Biotin-transducing lambda phages with unusual att regions

Molecular analysis of the recombination junctions of lambda bio transducing phages

To examine the mechanism of recombination involved in the formation of specialized transducing phage during the induction of bacteriophage lambda, we have determined the nucleotide sequences of the recombination junctions of lambda bio phages. The results indicate that abnormal excision takes place at many sites on both bacterial and phage genomes and that the recombination sites have short regions of homology (5-14 bp). Some of the sequences of the recombination sites were similar to the consensus sequences of DNA gyrase-cleavage sites and repetitive extragenic palindromic (REP) sequences. These results showed that abnormal excision is a type of illegitimate recombination. The possible involvement of DNA gyrase in this recombination is discussed.

A comprehensive molecular map of bacteriophage lambda

Physical and genetic mapping of deletion mutations has been correlated with the available molecular sizes of the lambda gene products and the DNA base sequence to construct a comprehensive molecular map of the phage lambda genome. The physical length of the DNA making up the left arm from the cos site through gene J is not sufficient to account in a nonoverlapping manner for all the proteins of the sizes reported to be coded, especially in the Nu1--C region. In the right arm all the coding capacity has not been accounted for, and it appears to be oversaturated only in the gam-ral region. The positions of several IS and Tn elements, and of restriction endonuclease cleavage sites are specified.

Isolation and characterization of plaque-forming lambdadnaZ+ transducing bacteriophages

The Escherichia coli dnaZ gene, a deoxyribonucleic acid (DNA) polymerization gene, is located 1.2 min counterclockwise from purE, at approximately min 10.5 on the E. coli map. From a lysogen with lamdacI857 integrated at a secondary attachment site near purE, transducing phages (lambdadnaS+) that transduced a dnaZts (lambda+) recipient to temperature insensitivity (TS+) were discovered. Three different plaque-forming transducing phages were isolated from seven primary heterogenotes. Genetic tests and heteroduplex mapping were used to determine the length and position of E. coli DNA within the lambda DNA. Complementation tests demonstrated that the deletions in all three strains removed both att P and the int gene, i,e., DNA from both prophage ends. Heteroduplex mapping confirmed this result by demonstrating that all three strains had deletions of lambda DNA that covered the b2 to red region, thereby removing both prophage ends. Specifically, the deletions removed lambda DNA between the points 39.3 to 66.5% of lambda length (measured in percent length from the left and of lambda phage DNA) in all three strains. The three strains are distinct, however, because they had differing lengths of host DNA insertions. These phages must have been formed by an anomalous procedure, because standard lambda transducing phages are deleted for one prophage end only. In lambdagal and lambdabio strains, the deletions of lambda DNA begin at the union of prophage ends (i.e., position 57.3% of lambda length) and extend leftward or rightward, respectively (Davidson and Szybalski, in A, D. Hershey [ed.], The Bacteriophage Lambda, p. 45-82, 1971). Models for formation of the lambdadnaZ+ phages are discussed.