOS repressor LexA. Here we identify the neighboring divergent rstR promoter, P(R), and show that RstR both positively and negatively autoregulates its own expression from this promoter. LexA is absolutely required for RstR-mediated activation of P(R) transcription. RstR autoactivation occurs when RstR is bound to an operator site centered 60 bp upstream of the start of transcription, and the coactivator LexA is bound to a 16-bp SOS box centered at position -23.5, within the P(R) spacer region. Our results indicate that LexA, when bound to its single site in the CTX Phi prophage, both represses transcription from P(A) and coactivates transcription from the divergent P(R). We propose that LexA coordinates P(A) and P(R) prophage transcription in a gene regulatory circuit. This circuit is predicted to display transient switch behavior upon induction of CTX Phi lysogens.

Production of double-stranded RNA for interference with TMV infection utilizing a bacterial prokaryotic expression system

In many species, the introduction of double-stranded RNA (dsRNA) induces potent and specific gene silencing, a phenomenon called RNA interference (RNAi). RNAi is the process of sequence-specific, posttranscriptional gene silencing (PTGS) in animals and plants, mediated by dsRNA homologous to the silenced genes. In plants, PTGS is part of a defense mechanism against virus infection, and dsRNA is the pivotal factor that induces gene silencing. Here, we report an efficient method that can produce dsRNA using a bacterial prokaryotic expression system. Using the bacteriophage lambda-dependent Red recombination system, we knocked out the rnc genes of two different Escherichia coli strains and constructed three different vectors that could produce dsRNAs. This work explores the best vector/host combinations for high output of dsRNA. In the end, we found that strain M-JM109 or the M-JM109lacY mutant strain and the vector pGEM-CP480 are the best choices for producing great quantities of dsRNA. Resistance analyses and Northern blot showed that Tobacco mosaic virus infection could be inhibited by dsRNA, and the resistance was an RNA-mediated virus resistance. Our findings indicate that exogenous dsRNA could form the basis for an effective and environmentally friendly biotechnological tool that protects plants from virus infections.

Expansion of a chromosomal repeat in Escherichia coli: roles of replication, repair, and recombination functions

Background

Previous studies of gene amplification in Escherichia coli have suggested that it occurs in two steps: duplication and expansion. Expansion is thought to result from homologous recombination between the repeated segments created by duplication. To explore the mechanism of expansion, a 7 kbp duplication in the chromosome containing a leaky mutant version of the lac operon was constructed, and its expansion into an amplified array was studied.

Results

Under selection for lac function, colonies bearing multiple copies of the mutant lac operon appeared at a constant rate of approximately 4 to 5 per million cells plated per day, on days two through seven after plating. Expansion was not seen in a recA strain; null mutations in recBCD and ruvC reduced the rate 100- and 10-fold, respectively; a ruvC recG double mutant reduced the rate 1000-fold. Expansion occurred at an increased rate in cells lacking dam, polA, rnhA, or uvrD functions. Null mutations of various other cellular recombination, repair, and stress response genes had little effect upon expansion. The red recombination genes of phage lambda could substitute for recBCD in mediating expansion. In the red-substituted cells, expansion was only partially dependent upon recA function.

Conclusion

These observations are consistent with the idea that the expansion step of gene amplification is closely related, mechanistically, to interchromosomal homologous recombination events. They additionally provide support for recently described models of RecA-independent Red-mediated recombination at replication forks.

Involvement of DNA replication in phage lambda Red-mediated homologous recombination

Crosses between a non-replicating linear bacteriophage lambda chromosome and a replicating plasmid bearing a short cloned segment of lambda DNA were monitored by extracting DNA from infected cells, and analysing it via restriction endonuclease digestion and Southern blots. Recombinant formation resulting from the action of the Red homologous recombination system, observed directly in this way, was found to be fast, efficient, independent of the bacterial recA function and highly dependent upon replication of the target plasmid. These features of the experimental system faithfully model Red-mediated recombination in a lytically infected cell in which phage DNA replication is occurring. Neither of the previously established mechanisms by which the Red system can operate--strand annealing or strand invasion--accounts well for these findings. A third mechanism, replisome invasion, involving replication directly in the recombination mechanism, is invoked as an alternative.

Requirements for ATP binding and hydrolysis in RecA function in Escherichia coli

RecA is essential for recombination, DNA repair and SOS induction in Escherichia coli. ATP hydrolysis is known to be important for RecA's roles in recombination and DNA repair. In vitro reactions modelling SOS induction minimally require ssDNA and non-hydrolyzable ATP analogues. This predicts that ATP hydrolysis will not be required for SOS induction in vivo. The requirement of ATP binding and hydrolysis for SOS induction in vivo is tested here through the study of recA4159 (K72A) and recA2201 (K72R). RecA4159 is thought to have reduced affinity for ATP. RecA2201 binds, but does not hydrolyse ATP. Neither mutant was able to induce SOS expression after UV irradiation. RecA2201, unlike RecA4159, could form filaments on DNA and storage structures as measured with RecA-GFP. RecA2201 was able to form hybrid filaments and storage structures and was either recessive or dominant to RecA(+), depending on the ratio of the two proteins. RecA4159 was unable to enter RecA(+) filaments on DNA or storage structures and was recessive to RecA(+). It is concluded that ATP hydrolysis is essential for SOS induction. It is proposed that ATP binding is essential for storage structure formation and ability to interact with other RecA proteins in a filament.

UvrD limits the number and intensities of RecA-green fluorescent protein structures in Escherichia coli K-12

RecA is important for recombination, DNA repair, and SOS induction. In Escherichia coli, RecBCD, RecFOR, and RecJQ prepare DNA substrates onto which RecA binds. UvrD is a 3'-to-5' helicase that participates in methyl-directed mismatch repair and nucleotide excision repair. uvrD deletion mutants are sensitive to UV irradiation, hypermutable, and hyper-rec. In vitro, UvrD can dissociate RecA from single-stranded DNA. Other experiments suggest that UvrD removes RecA from DNA where it promotes unproductive reactions. To test if UvrD limits the number and/or the size of RecA-DNA structures in vivo, an uvrD mutation was combined with recA-gfp. This recA allele allows the number of RecA structures and the amount of RecA at these structures to be assayed in living cells. uvrD mutants show a threefold increase in the number of RecA-GFP foci, and these foci are, on average, nearly twofold higher in relative intensity. The increased number of RecA-green fluorescent protein foci in the uvrD mutant is dependent on recF, recO, recR, recJ, and recQ. The increase in average relative intensity is dependent on recO and recQ. These data support an in vivo role for UvrD in removing RecA from the DNA.

Two transsulfurylation pathways in Klebsiella pneumoniae

In most bacteria, inorganic sulfur is assimilated into cysteine, which provides sulfur for methionine biosynthesis via transsulfurylation. Here, cysteine is transferred to the terminal carbon of homoserine via its sulfhydryl group to form cystathionine, which is cleaved to yield homocysteine. In the enteric bacteria Escherichia coli and Salmonella enterica, these reactions are catalyzed by irreversible cystathionine-gamma-synthase and cystathionine-beta-lyase enzymes. Alternatively, yeast and some bacteria assimilate sulfur into homocysteine, which serves as a sulfhydryl group donor in the synthesis of cysteine by reverse transsulfurylation with a cystathionine-beta-synthase and cystathionine-gamma-lyase. Herein we report that the related enteric bacterium Klebsiella pneumoniae encodes genes for both transsulfurylation pathways; genetic and biochemical analyses show that they are coordinately regulated to prevent futile cycling. Klebsiella uses reverse transsulfurylation to recycle methionine to cysteine during periods of sulfate starvation. This methionine-to-cysteine (mtc) transsulfurylation pathway is activated by cysteine starvation via the CysB protein, by adenosyl-phosphosulfate starvation via the Cbl protein, and by methionine excess via the MetJ protein. While mtc mutants cannot use methionine as a sulfur source on solid medium, they will utilize methionine in liquid medium via a sulfide intermediate, suggesting that an additional nontranssulfurylation methionine-to-cysteine recycling pathway(s) operates under these conditions.

Rapid allelic exchange in enterohemorrhagic Escherichia coli (EHEC) and other E. coli using lambda red recombination

This unit describes an allelic exchange system for enterohemorrhagic E. coli (EHEC), and similar pathogenic species of bacteria. The phage lambda Red recombination system is expressed from a plasmid, inducing a hyper-recombinogenic state where electroporated PCR-generated substrates recombine with the bacterial chromosome at high efficiency. The technique can be used to substitute a drug marker for the gene of interest, or used to generate a clean in-frame deletion of the target gene. Single gene knockouts in EHEC, or deletions of whole pathogenicity islands, can be constructed. A procedure for the preparation of hyper-recombinogenic electrocompetent cells is also described. Besides E. coli K-12 and EHEC, this method has also been used for the construction of gene knockouts in enteropathogenic E. coli (EPEC), enteroaggregative E. coli, and uropathogenic E. coli, as well as Shigella flexneri and Salmonella enterica.

Cloning and expression of IspDF from Mesorhizobium loti. Characterization of a bifunctional protein that catalyzes non-consecutive steps in the methylerythritol phosphate pathway

Gram-negative bacteria, plant chloroplasts, green algae and some Gram-positive bacteria utilize the 2-C-methyl-d-erythritol phosphate (MEP) pathway for the biosynthesis of isoprenoids. IspD, ispE, and ispF encode the enzymes required to convert MEP to 2-C-methyl-d-erythritol 2,4-cyclodiphosphate (cMEDP) during the biosynthesis of isopentenyl diphosphate and dimethylallyl diphosphate in the MEP pathway. Upon analysis of the Mesorhizobium loti genome, ORF mll0395 showed homology to both ispD and ispF and appeared to encode a fusion protein. M. loti ispE was located elsewhere on the chromosome. Purified recombinant IspDF protein was mostly a homodimer, MW approximately 46 kDa/subunit. Incubation of IspDF with MEP, CTP, and ATP gave 4-diphosphocytidyl-2-C-methyl-d-erythritol (CDP-ME) as the only product. When Escherichia coli IspE protein was added to the incubation mixture, cMEDP was formed. In addition, M. loti ORF mll0395 complements lethal disruptions in both ispD and ispF in Salmonella typhimurium. These results indicate that IspDF is a bifunctional protein, which catalyzes the first and third steps in the conversion of MEP to cMEDP.

NinR- and red-mediated phage-prophage marker rescue recombination in Escherichia coli: recovery of a nonhomologous immlambda DNA segment by infecting lambdaimm434 phages

We examined the requirement of lambda recombination functions for marker rescue of cryptic prophage genes within the Escherichia coli chromosome. We infected lysogenic host cells with lambdaimm434 phages and selected for recombinant immlambda phages that had exchanged the imm434 region of the infecting phage for the heterologous 2.6-kb immlambda region from the prophage. Phage-encoded activity, provided by either Red or NinR functions, was required for the substitution. Red(-) phages with DeltaNinR, internal NinR deletions of rap-ninH, or orf-ninC were 117-, 12-, and 5-fold reduced for immlambda rescue in a Rec(+) host, suggesting the participation of several NinR activities. RecA was essential for NinR-dependent immlambda rescue, but had slight influence on Red-dependent rescue. The host recombination activities RecBCD, RecJ, and RecQ participated in NinR-dependent recombination while they served to inhibit Red-mediated immlambda rescue. The opposite effects of several host functions toward NinR- and Red-dependent immlambda rescue explains why the independent pathways were not additive in a Rec(+) host and why the NinR-dependent pathway appeared dominant. We measured the influence of the host recombination functions and DnaB on the appearance of orilambda-dependent replication initiation and whether orilambda replication initiation was required for immlambda marker rescue.

Chromosomal duplications and cointegrates generated by the bacteriophage lamdba Red system in Escherichia coli K-12

Background

An Escherichia coli strain in which RecBCD has been genetically replaced by the bacteriophage λ Red system engages in efficient recombination between its chromosome and linear double-stranded DNA species sharing sequences with the chromosome. Previous studies of this experimental system have focused on a gene replacement-type event, in which a 3.5 kbp dsDNA consisting of the cat gene and flanking lac operon sequences recombines with the E. coli chromosome to generate a chloramphenicol-resistant Lac- recombinant. The dsDNA was delivered into the cell as part of the chromosome of a non-replicating λ vector, from which it was released by the action of a restriction endonuclease in the infected cell. This study characterizes the genetic requirements and outcomes of a variety of additional Red-promoted homologous recombination events producing Lac+ recombinants.

Results

A number of observations concerning recombination events between the chromosome and linear DNAs were made: (1) Formation of Lac+ and Lac- recombinants depended upon the same recombination functions. (2) High multiplicity and high chromosome copy number favored Lac+ recombinant formation. (3) The Lac+ recombinants were unstable, segregating Lac- progeny. (4) A tetracycline-resistance marker in a site of the phage chromosome distant from cat was not frequently co-inherited with cat. (5) Recombination between phage sequences in the linear DNA and cryptic prophages in the chromosome was responsible for most of the observed Lac+ recombinants. In addition, observations were made concerning recombination events between the chromosome and circular DNAs: (6) Formation of recombinants depended upon both RecA and, to a lesser extent, Red. (7) The linked tetracycline-resistance marker was frequently co-inherited in this case.

Conclusions

The Lac+ recombinants arise from events in which homologous recombination between the incoming linear DNA and both lac and cryptic prophage sequences in the chromosome generates a partial duplication of the bacterial chromosome. When the incoming DNA species is circular rather than linear, cointegrates are the most frequent type of recombinant.

Unequal access of chromosomal regions to each other in Salmonella: probing chromosome structure with phage lambda integrase-mediated long-range rearrangements

We have investigated the fluidity of the Salmonella chromosome architecture using the phage lambda site-specific recombination system as a probe. We determined how chromosome position affects the extent of integrase-mediated recombination between pairs of inversely oriented att sites at various loci. We also investigated the accessibility of each chromosomal att site to an extrachromosomal partner carried on a low-copy plasmid. Recombination events were assayed by semi-quantitative polymerase chain reaction of the attP product. The extent of recombination between the chromosome and the plasmid was generally higher than intrachromosomal recombination except for two loci, araA::attL and galT::attL, which gave no detectable recombination with any other locus. Based on 20 intervals, we found that chromosomal locations are not equally accessible to each other. Although multiple factors probably affect accessibility, the most important is the specific combination of the end-points used. Neither the size of the intervals nor the accessibility of individual end-points to extrachromosomal sequences is as important. These results suggest that the chromosome is not completely fluid but rather organized in some way, with barriers that limit the movement of DNA within the cell. The nature of the barriers involved in chromosomal organization remains to be determined.

Modulation of DNA repair and recombination by the bacteriophage lambda Orf function in Escherichia coli K-12

The orf gene of bacteriophage lambda, fused to a promoter, was placed in the galK locus of Escherichia coli K-12. Orf was found to suppress the recombination deficiency and sensitivity to UV radiation of mutants, in a Delta(recC ptr recB recD)::P(tac) gam bet exo pae cI DeltarecG background, lacking recF, recO, recR, ruvAB, and ruvC functions. It also suppressed defects of these mutants in establishing replication of a pSC101-related plasmid. Compared to orf, the recA803 allele had only small effects on recF, recO, and recR mutant phenotypes and no effect on a ruvAB mutant. In a fully wild-type background with respect to known recombination and repair functions, orf partially suppressed the UV sensitivity of ruvAB and ruvC mutants.

The sorbitol phosphotransferase system is responsible for transport of 2-C-methyl-D-erythritol into Salmonella enterica serovar typhimurium

2-C-methyl-D-erythritol 4-phosphate is the first committed intermediate in the biosynthesis of the isoprenoid precursors isopentenyl diphosphate and dimethylallyl diphosphate. Supplementation of the growth medium with 2-C-methyl-D-erythritol has been shown to complement disruptions in the Escherichia coli gene for 1-deoxy-D-xylulose 5-phosphate synthase, the enzyme that synthesizes the immediate precursor of 2-C-methyl-D-erythritol 4-phosphate. In order to be utilized in isoprenoid biosynthesis, 2-C-methyl-D-erythritol must be phosphorylated. We describe the construction of Salmonella enterica serovar Typhimurium strain RMC26, in which the essential gene encoding 1-deoxy-D-xylulose 5-phosphate synthase has been disrupted by insertion of a synthetic mevalonate operon consisting of the yeast ERG8, ERG12, and ERG19 genes, responsible for converting mevalonate to isopentenyl diphosphate under the control of an arabinose-inducible promoter. Random mutagenesis of RMC26 produced defects in the sorbitol phosphotransferase system that prevented the transport of 2-C-methyl-D-erythritol into the cell. RMC26 and mutant strains of RMC26 unable to grow on 2-C-methyl-D-erythritol were incubated in buffer containing mevalonate and deuterium-labeled 2-C-methyl-D-erythritol. Ubiquinone-8 was isolated from these cells and analyzed for deuterium content. Efficient incorporation of deuterium was observed for RMC26. However, there was no evidence of deuterium incorporation into the isoprenoid side chain of ubiquinone Q8 in the RMC26 mutants.

Genetic engineering using homologous recombination

In the past few years, in vivo technologies have emerged that, due to their efficiency and simplicity, may one day replace standard genetic engineering techniques. Constructs can be made on plasmids or directly on the Escherichia coli chromosome from PCR products or synthetic oligonucleotides by homologous recombination. This is possible because bacteriophage-encoded recombination functions efficiently recombine sequences with homologies as short as 35 to 50 base pairs. This technology, termed recombineering, is providing new ways to modify genes and segments of the chromosome. This review describes not only recombineering and its applications, but also summarizes homologous recombination in E. coli and early uses of homologous recombination to modify the bacterial chromosome. Finally, based on the premise that phage-mediated recombination functions act at replication forks, specific molecular models are proposed.

Gene replacement without selection: regulated suppression of amber mutations in Escherichia coli

We have developed a method called "gene gorging" to make precise mutations in the Escherichia coli genome at frequencies high enough (1-15%) to allow direct identification of mutants by PCR or other screen rather than by selection. Gene gorging begins by establishing a donor plasmid carrying the desired mutation in the target cell. This plasmid is linearized by in vivo expression of the meganuclease I-SceI, providing a DNA substrate for lambda Red mediated recombination. This results in efficient replacement of the wild type allele on the chromosome with the modified sequence. We demonstrate gene gorging by introducing amber stop codons into the genes xylA, melA, galK, fucI, citA, ybdO, and lacZ. To compliment this approach we developed an arabinose inducible amber suppressor tRNA. Controlled expression mediated by the suppressor was demonstrated for the lacZ and xylA amber mutants.

Recombination-promoting activity of the bacteriophage lambda Rap protein in Escherichia coli K-12

The rap gene of bacteriophage lambda was placed in the chromosome of an Escherichia coli K-12 strain in which the recBCD gene cluster had previously been replaced by the lambda red genes and in which the recG gene had been deleted. Recombination between linear double-stranded DNA molecules and the chromosome was tested in variants of the recGDelta red(+) rap(+) strain bearing mutations in genes known to affect recombination in other cellular pathways. The linear DNA was a 4-kb fragment containing the cat gene, with flanking lac sequences, released from an infecting phage chromosome by restriction enzyme cleavage in the cell. Replacement of wild-type lacZ with lacZ::cat was monitored by measuring the production of Lac-deficient chloramphenicol-resistant bacterial progeny. The results of these experiments indicated that the lambda rap gene could functionally substitute for the E. coli ruvC gene in Red-mediated recombination.

Phage lambda red-mediated adaptive mutation

Replacement of the recBCD genes of Escherichia coli with the red recombination genes of bacteriophage lambda results in a strain in which adaptive mutation occurs at an elevated frequency. Like RecBCD-dependent adaptive mutation, Red-mediated adaptive mutation is dependent upon recA and ruvABC functions.

Gene products encoded in the ninR region of phage lambda participate in Red-mediated recombination

BACKGROUND

The ninR region of phage lambda contains two recombination genes, orf (ninB) and rap (ninG), that were previously shown to have roles when the RecF and RecBCD recombination pathways of E. coli, respectively, operate on phage lambda.

RESULTS

When lambda DNA replication is blocked, recombination is focused at the termini of the virion chromosome. Deletion of the ninR region of lambda decreases the sharpness of the focusing without diminishing the overall rate of recombination. The phenotype is accounted for in large part by the deletion of rap and of orf. Mutation of the recJ gene of the host partially suppresses the Rap- phenotype.

CONCLUSION

ninR functions Orf and Rap participate in Red recombination, the primary pathway operating when wild-type lambda grows lytically in rec+ cells. The ability of recJ mutation to suppress the Rap- phenotype indicates that RecJ exonuclease can participate in Red-mediated recombination, at least in the absence of Rap function. A model is presented for Red-mediated RecA-dependent recombination that includes these newly identified participants.

A tale of two HSV-1 helicases: roles of phage and animal virus helicases in DNA replication and recombination

Helicases play essential roles in many important biological processes such as DNA replication, repair, recombination, transcription, splicing, and translation. Many bacteriophages and plant and animal viruses encode one or more helicases, and these enzymes have been shown to play many roles in their respective viral life cycles. In this review we concentrate primarily on the roles of helicases in DNA replication and recombination with special emphasis on the bacteriophages T4, T7, and A as model systems. We explore comparisons between these model systems and the herpesviruses--primarily herpes simplex virus. Bacteriophage utilize various pathways of recombination-dependent DNA replication during the replication of their genomes. In fact the study of recombination in the phage systems has greatly enhanced our understanding of the importance of recombination in the replication strategies of bacteria, yeast, and higher eukaryotes. The ability to "restart" the replication process after a replication fork has stalled or has become disrupted for other reasons is a critical feature in the replication of all organisms studied. Phage helicases and other recombination proteins play critical roles in the "restart" process. Parallels between DNA replication and recombination in phage and in the herpesviruses is explored. We and others have proposed that recombination plays an important role in the life cycle of the herpesviruses, and in this review, we discuss models for herpes simplex virus type 1 (HSV-1) DNA replication. HSV-1 encodes two helicases. UL9 binds specifically to the origins of replication and is believed to initiate HSV DNA replication by unwinding at the origin; the heterotrimeric helicase-primase complex, encoded by UL5, UL8, and UL52 genes, is believed to unwind duplex viral DNA at replication forks. Structure-function analyses of UL9 and the helicase-primase are discussed with attention to the roles these proteins might play during HSV replication.

Type I topoisomerase activity is required for proper chromosomal segregation in Escherichia coli

Type I DNA topoisomerases are ubiquitous enzymes involved in many aspects of DNA metabolism. Escherichia coli possesses two type I topoisomerase activities, DNA topoisomerase I (Topo I) and III (Topo III). The gene encoding Topo III (topB) can be deleted without affecting cell viability. Cells possessing a deletion of the gene encoding Topo I (topA) are only viable in the presence of an additional compensatory mutation. In the presence of compensatory mutations, Topo I deletion strains grow normally; however, if Topo III activity is repressed in these cells, they filament extensively and possess an abnormal nucleoid structure. These defects can be suppressed by the deletion of the recA gene, suggesting that these enzymes may be involved in RecA-mediated recombination and may specifically resolve recombination intermediates before partitioning.

What makes the bacteriophage lambda Red system useful for genetic engineering: molecular mechanism and biological function

Recent studies have generated interest in the use of the homologous recombination system of bacteriophage lambda for genetic engineering. The system, called Red, consists primarily of three proteins: lambda exonuclease, which processively digests the 5'-ended strand of a dsDNA end; beta protein, which binds to ssDNA and promotes strand annealing; and gamma protein, which binds to the bacterial RecBCD enzyme and inhibits its activities. These proteins induce a 'hyper-rec' state in Escherichia coli and other bacteria, in which recombination events between DNA species with as little as 40 bp of shared sequence occur at high frequency. Red-mediated recombination in the hyper-rec bacterium proceeds via a number of different pathways, and with the involvement of different sets of bacterial proteins, depending in part on the nature of the recombining DNA species. The role of high-frequency double-strand break repair/recombination in the life cycle of the lambdoid phages is discussed.