Homologous interactions of λ repressor and λ Cro with the λ operator

Lambda repressor and lambda Cro bind to the same six sites on the phage chromosome but with different relative affinities. Nucleotides at certain positions in the operator are conserved in all sites, as are amino acids at certain positions in the recognition α-helices of repressor and Cro. Here we focus on one of the conserved amino acids, a serine found at position 2 of each recognition helix. We show that, contrary to a previous model, both serines contact the same conserved position in the operator, position 4. We suggest a simplified view of how repressor and Cro recognize similar operator sites but distinguish differently among them.     

Mechanism for the Action of λ Exonuclease in Genetic Recombination

Lambda exonuclease degrades in vitro redundant single stranded regions which probably result in λ DNA from genetic recombination in vivo.     

Molecular simulation uncovers the conformational space of the λ Cro dimer in solution

The significant variation among solved structures of the λ Cro dimer suggests its flexibility. However, contacts in the crystal lattice could have stabilized a conformation which is unrepresentative of its dominant solution form. Here we report on the conformational space of the Cro dimer in solution using replica exchange molecular dynamics in explicit solvent. The simulated ensemble shows remarkable correlation with available x-ray structures. Network analysis and a free energy surface reveal the predominance of closed and semi-open dimers, with a modest barrier separating these two states. The fully open conformation lies higher in free energy, indicating that it requires stabilization by DNA or crystal contacts. Most NMR models are found to be unstable conformations in solution. Intersubunit salt bridging between Arg⁴ and Glu⁵³ during simulation stabilizes closed conformations. Because a semi-open state is among the low-energy conformations sampled in simulation, we propose that Cro-DNA binding may not entail a large conformational change relative to the dominant dimer forms in solution.     

Calculating biological behaviors of epigenetic states in the phage λ life cycle

The biology and behavior of bacteriophage regulation have been the focus of classical investigations of molecular control of gene expression. Both qualitative and quantitative aspects of this behavior have been systematically characterized experimentally. Complete understanding of the robustness and stability of the genetic circuitry for the lysis-lysogeny switch remains an unsolved puzzle. It is an excellent test case for our understanding of biological behavior of an integrated network based on its physical, chemical, DNA, protein, and functional properties. We have used a new approach to non-linear dynamics to formulate a new mathematical model, performed a theoretical study on the phage life cycle, and solved the crucial part of this puzzle. We find a good quantitative agreement between the theoretical calculation and published experimental observations in the protein number levels, the lysis frequency in the lysogen culture, and the lysogenization frequency for mutants of O_R. We also predict the desired robustness for the genetic switch. We believe that this is the first successful example in the quantitative calculation of robustness and stability of the phage regulatory network, one of the simplest and most well-studied regulatory systems.     

ClpP/ClpX-mediated degradation of the bacteriophage λ O protein and regulation of λ phage and λ plasmid replication

The O protein is a replication initiator that binds to the orilambda region and promotes assembly of the bacteriophage lambda replication complex. This protein, although protected from proteases by other elements of the replication complex, in a free form is rapidly degraded in the host, Escherichia coli, by the ClpP/ClpX protease. Nevertheless, the physiological role of this rapid degradation remains unclear. Here we demonstrate that the copy number of plasmids derived from bacteriophage lambda is significantly higher in wild-type cells growing in rich media than in slowly growing bacteria. However, lambda plasmid copy number in bacteria devoid of the ClpP/ClpX protease was not dependent on the bacterial growth rate and in all minimal media tested was comparable to that observed in wildtype cells growing in a rich medium. Contrary to lambda plasmid replication, the efficiency of lytic growth of bacteriophage lambda was found to be dependent on the host growth rate in both wild-type bacteria and clpP and clpX mutants. The activities of two major lambda promoters operating during the lytic development, p(R) and p(L), were found to be slightly dependent on the host growth rate. However, when p(R) activity was significantly decreased in the dnaA mutant, production of phage progeny was completely abolished at low growth rates. These results indicate that the O protein (whose level in E. coli cells depends on the activity of ClpP/ClpX protease) is a major limiting factor in the regulation of lambda plasmid replication at low bacterial growth rates. However, this protein seems to be only one of the limiting factors in the bacteriophage lambda lytic development under poor growth conditions of host cells. Therefore, it seems that the role of the rapid ClpP/ClpX-mediated proteolysis of the O protein is to decrease the efficiency of early DNA replication of the phage in slowly growing host cells.     

Deletion Mapping of the λ REX Gene

Deletion mapping has been used to order 12 λ rex^- mutants. Correlation of recombination data with physically-determined positions of deletion end-points (Szybalski 1971; Blattner et al. 1972) suggests that the left-most rex^- mutation, rex209, is located about 260-300 nucleotide pairs from the p_L mutation sex1 and about 475 nucleotide pairs from the left end-point of the region of nonhomology with λimm434.     

Deoxyribonucleic Acid Replication in λ Bacteriophage Mutants

After ultraviolet light induction of Escherichia coli K-12 strain W3350(λ), several structural intermediate forms of phage deoxyribonucleic acid (DNA) are synthesized. The early defective lysogens of λ, sus O₈, sus P₃, and T₁₁, were found to synthesize none of the DNA structural intermediates. A lysogen believed to be defective in all known phage activities, λsus N₇, was found to be able to synthesize an early phage DNA intermediate. The lysogen λsus Q₂₁, defective in late phage functions, is able to synthesize the early phage DNA intermediate and a concatenated molecule of greater molecular weight than the mature λ DNA.     

Formation and Stability of the Bacteriophage λ Replication Complexes in UV-Irradiated Escherichia coli

Bacteriophage λ replication complex, containing the phage-encoded O initiator protein protected from proteases by other elements of this complex, is a stable structure that can be inherited by one of the two daughter λ DNA copies after a replication round in Escherichia coli. In normal growth conditions in bacteria bearing a plasmid derived from bacteriophage λ, such a complex may be stable for many cell generations. However, it was found that this stable structure is disassembled under certain conditions, namely, after heat shock. Therefore, we asked whether other environmental stresses may cause disassembly of the λ replication complex. We found that UV irradiation of the host cells prevented formation of the stable λ replication complex (though not preventing phage replication), while the same UV doses did not affect the stability of the replication complex assembled prior to the irradiation. These results indicate that the stable λ replication complex, although sensitive to heat shock, is resistant to some other environmental stresses and that formation of at least two types of λ replication complexes is possible. Both stable and unstable λ replication complexes are functional because replication of λ DNA under conditions preventing formation of the stable complex proceeds efficiently. Received: 18 January 2000 / Accepted: 2 March 2000     

The C-terminus of the phage λ Orf recombinase is involved in DNA binding

Phage λ Orf substitutes for the activities of the Escherichia coli RecFOR proteins in vivo and is therefore implicated as a recombination mediator, encouraging the assembly of bacterial RecA onto single-stranded DNA (ssDNA) coated with SSB. Orf exists as a dimer in solution, associates with E. coli SSB and binds preferentially to ssDNA. To help identify interacting domains we analysed Orf and SSB proteins carrying mutations or truncations in the C-terminal region. A cluster of acidic residues at the carboxy-terminus of SSB is known to attract multiple protein partners to assist in DNA replication and repair. In this case an alternative domain must be utilized since Orf association with SSB was unaffected by an SSB113 point mutant (P176S) or removal of the last ten residues (ΔC10). Structurally the Orf C-terminus consists of a helix with a flexible tail that protrudes from each side of the dimer and could serve as a binding site for either SSB or DNA. Eliminating the six residue flexible tail (ΔC6) or the entire helix (ΔC19) had no significant impact on the Orf-SSB interaction. However, the OrfΔC6 protein exhibited reduced DNA binding, a feature shared by single amino acid substitutions within (W141F) or adjacent (R140A) to this region. The OrfΔC19 mutant bound poorly to DNA and secondary structure analysis in solution revealed that this truncation induces protein misfolding and aggregation. The results show that the carboxy-terminus of Orf is involved in nucleic acid recognition and also plays an unexpected role in maintaining structural integrity.     

Induction threshold of the Q - mutant of bacteriophage λ in Escherichia coli

Temperature induction of bacteriophage in Escherichia coli depends on bacterial population density. The lowest rate of viability loss at the temperature threshold results in maximal gene expression of . -Infection causes bacterial cells to lose cell viability and thus decrease temperature induction efficiency. In addition, shifting-up in temperature increases the probability of progeny ; thus, the mortality of bacterial hosts increases and the expression of recombinant proteins by naked significantly decrease.     

Genetic Heterozygosity in Unreplicated Bacteriophage λ Recombinants

Bacteriophage crosses using density-labeled parents have been carried out under conditions restricting DNA synthesis. The parental material and genetic contributions to progeny manifesting recombination within a genetic interval sufficiently short to exhibit high negative interference have been examined. The unreplicated products of recombination isolated as phage particles appear to contain long continuous heteroduplex regions which are heterozygous for the closely linked markers. Recombination between closely linked markers seems to be the consequence of the removal of base-pair mismatches that are present within the heteroduplex regions. This localized reduction of heterozygosity within the heteroduplex regions that join the parental components of recombinant DNA molecules can account for high negative interference.     

Heat-Sensitive Early Function in Induced λ Nsus Lysogens

Mutations in gene N of lambda prevent killing of the host bacterium after infection. However, derepression of Nsus prophages in nonpermissive (pm(-)) bacteria results in death of the lysogens. When prophages in pm(-)(lambdaCItsA-Nsus) lysogens are derepressed by raising the temperature to 45 C, the cells remain viable as long as they are at 45 C. However, they cannot form colonies at 33 C unless they have been superinfected, at the high temperature, by lambdaCI(+)-Nsus phage which produces repressor at 45 C. A large fraction of these "rescued," heat-inducible lysogens are lysogenized by the superinfecting phage, but lysogenization is not required for rescue. In pm(-)(lambdaCItsA-Nsus) lysogens growing at 45 C, the rate of deoxyribonucleic acid (DNA) synthesis shows a characteristic increase after the temperature is lowered. This increased DNA synthesis, which is correlated with loss of rescue potential, does not occur as long as the cultures are maintained at 45 C.     

Roles for λ Orf and Escherichia Coli Reco, Recr and Recf in λ Recombination

Bacteriophage λ lacking its Red recombination functions requires either its own gene product, Orf, or the product of Escherichia coli's recO, recR and recF genes (RecORF) for efficient recombination in recBC sbcB sbcC mutant cells (the RecF pathway). Phage crosses under conditions of a partial block to DNA replication have revealed the following: (1) In the presence of Orf, RecF pathway recombination is similar to λ Red recombination; (2) Orf is necessary for focusing recombination toward the right end of the chromosome as λ is conventionally drawn; (3) RecORF-mediated RecF pathway recombination is not focused toward the right end of the chromosome, which may indicate that RecORF travels along the DNA; (4) both Orf- and RecORF-mediated RecF pathway recombination are stimulated by DNA replication; and (5) low level recombination in the simultaneous absence of Orf and RecORF may occur by a break-copy mechanism that is not initiated by a double strand break. Models for the roles of Orf and RecO, RecR and RecF in recombination are presented.     

Annealing Vs. Invasion in Phage λ Recombination

Genetic recombination catalyzed by λ's Red pathway was studied in rec(+) and recA mutant bacteria by examining both intracellular λ DNA and mature progeny particles. Recombination of nonreplicating phage chromosomes was induced by double-strand breaks delivered at unique sites in vivo. In rec(+) cells, cutting only one chromosome gave nearly maximal stimulation of recombination; the recombinants formed contained relatively short hybrid regions, suggesting strand invasion. In contrast, in recA mutant cells, cutting the two parental chromosomes at non-allelic sites was required for maximal stimulation; the recombinants formed tended to be hybrid over the entire region between the two cuts, implying strand annealing. We conclude that, in the absence of RecA and the presence of non-allelic DNA ends, the Red pathway of λ catalyzes recombination primarily by annealing.     

Adsorption of phage λ to Salmonella typhimurium lamB + requires the presence of lipopolysaccharide in the outer membrane

Summary Two S. typhimurium strains TA1534 (rfa ⁺) and TA1538 (rfaE) were transformed with the lamB expression plasmid pAMH70. Transposition events with placMu55 hybrid phage were successful only with TA1534/pAMH70 strain. Using SDS-PAGE, the LamB protein was present in the total cell proteins but not in the outer membrane proteins of the TA1538/pAMH70 strain. The LamB protein must linked to the LPS of the outer membrane to allow adsorption of phage in S. typhimurium.     

Catenation and supercoiling in the products of bacteriophage λ integrative recombination in vitro

Catenanes (interlocked circular DNA molecules) are the exclusive products of the bacteriophage λ integrative recombination reaction in vitro when the substrate is a supercoiled DNA molecule containing both the attP and attB sites. It is proposed that the catenation results from the superhelical form of the substrate DNA. We also show that both circular DNA products of a single recombination event can be recovered as superhelical molecules with a superhelical density approximately that of the substrate DNA. The recombination reaction must therefore occur as a coupled process which does not permit free rotation around single-strand breaks at any stage.     

Genetic Analysis of the Bacteriophage λ Attl Nucleoprotein Complex

Site-specific recombination in bacteriophage λ involves interactions among proteins required for integration and excision of DNA molecules. We have analyzed the elements required to form an in vivo nucleoprotein complex of integrase (Int) and integration host factor (IHF). Interaction of Int with the core (the site of strand exchange) is stabilized by the flanking arm region of attL. IHF, in addition to Int, is required for efficient Int-core binding. We used the in vivo attL binding assay to characterize several Int variants for their abilities to form stable attL complexes. Substitution of Int active site tyrosine 342 by phenylalanine had no effect on the ability of the protein to form attL complexes. Three other amino acids that are completely conserved in the integrase family of recombinases (arginine 212, histidine 308, and arginine 311) were separately substituted by glutamine, leucine, and histidine, respectively. In each case, the mutant protein was altered in its ability to form attL complexes while retaining its ability to bind to the λ arm-type sites. We propose that, in addition to their role in catalysis, this triad of amino acids helps the Int protein to interact with the λ core sites.