Gene conversion associated with site-specific recombination in yeast plasmid pSR1

The transposition pattern of the Ac element in tobacco cultured cells

We investigated physical distances and directions of transposition of the maize transposable element Ac in tobacco cultured cells. We introduced a T-DNA construct that carried a non-autonomous derivative of Ac (designated dAc-I-RS) that included sites for cleavage by restriction endonuclease MluI. Another cleavage site was also introduced into the T-DNA region outside of the dAc-I-RS transposable element. The tobacco cultured cell line BY-2 was transformed with the T-DNA and several transformed lines that had a single copy of the T-DNA at a different chromosomal location were isolated. These lines were co-cultured with Agrobacterium tumefaciens cells that carried a cDNA for the Ac transposase gene under the control of various promoters. Sublines of cultured cells in which dAc-I-RS had been transposed, were isolated. The genomic DNAs of these sublines were isolated and digested with MluI. Sizes of DNA segments generated by digestion were determined by pulse-field gel electrophoresis. Our results showed that 20 to 70% of transposition events had occurred within several hundreds kilo-base pairs (kb) on the same chromosome. These results demonstrate that the Ac-Ds element preferentially transposed to regions near the original site in a tobacco chromosome. In addition, the present results are an example of asymmetric transposition as demonstrated by the distance of transposition on the chromosome.

Genomic exploration of the hemiascomycetous yeasts: 8. Zygosaccharomyces rouxii

This paper reports the genomic analysis of strain CBS732 of Zygosaccharomyces rouxii, a homothallic diploid yeast. We explored the sequences of 4934 random sequencing tags of about 1 kb in size and compared them to the Saccharomyces cerevisiae gene products. Approximately 2250 nuclear genes, 57 tRNAs, the rDNA locus, the endogenous pSR1 plasmid and 15 mitochondrial genes were identified. According to 18S and 25S rRNA cladograms and to synteny analysis, Z. rouxii could be placed among the S. cerevisiae sensu lato yeasts.

The Kw recombinase, an integrase from Kluyveromyces waltii

Site-specific recombinases of the integrase family share limited amino-acid-sequence similarity, but use a common reaction mechanism to recombine distinct DNA target sites. Here we report the characterisation of the Kw site-specific recombinase, encoded on the 2 mu-like plasmid pKWS1 from the yeast Kluyveromyces waltii. Using in vitro-translated Kw recombinase, we show that the protein is able to bind and to recombine its putative DNA target site. Recombination is conservative and the Kw target site has a spacer of seven base pairs. We show that Kw recombinase is able to mediate recombination in a mammalian cell line, thus, it has potential for use as a tool for genomic manipulation in heterologous systems.

Visualization of site-specific recombination catalyzed by a recombinase from Zygosaccharomyces rouxii in Arabidopsis thaliana

Excision of a DNA segment can occur in Arabidopsis thaliana by reciprocal recombination between two specific recombination sites (RSs) when the recombinase gene (R) from Zygosaccharomyces rouxii is expressed in the plant. To monitor recombination events, we generated several lines of transgenic Arabidopsis plants that carried a cryptic beta-glucuronidase (GUS) reporter gene which was designed in such a way that expression of the reporter gene could be induced by R gene-mediated recombination. We also made several transgenic lines with an R gene linked to the 35S promoter of cauliflower mosaic virus. Each transgenic line carrying the cryptic reporter gene was crossed with each line carrying the R gene. Activity of GUS in F1 and F2 progeny was examined histochemically and recombination between two RSs was analyzed by Southern blotting and the polymerase chain reaction. In seedlings and plantlets of F1 progeny and most of the F2 progeny, a variety of patterns of activity of GUS, including sectorial chimerism in leaves, was observed. A small percentage of F2 individuals exhibited GUS activity in the entire plant. This pattern of expression was ascribed to germinal recombination in the F1 generation on the basis of an analysis of DNA structure by Southern blotting. These results indicate that R gene-mediated recombination can be induced in both somatic and germ cells of A. thaliana by cross-pollination of parental transgenic lines.

A site-directed chromosomal translocation induced in embryonic stem cells by Cre-loxP recombination

We have developed a strategy for chromosome engineering in embryonic stem (ES) cells that relies on sequential gene targeting and Cre-loxP site-specific recombination. Gene targeting was first used to integrate loxP sites at the desired positions in the genome. Transient expression of Cre recombinase was then used to mediate the chromosomal rearrangement. A genetic selection relying on reconstruction of a selectable marker from sequences co-integrated with the loxP sites allowed detection of cells containing the Cre-mediated rearrangement. A programmed translocation between the c-myc and immunoglobulin heavy chain genes on chromosomes 15 and 12 was created by this method. This strategy will allow the design of a variety of chromosome rearrangements that can be selected and verified in ES cells or activated in ES cell-derived mice.

A specific host factor binds at a cis-acting transcriptionally silent locus required for stability control of yeast plasmid pSR1

A cis-acting locus, Z, of plasmid pSR1 functions in stable maintenance of the plasmid in the native host, Zygosaccharomyces rouxii. The Z locus was shown to be located in a 482 bp sequence in the 5' upstream region of an open reading frame, P, by subcloning various DNA fragments in a plasmid replicating via the ARS1 sequence of the Saccharomyces cerevisiae chromosome. Northern analysis revealed that the Z region is not transcribed in either the native host Z. rouxii or the heterologous host S. cerevisiae. The Z region is protected from micrococcal nuclease attack in Z. rouxii but not in S. cerevisiae, its protection depending on the product of the S gene encoded by pSR1. Gel retardation assays suggested that a factor present in nuclear extracts of Z. rouxii cells, irrespective of the presence or absence of a resident pSR1 plasmid, binds to a 111 bp RsaI-SacII sequence in the Z region. These findings suggest that a host protein binds to the Z locus and that the S product interacts with this DNA-protein complex and stabilizes pSR1.

Automatic elimination of unnecessary bacterial sequences from yeast vectors

Most vectors for Saccharomyces cerevisiae are shuttle vectors which can be both propagated and selected in Escherichia coli. The DNA segments, however, which are required for propagation in E. coli are unnecessary and moreover toxic in S. cerevisiae. To delete these harmful DNA fragments from the vector after it is introduced into S. cerevisiae cells, we propose a specific gene conversion mechanism of a yeast plasmid, pSR1. Plasmid pSR1 has a pair of inverted repeats (IRs) that divides the plasmid molecule into two unique regions. Intramolecular recombination frequently occurs at a pair of specific recombination sites in IRs catalyzed by recombinase R, encoded by a pSR1 plasmid gene. This R-mediated recombination is often accompanied by gene conversion in IRs. Thus, a 2.1-kb pBR322 sequence for the E. coli host ligated into one of the IRs of a composite plasmid was automatically and effectively eliminated when the plasmid was introduced into S. cerevisiae cells.

Site-specific recombinase, R, encoded by yeast plasmid pSR1

The R gene product (R protein) of Zygosaccharomyces rouxii plasmid pSR1 catalyzes site-specific recombination within a 58 base-pair (bp) sequence present in the 959 bp inverted repeats of this plasmid. The R protein was produced in Escherichia coli and partially purified. The partially purified protein catalyzed site-specific recombination in vitro without the supply of an energy source. Recombination resulted in intramolecular inversion or deletion, depending on whether the orientations of the two recombination sites on the substrate plasmid were the same or opposite. Presumably, R protein is the only protein required for the recombination reaction. A circular DNA molecule appears to be a better substrate than a linear molecule in R-mediated in vitro intramolecular recombination. The R protein binds to a set of six 12 bp elements within the inverted repeats of pSR1. Two of these 12 bp elements are arranged in an inverted configuration with a 7 bp spacer in the 58 bp sequence. The R protein mediates strand cleavage in vitro at the junction between the 12 bp elements and the 7 bp spacer. The cleavage sites on the top and bottom strands are staggered and flanked by polypurine tracts that form part of the 12 bp elements.

Mutations in a Saccharomyces cerevisiae host showing increased holding stability of the heterologous plasmid pSR1

We have isolated Saccharomyces cerevisiae mutants, smp, showing stable maintenance of plasmid pSR1, a Zygosaccharomyces rouxii plasmid. The smp mutants were recessive and were classified into at least three different complementation groups. The three mutants also showed increased stability of YRp plasmids and the mutations are additive for plasmid stability. One mutation, smp1, confers a respiration-deficient (rho0) phenotype and several Rho- mutants independently isolated by ethidium bromide treatment of the same yeast strain also showed increased stabilities of pSR1 and YRp plasmids. The wild-type S. cerevisiae cells showed a strongly biased distribution of pSR1 molecules as well as YRp plasmids to the mother cells at mitosis, while the smp1 mutant did not show this bias. Another mutation, smp3, at a locus linked to ade2 on chromosome XV, confers temperature-sensitive growth. The SMP3 gene encodes a 59.9 kDa hydrophobic protein and disruption of the gene is lethal.

An autonomously replicating sequence of pSRI plasmid is effective in two yeast species, Zygosaccharomyces rouxii and Saccharomyces cerevisiae

The autonomously replicating sequences (ARSs) of pSR1, a cryptic circular DNA plasmid detected in a strain of Zygosaccharomyces rouxii, were delimited by subcloning and deletion analysis and by the isolation of nucleotide substitution mutations. A 30 base-pair (bp) sequence from inverted repeat 1 (IR1) and presumably the same region from IR2 of pSR1 functions as an ARS in the native host, Z. rouxii, and in a heterologous host, Saccharomyces cerevisiae. Thus, pSR1 has two ARSs per molecule, either of which is sufficient for replication of the plasmid molecule in both hosts. These hosts, however, respond differently to nucleotide substitutions in the 30 bp sequence, suggesting that the sequences required for ARS function in the two organisms are not exactly the same. In addition, a 137 bp sequence that overlaps the 30 bp sequence by 11 bp also functions as an ARS in Z. rouxii but not in S. cerevisiae. However, this 137 bp sequence enhances the stability of plasmids carrying the pSR1 ARS in S. cerevisiae. The 30 bp and 137 bp sequences each contain a single copy of the 11 bp ARS consensus sequence, which is essential for ARS function in S. cerevisiae. Small insertions between the 11 bp overlapping region and the 11 bp ARS consensus sequence showed that a proper distance between these two 11 bp sequences is essential for the ARS function of the 30 bp sequence. Point mutations that inactivate ARS function show that the ARS consensus sequence, as well as a short A:T segment in the overlapping sequence, is required for the ARS function of the 30 bp sequence.

Interactions between the termini of adeno-associated virus DNA

The adeno-associated virus (AAV) genome is a linear, single polynucleotide chain with inverted terminal repeats of 145 bases. In order to test whether the terminal repeats at opposite ends of the genome have to be able to completely base-pair during DNA replication, we have created chimeric genomes in which an 11 base symmetrical sequence has been deleted from the terminal repeat at one end of the genome and replaced by a different 12 base symmetrical sequence. We have used these chimeric constructs either as a duplex insert in pBR322 or as purified duplex virion DNA to transfect adenovirus-infected HeLa cells. When chimeric duplex virion DNA was used, all of the progeny virions obtained after two cell passages contained DNA with wild-type sequences in both terminal repeats. When plasmid clones were used, the structure of virion DNA depended on the original orientation. If the mutant terminal repeat was originally at the right end of the genome (terminus of genetic map), all progeny terminal repeat sequences were again wild-type. However, if the original construct contained the mutant sequence in the left terminal repeat, the majority of progeny molecules were parental in type (i.e. mutant left and wild-type right terminal repeat). We conclude (1) although the terminal repeats at opposite ends of the genome may interact during DNA replication, it is not necessary that they be perfectly complementary. (2) In direct competition, the wild-type sequence displays an advantage over the mutant allele. (3) In a plasmid clone, the terminal repeat on the left end of the genome is at an advantage in a competitive situation. We note that the left terminal repeat is adjacent to a transcriptional promoter.