Red-mediated recombination of phage lambda in a recA? recB?host

Summary The lambda Red recombination system works poorly among unreplicated gam ⁺ lambda chromosomes in recA ^- cells compared to recA ⁺ cells. Recombination is not enhanced in recA ^- recB^-cells. Thus, the inability of Red to promote recombination in recA ^- replication-blocked cross is not due to the hypothetical destruction of recombination intermediates by the recB nuclease. This conclusion strengthens previous proposals that the products of the red genes can operate upon recombinational intermediates which require recA activity for their formation.     

Analysis of Aspergillus niger transformants for single site integration and vector recombination

Summary In order to understand the mechanism of integrative transformation, bulk DNA from several transformants of Aspergillus niger was assaved for the presence of the heterologous vector p3SR2. In all cases vector sequences and recombinant vector fragments were found. Transformant T31-6 containing seven plasmid-probed bands was studied in detail. Recloning of six of these plasmids in Escherichia coli revealed that internal recombination events had produced deletions and insertions. Only one plasmid was isolated among 402 analysed clones that had involved A. niger DNA. Sequence analysis revealed that the integration of vector p3SR2 occurred via its A. nidulans amdS ⁺ sequence. These data support the assumption that the integration of multiple copies of p3SR2 occurred at a single genomic site.Offprint requests to: K. Esser     

Formation of concatemers of lambda phage DNA in a recombination-deficient system

Summary Concatenand molecules of lambda DNA were formed even in a recombination dificient system (Int^-Red^-Rec^-) in the late stage of phage growth. No significant difference was observed in the formation of concatemers between recombination deficient and proficient systems. These results suggest that concatemer formation is an intrinsic nature of replication in the late stage. The possibility of concatemer formation by molecular exchanges which do not contribute genetic recombination is not excluded.This paper is the sixth of a series Replication of bacteriophage DNA the fourth and fifth of which are J. Tomizawa, and Y. Sakakibara and J. Tomizawa in Bacteriophage lambda ed. A. D. Hershey, Cold Spring Harbor, N. Y. in press.     

Mapping ethanol-induced deletions

Summary Chromosomal rearrangements, uniformly represented by very large deletions, were stimulated upon transiently exposing Escherichia coli cells with a defective lambda prophage to about 18% (v/v) ethanol. It was shown that the ethanol treatment induced deletion formation rather than enriching for ethanol-tolerant cells. The deletions in 435 mutants were mapped to 26 groups. Ethanol treatment changed the spectrum of deletions relative to those arising spontaneously, and stimulated the formation of deletions with endpoints in E. coli DNA flanking the lambda fragment. The promotion of deletion formation by ethanol involves the joining of distant, nonhomologous linear DNA segments, which can be considered an illegitimate recombination event; however, activity of the E. coli recA gene product was also required. Although spontaneous deletions arose in comparable cells defective for recA, the incidence of deletion formation in recA cells was not altered by ethanol. It is proposed that ethanol stimulates chromosomal rearrangements involving two oppositely oriented replication forks, since the localized deletions commonly removed or inactivated the chromosomal segment including the bidirectional lambda origin of replication. The results imply a novel mutagenic process induced by an agent that does not act directly on DNA.     

Transposition of IS1-lambdaBIO-IS1 from a bacteriophage lambda derivative carrying the IS1-cat-IS1 transposon (Tn9)

Summary Tn9 is a transposable element in which a gene (cat) determining chloramphenicol resistance is flanked by directly repeated sequences that are homologous to the insertion sequence IS1. We show here that infection of Escherichia coli K12 (under Rec^- Red^- Int^- conditions) with a bio transducing phage carrying Tn9 results in the formation of bio transductants as frequently as cat transductants (about 1 per 10⁶ to 10⁷ infected cells). Most of the bio transductants do not carry cat, just as most of the cat transductants do not carry bio. In spite of the absence of cat, the bio prophage can transpose a second time, from the E. coli chromosome to different sites on an F gal plasmid. Analysis of the structure of the transposed bio element, by restriction nuclease digestion and by electron microscopy, demonstrates that the integrated bio prophage is flanked by directly repeated IS1 elements. We conclude that there is no genetic information for the ability to transpose encoded in the non-repeated portion of Tn9, i.e. that the directly repeated IS1 elements alone are responsible for Tn9 transposition.     

Recombination of a eukaryotic DNA in bacteria

Single, 824 bp repeating units of Xenopus laevis oocyte-type 5S DNA were inserted into the recombination vectors, λrva and λrvb. When the inserts had the same orientation with respect to the λ chromosomes, Spi^-imm434 recombinants were recovered by selection on a P2, λ double lysogenic host. Because of the structure of the vectors, the crossover point in each recombinant must lie completely within the 5S DNA insert. The physical characteristics of these recombinants were determined by examination of restriction enzyme digests. By use of RecA mutant hosts and the Red^- vector, λrvc, recombination frequencies were measured separately for the bacterial and phage systems.Some of the recombination events resulted in 5S DNA inserts of altered length due to unequal crossovers within repeated sequences in the 5S DNA spacer. The occurrence of just such events in frog 5S DNA had been predicted, based on the structure of 5S DNA and evolutionary considerations.     

Relationship of vector insert size to homologous integration during transformation of Neurospora crassa with the cloned am (GDH) gene

Summary We used lambda and plasmid vectors containing the am ⁺ gene in an insert of from 2.7 to 9.1 kb, to transform am point mutant and deletion strains. A total of 199 transformants were examined with the potential to yield am ^– transformants by homologous recombination. When we used vectors that had 9.1 kb of homology with the chromosomal DNA, 30% of the transformants obtained were the result of homologous recombination regardless of whether the vector was a lambda molecule, a circular plasmid, or a plasmid that had been linearized prior to transformation. When vectors with up to 5.1 kb of homology were used, very few transformants (1 of 89 tested) resulted from homologous recombination. Of a sample of 29 ectopic integration events obtained by transformation with the 9.1 kb fragment cloned in a vector, 18 included a major part (usually almost all) of both arms of lambda with the entire Neurospora 9.1 kb insert between them. Four included only long arm sequence together with an adjacent segment of the insert containing the am gene. The remaining seven were the result of multiple integrations. There was no evidence of circularization of the vector prior to integration. All transformants that had multiple copies of the am gene appeared to be subject to the RIP process, which causes multiple mutations in duplicated sequences during the sexual cycle.     

RecET driven chromosomal gene targeting to generate a RecA deficient Escherichia coli strain for Cre mediated production of minicircle DNA

Background  

Minicircle DNA is the non-replicating product of intramolecular site-specific recombination within a bacterial minicircle producer plasmid. Minicircle DNA can be engineered to contain predominantly human sequences which have a low content of CpG dinucleotides and thus reduced immunotoxicity for humans, whilst the immunogenic bacterial origin and antibiotic resistance marker gene sequences are entirely removed by site-specific recombination. This property makes minicircle DNA an excellent vector for non-viral gene therapy. Large-scale production of minicircle DNA requires a bacterial strain expressing tightly controlled site-specific recombinase, such as Cre recombinase. As recombinant plasmids tend to be more stable in RecA-deficient strains, we aimed to construct a recA ^- bacterial strain for generation of minicircle vector DNA with less chance of unwanted deletions.     

Mapping of gal minus-mutants by transducing lambda dg carrying deletions of the gal-region

Summary To map numerousgal ^--mutants ofE. coli, advantage is taken of the fact that transducing dg's can carry different amounts of bacterial DNA of the host from which they originated (Adler andTempleton, 1963).A method is described with which a large number of transducing dg can be easily isolated, differing from each other with respect to the amount of bacterial DNA of thegal-region. By observing whethergal ⁺-colonies can arise as the result of recombination betweengal ^--mutants and dg's carrying deletions in thegal-region, so far 104 kinaseless mutants and 96 transferaseless mutants could be ordered into 26 groups. The mapping-tests were done by spotting the mutants with 52 HFT-lysates of dg's lacking more or less of the kinase- or the kinase- and transferase gene.     

Synthesis of Fragments of the Peptide Component of Pseudobactin

Pseudobactin is a structurally complex and physiologically important siderophore (microbial iron chelator) from Pseudomonas putida- fluorescens. Various fragments of the unusual peptide component of pseudobactin listed below were prepared by solution-phase peptide synthesis. L -Lys· D -threo-β-OH Asp· L -Ala· D -allo-Thr· L -Ala L -Lys· D -threo-βOH Asp· L -Ala· D -allo-Thr D -threo-β-OH Asp· L -Ala· D - allo-Thr· L -Ala· D -N-OH-cycloOrn D -threo-β-OH-Asp· L -Ala· D -allo-Thr· L -Ala L -Ala· D -allo-Thr· L - Ala· D -N-OH-cycloOrn A class of related peptides named pseudomycins have shown promising antifungal activity. To examine if these peptide fragments above would elicit similar activity, the fragments were tested and found to have no antifungal activity in limited bioassays.