Lambda phage

About: Lambda phage is a research topic. Over the lifetime, 1609 publications have been published within this topic receiving 84675 citations. The topic is also known as: Enterobacteria phage lambda.

The role of the OOP antisense RNA in coliphage λ development

Abstract: We have made a derivative of bacteriophage lambda that makes no OOP antisense RNA. The mutant phage carries a point mutation that inactivates the OOP promoter, po. The phages lambda + and lambda po- have identical plaque morphologies, one-step growth curves, and frequencies of lysogenization of a sensitive host. OOP RNA synthesis is weakly repressed by the Escherichia coli LexA protein. Consonant with this inducibility of OOP RNA synthesis by ultraviolet light, we find a two-fold greater phage burst following ultraviolet induction of a lambda + than of a lambda po- prophage. In lambda + infections, OOP RNA causes two cleavage events in cll mRNA: one is in the 3'-end of the coding region, and the second is in the intercistronic region between the cll and O genes. The cll gene fragments are subject to additional hydrolytic events, and cll mRNA levels are several-fold lower in lambda + than in lambda po- infections late in the infection cycle. However, O mRNA levels are almost unaffected by the po- mutation.

The Escherichia coli heat shock response and bacteriophage λ development

Abstract: The Escherichia coli/bacteriophage lambda genetic interaction system has been used to uncover the existence of various biological machines. The starting point of all these studies was the isolation and characterization of E. coli mutants that blocked lambda growth, and the corresponding lambda compensatory mutations. In this manner, the lambda N-promoted transcriptional anti-termination machine was discovered composed of the NusA/NusB/NusE/NusG host proteins. In addition, the DnaK and GroEL chaperone machines were discovered composed of DnaK/DnaJ/GrpE and GroES/GroEL heat shock proteins. The individual members of the DnaK and GroEL chaperone machines have been conserved throughout evolution in both function and structure. Their biological roles include a direct involvement in lambda DNA replication and morphogenesis, the protection of proteins from aggregation, the disaggregation of various protein aggregates, the manipulation of protein structure and function, as well as the autoregulation of the heat shock response. The evolution of lambda to extensively rely on the status of the heat shock response of E. coli is likely linked to its lytic versus lysogenic choice of lifestyle. The bacteriophage T4 gp31 protein has been purified and shown to substitute for many of GroES' co-chaperonin activities.

Bacteriophage Lambda: a Paradigm Revisited

Abstract: Bacteriophage lambda has an archetypal immunity system, which prevents the superinfection of its Escherichia coli lysogens. It is now known that superinfection can occur with toxigenic lambda-like phages at a high frequency, and here we demonstrate that the superinfection of a lambda lysogen can lead to the acquisition of additional lambda genomes, which was confirmed by Southern hybridization and quantitative PCR. As many as eight integration events were observed but at a very low frequency (6.4 × 10−4) and always as multiple insertions at the established primary integration site in E. coli. Sequence analysis of the complete immunity region demonstrated that these multiply infected lysogens were not immunity mutants. In conclusion, although lambda superinfection immunity can be confounded, it is a rare event.

Expression of a cloned denV gene of bacteriophage T4 in Escherichia coli.

Abstract: A 713-base-pair Hae III fragment from bacteriophage T4 encompassing the denV gene with its preceding promoter has been cloned in a pBR322-derived positive-selection vector and introduced into a variety of DNA repair-deficient uvr and rec and uvr,rec Escherichia coli strains. The denV gene was found to be expressed, probably from its own promoter, causing pyrimidine dimer incision-deficient uvrA, uvrB, uvrC strains to be rescued by the denV gene. A uvrD (DNA helicase II) strain was also complemented, but to a lesser extent. A wild-type strain did not seem to be affected at the UV doses tested. Surprisingly, all recA, recB, and recC strains tested also showed an increased UV resistance, perhaps by reinforcement of the intact uvr system in these strains. Complementation of denV- T4 strains and host-cell reactivation of lambda phage was also observed in denV+ E. coli strains. Equilibrium sedimentation showed that DNA repair synthesis occurred in a UV-irradiated uvrA E. coli strain carrying the cloned denV gene. Southern blotting confirmed our earlier results [Valerie, K., Henderson, E. E. & de Riel, J. K. (1984) Nucleic Acids Res. 12, 8085-8096] that the denV gene is located at 64 kilobases on the T4 map. Phage T2 (denV-) did not hybridize to a denV-specific probe.