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.

Mutations allowing growth on maltose of Escherichia coli K12 strains with a deleted malT gene

Abstract: Previous work suggests that the malT gene exerts a positive control on two operons. One operon (malB lamB) codes for maltose permease and a protein involved in the biosynthesis of cell wall receptors for phage lambda. The other operon (malP malQ) codes for two enzymes of maltose metabolism.

Cloning, characterization, and functional expression in Escherichia coli of chaperonin (groESL) genes from the phototrophic sulfur bacterium Chromatium vinosum.

Abstract: A recombinant lambda phage which was able to propagate in groE mutants of Escherichia coli was isolated from a Chromatium vinosum genomic DNA library. A 4-kbp SalI DNA fragment, isolated from this phage and subcloned in plasmid vectors, carried the C. vinosum genes that allowed lambda growth in these mutants. Sequencing of this fragment indicated the presence of two open reading frames encoding polypeptides of 97 and 544 amino acids, respectively, which showed high similarity to the molecular chaperones GroES and GroEL, respectively, from several eubacteria and eukaryotic organelles. Expression of the cloned C. vinosum groESL genes in E. coli was greatly enhanced when the cells were transferred to growth temperatures that induce the heat shock response in this host. Coexpression in E. coli of C. vinosum groESL genes and the cloned ribulose bisphosphate carboxylase/oxygenase genes from different phototrophic bacteria resulted in an enhanced assembly of the latter enzymes. These results indicate that the cloned DNA fragment encodes C. vinosum chaperonins, which serve in the assembly process of oligomeric proteins. Phylogenic analysis indicates a close relationship between C. vinosum chaperonins and their homologs present in pathogenic species of the gamma subdivision of the eubacterial division Proteobacteria.

Enzymatic breakage of the cohesive end site of phage lambda DNA: terminase (ter) reaction.

Abstract: An in vitro system is described for measuring the endonucleolytic conversion of the phage lambda cohesive end sites in concatemeric DNA to the cohesive chromosomal ends of the mature molecule. This enzymic process, known as the ter reaction, is catalyzed by purified lambda A gene protein. The reaction is markedly stimulated by ATP, Mg2+, spermidine, and one or more uncharacterized factors present in extracts of uninfected Escherichia coli cells. In vitro, the ter reaction proceeds in the absence of proheads under conditions that are similar to those previously found necessary for the formation of a DNA-A gene protein intermediate for the initiation of packaging.

Regulated protein production using site-specific recombination

Abstract: In vivo regulation of protein production is achieved by rearranging DNA segments comprising a protein-producing gene (i.e., protein-encoding DNA as well as regulatory DNA to effect the expression of the protein-encoding DNA in the host), in response to a change in an environmental condition such as temperature. The rearrangement is synchronized and directional (irreversible) in members of the cell population, because it is catalyzed by a lambda phage site-specific recombination enzyme system that operates on a pair of lambda phage attachment sites to rapidly drive the rearrangement and to avoid the reverse reaction. The cells include means to produce the lambda enzyme system in response to the change in environmental condition. By engineering one of the attachment sites within the gene that produces the protein whose production is to be regulated (yielding two gene segments), the synchronized rearrangement operates to change the gene from one configuration to another. In only one of these configurations are the gene segments positioned and oriented for protein production. Specifically, the protein-producing configuration is: gene segment one-attachment site-gene segment two. The attachment site is exogeneous to the gene, i.e, it does not occur in that location naturally and is positioned there by engineering techniques. The regulated protein production is useful, e.g., in fermenting the desired product, by allowing cell growth to proceed in the absence of product formation. When the desired cell mass is achieved, product production is enabled by the rearrangement.