Transformation of Neurospora crassa with the trp-1 gene and the effect of host strain upon the fate of the transforming DNA

Summary Neurospora trp-1 ⁺ transformants, obtained by transforming a trp-1 inl strain with plasmid DNA containing the wild type trp1 ⁺ gene, were characterized by genetic and Southern blot analyses. The transforming trp-1 gene integrated at or near the resident site in all of the trp-1 ⁺ transformants obtained with circular DNA or DNA cut within the trp-1 coding region. The frequency of homologous integration decreased substantially when the donor DNA was cleaved outside the trp-1 coding region. The transformants were very stable mitotically and, in general, also showed meiotic stability. Analysis of trp-1 ⁺ transformants obtained with another recipient strain, trp-1 ⁺ ga-2 aro-9 inl, showed that homologous integration of donor DNA occurred in only 20% of the transformants, whether circular or linear DNA was used. Thus, the host strain employed for transformation appears to be a major factor in determining the fate of transforming DNA. Southern blot analysis of transformants showed that integration of the transforming DNA at the homologous site occurred by double crossover or gene conversion events rather than by insertion of the entire plasmid DNA. Multiple and apparently non functional integration events were observed in some transformants.     

The mcm2-1 mutation of yeast causes DNA damage with a RAD9 requirement for repair

The minichromosome maintenance mutation, mcm2-1, has been found to synthesize damaged DNA at 35°C. Growth at this temperature rendered the mutant strain more sensitive to killing by ultraviolet irradiation. DNA damage could also be detected by pulsed-field gel electrophoresis, where a higher fraction of the DNA loaded was retained in the inserts at the wells. During the exponential phase of growth at this temperature about 50% of the cells had large buds, with the nucleus at or near the neck of the bud in most cases. The incorporation of the rad9 deletion in the mcm2-1-carrying strain caused a reduction in the percentage of large-budded cells and a moderate loss of cell viability. The results are consistent with mcm2-1 causing DNA damage leading to the arrest of cells in the S/G₂ phase of the cell cycle, which was partially dependent on the RAD9 gene product.     

Cloning and mapping of CDC40, a Saccharomyces cerevisiae gene with a role in DNA repair

Summary The cdc40 mutation has been previously shown to be a heat-sensitive cell-division-cycle mutation. At the restrictive temperature, cdc40 cells arrest at the end of DNA replication, but retain sensitivity to hydroxyurea (Kassir and Simchen 1978). The mutation has also been shown to affect commitment to meiotic recombination and its realization. Here we show that mutant cells are extremely sensitive to Methyl-Methane Sulfonate (MMS) when the treatment is carried out at restrictive temperature. Incubation at 37 °C prior to, or after MMS treatment at 23 °C, does not result in lower survival. It is concluded that the CDC40 gene product has a role in DNA repair, possibly holding together or protecting the DNA during the early stages of repair.The CDC40 gene was cloned on a 2.65 kb DNA fragment. A 2 plasmid carrying the gene was integrated and mapped to chromosome IV, between trp4 and ade8, by the method of marker loss. Conventional tetrad analysis has shown cdc40 to map 1.7 cM from trp4.     

Isolation, characterization and chromosome localization of repetitive DNA sequences in bananas (Musa spp.)

Partial genomic DNA libraries were constructed in Musa acuminata and M. balbisiana and screened for clones carrying repeated sequences, and sequences carrying rDNA. Isolated clones were characterized in terms of copy number, genomic distribution in M. acuminata and M. balbisiana, and sequence similarity to known DNA sequences. Ribosomal RNA genes have been the most abundant sequences recovered. FISH with probes for DNA clones Radka1 and Radka7, which carry different fragments of Musa 26S rDNA, and Radka14, for which no homology with known DNA sequences has been found, resulted in clear signals at secondary constrictions. Only one clone carrying 5S rDNA, named Radka2, has been recovered. All remaining DNA clones exhibited more or less pronounced clustering at centromeric regions. The study revealed small differences in genomic distribution of repetitive DNA sequences between M. acuminata and M. balbisiana, the only exception being the 5S rDNA where the two Musa clones under study differed in the number of sites. All repetitive sequences were more abundant in M. acuminata whose genome is about 12% larger than that of M. balbisiana. While, for some sequences, the differences in copy number between the species were relatively small, for some of them, e.g. Radka5, the difference was almost thirty-fold. These observations suggest that repetitive DNA sequences contribute to the difference in genome size between both species, albeit to different extents. Isolation and characterization of new repetitive DNA sequences improves the knowledge of long-range organization of chromosomes in Musa. This revised version was published online in July 2006 with corrections to the Cover Date.     

DNA polymerase III is required for DNA repair in Saccharomyces cerevisiae

We have studied the role of DNA polymerase III, encoded in S. cerevisiae by the CDC2 gene, in the repair of yeast nuclear DNA. It was found that the repair of MMS-induced single-strand breaks is defective in the DNA polymerase III temperature-sensitive mutant cdc2-1 at the restrictive temperature (37 °C), but is not affected at the permissive temperature (23 °C). Under conditions where only a small number of lesions was introduced into DNA (80% survival), the repair of MMS-induced damage could also be observed in the mutant at the restrictive temperature, although with low efficiency. When the quantity of lesions increased (50% survival or less), the repair of single-strand breaks was blocked. At the same time we observed a high rate of reversion in the meth, his and trp loci of the cdc2-1 mutant under restrictive conditions. The results presented suggest that DNA polymerase III is involved in the repair of MMS-induced lesions in yeast DNA and that the cdc2-1 mutation affects the proofreading activity of this polymerase.     

Plasmid recovery from transformants and the isolation of chromosomal DNA segments improving plasmid replication in Neurospora crassa

Summary The efficient recovery of plasmid DNA from Neurospora crassa transformants is described. Lithium acetate-treated spores were transformed with plasmid DNA and grown in mass in liquid culture. The resulting mycelial growth was harvested and plasmid DNA was extracted and used to transform E. coli to ampicillin resistance. Although at low frequency, routine recovery of plasmid pSD3 which carries the Neurospora qa-2 ⁺ gene and pBR322 sequences has been demonstrated. About 10% of the recovered plasmids carried deletions and transformed Neurospora at a higher frequency. The liquid culture procedure was also used in attempts to isolate autonomously replicating sequences (ars). In order to select for a stable vector which contains an ars sequence, a clone bank containing a selectable marker (qa-2 ⁺) and Neurospora chromosomal BamHI fragments was constructed and used to transform Neurospora. Several plasmid isolates resulting from a screening of the clone bank showed an improvement in the efficiency of recovery from Neurospora transformants. The properties of one such isolated plasmid, pJP102, suggest that it may contain an ars sequence. Some potential applications of these results for cloning in Neurospora and other filamentous fungi are discussed.     

A DNA sequence in Saccharomyces exiguus is homologous with the HO gene of Saccharomyces cerevisiae

Summary The DNA of Saccharomyces exiguus was analyzed by Southern hybridization using cloned MATa, MAT, and HO genes of Saccharomyces cerevisiae as probes. It was shown that S. exiguus has a DNA sequence homologous with the HO gene of S. cerevisiae and that this DNA sequence is on a chromosome of about 940 kb of DNA in S. exiguus. However, there is no DNA sequence in S. exiguus that is homologous with the MAT genes of S. cerevisiae.     

Cloning and physical characterization of linked lysine genes (LYS4, LYS15) of Saccharomyces cerevisiae

Summary The plasmid pSC4 which carries a 7.8 kb yeast DNA insert at the BamHI site of the Vector YEp13, complemented simultaneously MO-59-13c lys4, LU75 1ys15 and LU32 lys4lys15 (double) mutations of Saccharomyces cerevisiae. The 1.9 kb BamHl-XbaI DNA insert of the subclone pS051 complemented the LU75 lys15 mutation. The 2.8 kb XhoI-XhoI DNA insert of the pS052 subclone, like pSC4, complemented all three mutations. The 1.9 kb BamHI-XbaI DNA and the 2.8 kb XhoI-XhoI DNA were 100 bp apart in the pSC4 DNA insert and exhibited no homology with each other upon Southern hybridization. The 1.9 kb BamHI-XbaI DNA insert exhibited homology with the pSC4 and pS051 DNA as well as the genomic DNA of MO-59-13c lys4, LU75 lys15, LU32 lys4lys15, and RC1 (LYS) when digested with appropriate restriction enzymes. The 2.8 kb Xhol-XhoI DNA insert exhibited homology with the pSC4 and pS052 DNA as well as MO-59-13c lys4, LU75 lys15, LU32 lys4lys15, and RC1 (LYS) genomic DNA, when digested with XhoI enzyme. The 2.8 kb DNA probe also hybridized with ply(A)⁺ RNA from RC1 and lys4 ^– transformant but not that from. MO-59-13c lys4 mutant.     

Genetic and physical interactions between Schizosaccharomyces pombe Mcl1 and Rad2, Dna2 and DNA polymerase α: evidence for a multifunctional role of Mcl1 in DNA replication and repair

Schizosaccharomyces pombe rad2 is involved in Okazaki fragments processing during lagging-strand DNA replication. Previous studies identified several slr mutants that are co-lethal with rad2 and sensitive to methyl methanesulfonate as single mutants. One of these mutants, slr3-1, is characterized here. Complementation and sequence analyses show that slr3-1 (mcl1-101) is allelic to mcl1⁺, which is required for chromosome replication, cohesion and segregation. mcl1-101 is temperature-sensitive for growth and is highly sensitive to DNA damage. mcl1 cells arrest with 2C DNA content and chromosomal DNA double-strand breaks accumulate at the restrictive temperature. Mcl1p, which belongs to the Ctf4p/SepBp family, interacts both genetically and physically with DNA polymerase . Mutations in rhp51 and dna2 enhance the growth defect of the mcl1-101 mutant. These results strongly suggest that Mcl1p is a functional homologue of Saccharomyces cerevisiae Ctf4p and plays a role in lagging-strand synthesis and Okazaki fragment processing, in addition to DNA repair.     

Transformation of the mycoparasite Gliocladium

Summary Gliocladium roseum and G. virens are saprophytic fungi with biological control activity against various plant pathogens, including those causing seedling diseases in cotton. Genetic transformation systems were developed to provide the potential for incorporating additional traits to improve the biocontrol efficacy of Gliocladium. Gliocladium roseum protoplasts were transformed with G. virens genomic DNA. The 6.7 kb plasmid pH1S containing a bacterial hygromycin B resistance gene, hygB, was used to transform G. virens. Up to ten methionine-independent G. roseum transformants were recovered per microgram of G. virens DNA. Transformation frequencies as high as 150 hygromycin B-resistant transformants per microgram of circular palsmid DNA were observed with electroporation at a field strength of 500 V/cm. Total DNA was isolated from G. virens transformants and hybridized to purified hygB or pBR322 (the vector used in the pH1S construct) DNA. The hygB DNA was integrated into genomic DNA. Precise excision of the plasmid by two different restriction endonucleases provided evidence for the presence of multiple tandem copies in some transformants. The presence of multiple bands in digests of other transformants suggested multiple sites of integration.     

Plastid DNA is not detectable in the male gametes and pollen tubes of an angiosperm (Antirrhinum majus) that is maternal for plastid inheritance

Summary Prior cytological observations using DAPI/epifluorescence microscopy have suggested that the method could be used to rapidly screen plant species for their potential mode of plastid DNA transmission. Cytoplasmic DAPI-DNA aggregates were observed in generative cells of germinated pollen of Medicago sativa (alfalfa), a species known genetically to display biparental transmission, but not in Antirrhinum majus (snapdragon), a species known to be maternal for plastid transmission. If, as suggested, these aggregates are plastid DNA nucleoids, then M. sativa pollen should contain plastid DNA detectable by molecular biology methods and A. majus pollen should not. Total DNA was isolated from germinated pollen and analyzed by Southern blot hybridization. A clone containing part of the rbcL gene from the garden pea plastome was used as a probe for plastid DNA. This probe hybridized with a restriction fragment from M. sativa pollen DNA, but not detectably with A. majus pollen DNA, thereby corroborating the identification of the cytoplasmic DAPI-DNA aggregates in M. sativa pollen as plastid DNA, and confirming the cytologically determined absence of plastic DNA in A. majus pollen.     

Comparison of Tetrahymena ARS sequence function in the yeasts Saccharomyces cerevisiae and Schizosaccharomyces pombe

Summary We have isolated several Tetrahymena thermophila chromosomal DNA fragments which function as autonomously replicating sequences (ARS) in the heterologous Saccharomyces cerevisiae and Schizosaccharomyces pombe selection systems. The Tetrahymena ARS sequences were first isolated in S. cerevisiae and were derived from non-ribosomal micro- and macronuclear DNA. Sequence analysis of the ARS elements identified either perfect or close matches with the 11 by S. cerevisiae ARS core consensus sequence. Subcloning studies of two Tetrahymena ARS elements defined functional regions ranging in size from 50 to 300 bp. Testing of the ARS elements in S. pombe revealed that most of the T. thermophila inserts confer ARS function in both yeasts, at least in the sense of promoting a high transformation frequency to plasmids which contain them. However, the actual sequences responsible for ARS activity were not always identical in the two yeasts.     

Integrative transformation of the yeast Yarrowia lipolytica

Summary An EcoR1 shotgun of Yarrowia lipolytica DNA was inserted into the plasmid YIp333 which carries the LYS2 gene of S. cerevisiae. The resulting plasmid pool was transformed in both S. cerevisiae and Y. lipolytica. Whereas numerous replicating plasmids could be isolated from the S. cerevisiae Lys⁺ transformants, all transformants of Y. lipolytica so far analyzed were found to result from integrative transformation. This occurred at a frequency of 1 to 10 transformants per g of input DNA. Co-transformation occurred at high frequency and resulted in tandem integration of 2 to 10 copies of the incoming DNA. Structural and segregational stability of the transforming DNA were both high.     

Characterization of AcMNPV with a deletion of me53 gene

The Autographa Californica multiple nucleopolyhedrovirus (AcMNPV) me53 gene, which was previously reported as one of the major early-transcribed genes, was deleted through homologous recombination from an AcMNPV genome propagated as a bacmid DNA in E. coli, generating a me53 gene knockout bacmid. Green fluorescent protein (GFP) expression analysis and supernatant passage assay revealed that the me53 knockout bacmid was unable to replicate in cell culture, while me53 repair bacmid, which was generated by reinsertion of the me53 gene into the mutant at a different locus (the gentamicin locus) with ET-recombination technique, resumed viral replication ability at wild-type levels, indicating that the defective phenotype of the me53 knockout virus was directly due to the deletion of the me53-ORF. Subsequent electron microscopy revealed that the me53 knockout bacmid failed to form nucleocapsid in the nuclei of the transfected cells, though viral infection seemed to be initiated. Meanwhile, real-time PCR analysis based on SYBR Green fluorescence indicated abolishment of the viral DNA replication by me53 gene inactivation. Thus, it is demonstrated for the first time that me53 knockout blocked viral DNA replication, nucleocapsid formation, and consequent BV and ODV production.     

Exposure of cdc8 homozygous diploids of Saccharomyces cerevisiae to nonpermissive temperature leads to an increase in mitotic conversion frequencies

Summary In a diploid strain homozygous for the cdc8-1 mutation, a block in DNA synthesis caused by restrictive temperature resulted in a significant increase in the frequency of intragenic recombination at the HOM2 locus. Under restrictive conditions, incorporation of radioactivity into DNA was reduced to 2% of the control and alkaline sucrose gradient centrifugation revealed that only short DNA fragments were synthesized. There was no considerable fragmentation of template DNA during incubation of cdc8-1 strains under restrictive conditions.     

Transformation of Aspergillus giganteus to hygromycin B resistance

Summary A wild strain of A. giganteus was transformed to hygromycin B resistance using a bacterial resistance gene under the control of A. nidulans sequences. Stable transformants arose by heterogenous integration, mainly of tandem repeats of vector DNA at various sites in the host genome. Between 6 and 30 resistant colonies were obtained per g DNA per 3×10³ viable protoplasts. Vector DNA could be recovered by transformation of Escherichia coli with undigested genomic DNA from Aspergillus giganteus transformants.     

FISH to mitotic chromosomes and extended DNA fibres of Beta procumbens in a series of monosomic additions to beet (B. vulgaris)

The physical localization and organization of a Procumbentes-specific repetitive DNA sequence, PB6-4, on the chromosomes of Beta procumbens (2n=18) were studied, using FISH (fluorescence in situ hybridization) to mitotic chromosomes and extended DNA fibres. The chromosomes of B. procumbens were studied in metaphase complements of the species itself, as well as in preparations of a series of eight different B. procumbens-derived monosomic additions to B. vulgaris (2n=18). FISH to chromosome spreads of B. procumbens revealed that PB6-4 hybridizes to all chromosomes, predominantly in the pericentromeric regions, but with differences in size and brightness of the signals. Hybridization of PB6-4 to metaphase complements of B. vulgaris revealed no signals, indicating that cross-hybridization with the genome of this species was negligible. Consequently, hybridization of PB6-4 to metaphase complements of the monosomic additions yielded fluorescent signals on the alien chromosomes only. The previously observed differences in size and brightness of the fluorescent spots were confirmed using the single alien chromosomes. FISH of PB6-4 to extended DNA fibres of the monosomic additions indicated differences in the fluorescent track lengths between the alien chromosomes. Measurements of the fluorescent tracts allowed classification into discrete groups, varying from one to three groups per B. procumbens chromosome. The data revealed that the brightness or size of the signal at mitotic metaphase and the length of the fluorescent tracks on the DNA fibres were correlated. This revised version was published online in July 2006 with corrections to the Cover Date.     

How heterologously expressed <Emphasis Type="Italic">Escherichia coli</Emphasis> genes contribute to understanding DNA repair processes in <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

DNA-damaging agents constantly challenge cellular DNA; and efficient DNA repair is therefore essential to maintain genome stability and cell viability. Several DNA repair mechanisms have evolved and these have been shown to be highly conserved from bacteria to man. DNA repair studies were originally initiated in very simple organisms such as Escherichia coli and Saccharomyces cerevisiae, bacteria being the best understood organism to date. As a consequence, bacterial DNA repair genes encoding proteins with well characterized functions have been transferred into higher organisms in order to increase repair capacity, or to complement repair defects, in heterologous cells. While indicating the contribution of these repair functions to protection against the genotoxic effects of DNA-damaging agents, heterologous expression studies also highlighted the role of the DNA lesions that are substrates for such processes. In addition, bacterial DNA repair-like functions could be identified in higher organisms using this approach. We heterologously expressed three well characterized E. coli repair genes in S. cerevisiae cells of different genetic backgrounds: (1) the ada gene encoding O⁶-methylguanine DNA-methyltransferase, a protein involved in the repair of alkylation damage to DNA, (2) the recA gene encoding the main recombinase in E. coli and (3) the nth gene, the product of which (endonuclease III) is responsible for the repair of oxidative base damage. Here, we summarize our results and indicate the possible implications they have for a better understanding of particular DNA repair processes in S. cerevisiae.     

Studies on homologous recombination in the green alga Chlamydomonas reinhardtii

The introduction of exogenous DNA into the nuclear genome of Chlamydomonas reinhardtii occurs predominantly via non-homologous (illegitimate) recombination and results in integration at apparently-random loci. Using truncated and modified versions of the C. reinhardtii ARG7 gene in a series of transformation experiments, we demonstrate that homologous recombination between introduced DNA molecules occurs readily in C. reinhardtii, requires a region of homology of no more than 230 bp, and gives rise to intact copies of ARG7 in the nuclear genome. Evidence is presented for homologous recombination between introduced ARG7 DNA and the resident copy of the gene, and for the de-novo synthesis of the ARG7 sequence during transformation.     

Transformation ofNeurospora crassa with circular and linear DNA and analysis of the fate of the transforming DNA

Summary We have conducted a detailed study of 108qa-2 ⁺ Neurospora transformants which were obtained by use of circular plasmid DNAs and various linear DNAs. Parallel genetic and molecular analyses have revealed that three classes of transformants can be identified: linked transformants, in which theqa-2 gene has integrated at the resident locus, unlinked transformants, where integration has occurred at other genomic sites, and a third class designated non-transmissible which fail to pass theqa-2 gene through a cross. The non-transmissible class comprises the majority of transformants and may identify those which harbor autonomously replicating plasmids. Evidence is presented which suggests that a 1.2 kB BamHI-Bg1IIqa-2 ⁺ DNA fragment might possess anars sequence. Transformation with linear plasmid DNAs and DNA fragments carrying theqa-2 gene resulted in a demonstrable increase in transformation frequency beyond that achieved with circular plasmid DNAs, but did not permit precise targeting to the resident locus. Southern analysis showed that linked transformants have only the normal residentqa-2 band whereas the unlinked transformants always possess the resident band plus at least one additional band. Multiple integration events appear to be common and include cases where only a portion of the transforming DNA has been integrated.