Characterization of deletion derivatives of an autonomously replicating Neurospora plasmid

Efficient sequential repetitive gene deletions in Neurospora crassa employing a self-excising β-recombinase/six cassette

Despite its long-standing history as a model organism, Neurospora crassa has limited tools for repetitive gene deletions utilizing recyclable self-excising marker systems. Here we describe, for the first time, the functionality of a bacterial recombination system employing β-recombinase acting on six recognition sequences (β-rec/six) in N. crassa, which allowed repetitive site-specific gene deletion and marker recycling. We report generating the mus-51 deletion strain using this system, recycling the marker cassette, and subsequently deleting the global transcriptional regulator gene cre-1.

Efficient cloning of genes of Neurospora crassa

We have constructed a genomic library of Neurospora crassa DNA in a cosmid vector that contains the dominant selectable marker for benomyl resistance. The library is arranged to permit the rapid cloning of Neurospora genes by either sib-selection or colony-hybridization protocols. Detailed procedures for the uses of the library are described. By use of these procedures, a modest number of unrelated genes have been isolated. The cloning of trp-3, the structural gene for the multifunctional enzyme tryptophan synthetase (tryptophan synthase, EC 4.2.1.20), is reported in detail; its identity was verified by restriction fragment length polymorphism mapping. The strategies described in this paper should be of use in the cloning of any gene of Neurospora, as well as genes of other lower eukaryotes.

Homologous transformation of the edible basidiomycete Agrocybe aegerita with the URA1 gene: characterization of integrative events and of rearranged free plasmids in transformants

The URA1 gene, encoding dihydroorotate dehydrogenase of the pyrimidine pathway, cloned into pUC18 (pUra1-1) was used to develop an homologous transformation system for the cultivated mushroom Agrocybe aegerita. Protoplasts of a ura1 auxotrophic strain were transformed by electroporation with efficiencies ranging from 1 to 26 transformants per micrograms of DNA. The phenotype of the stable Ura+ transformants suggested a strong nuclear heterogeneity further confirmed by Southern-blot analysis. All transformants acquired extrachromosomal forms derived from pUra1-1. Integration of pUra1-1 into chromosomal DNA occurred for some transformants. Plasmids containing the integrant of pUC18 recombined to different parts of the URA1 gene were rescued from A. aegerita transformants through transformation of E. coli. Their molecular analysis indicated that they represent products of the continuous excision of primary-integrated vector sequences rather than ARS-dependent autoreplicative forms.

Restoration of pathogenicity of a penetration-deficient mutant of Collectotrichum lagenarium by DNA complementation

Infection by Colletotrichum lagenarium requires formation of an appressorium and of a penetration peg. A mutant, 83,348, defective in morphogenesis of the penetration peg was unable to penetrate into cellulose membranes or infect cucumber leaves. DNA transformation using a wild-type genomic library constructed in pKVB resulted in two transformants, Ppr1 and Ppr2, with restored penetration peg formation, from 2,000 benomyl-resistant transformants. However, penetration into cellulose membranes by these transformants ranged from 30 to 40% compared to greater than 90% by wild-type. Southern-blot hybridization showed that a single copy of a cosmid clone had integrated into the genome of the transformants. A 12.0-kbp fragment of the cosmid vector with the flanking region of wild-type genomic DNA was recovered by plasmid rescue from Ppr1. Using the flanking DNA sequences as a probe for colony blot hybridization, a genomic clone was identified and designated pRP46. Transformants obtained following transformation with pRP46 were able to penetrate cellulose membranes. The penetration frequency of pRP46 transformants ranged from 25 to 65%. Transformants were also pathogenic on cucumber.

The nature of extra-chromosomal maintenance of transforming plasmids in the filamentous basidiomycete Phanerochaete chrysosporium

The nature of extra-chromosomal maintenance of the transforming plasmid p12-6 in Phanerochaete chrysosporium was studied. Our results indicate that the plasmid is maintained in the fungal transformants extra-chromosomally as part of a larger endogenous plasmid (designated pME) of P. chrysosporium. Using the total DNA of p12-6 fungal transformants, p12-6, as well as a larger plasmid, p511, were recovered in recA- E. coli strains while only p12-6 was recovered in recA+ E. coli strains. The results also showed that the cytosine methylation system has no apparent effect on the strain-dependent recovery of p12-6 and p511 in E. coli from the total DNA of fungal transformants.

Molecular and genetic analysis of URA5 transformants of Cryptococcus neoformans

Cryptococcus neoformans var. neoformans ura5 mutants were transformed with linearized or circular plasmids containing the C. neoformans orotidine monophosphate pyrophosphorylase gene. Following electroporation, randomly isolated transformants were analyzed for the mitotic and meiotic stability of uracil prototrophy. All stable transformants tested showed nonspecific ectopic integration. Uracil prototrophy in these transformants was stable through meiosis. Some of the stable transformants showed integration of both URA5 and vector sequences, while others lacked any vector sequences. Unstable transformants exhibited the presence of an autonomously replicating plasmid which had undergone significant sequence rearrangement. The autonomously replicating plasmid in the transformants was observed to be the same size or smaller than the transforming plasmid, was maintained in a linear form, and had acquired a genomic sequence(s) with homology to a sequence(s) on all the chromosomes. The conservation of a 300-bp sequence at the 5' end of the URA5 gene was observed in all the rearranged plasmids. These results suggest mechanisms of plasmid maintenance in C. neoformans that are different from those reported for other yeasts. The ura5 mutant was significantly less virulent than the wild type. The transformants did not recover virulence regardless of prototrophic stability.

The LaBelle mitochondrial plasmid of Neurospora intermedia encodes a novel DNA polymerase that may be derived from a reverse transcriptase

The LaBelle-1b strain of Neurospora intermedia contains a 4.1-kb closed-circular mitochondrial plasmid DNA, which encodes a single long open reading frame of 1,151 amino acids reported to have sequence similarity to reverse transcriptases. Here, we show that the LaBelle strain contains a novel DNA polymerase activity that is highly specific for the endogenous LaBelle plasmid DNA in nucleoprotein particles and can be distinguished from the mitochondrial DNA polymerase by several characteristics. Photolabeling experiments indicate that the LaBelle-specific DNA polymerase activity is associated with a polypeptide of 120 kDa, which is in good agreement with the size predicted for the protein encoded by the LaBelle plasmid open reading frame (132 kDa). This 120-kDa polypeptide is found only in the LaBelle strain that contains the mitochondrial plasmid, and it cosegregates with mitochondria in sexual crosses, suggesting that it is encoded by the plasmid. The LaBelle-specific DNA polymerase efficiently uses the artificial DNA substrates, poly(dA)-oligo(dT) and poly(dC)-oligo(dG), but despite its reported sequence similarity to reverse transcriptases, it has very low activity with analogous RNA substrates, poly(rA)-oligo(dT), poly(rC)-oligo(dG), or poly(rCm)-oligo(dG). Considered together with the previous sequence comparisons, our results suggest that the LaBelle plasmid encodes a novel DNA polymerase, which was derived from a protein that was at one time a reverse transcriptase but lost its ability to use RNA templates. This DNA polymerase now presumably functions in replication of the plasmid. Our results constitute the first biochemical evidence for a DNA polymerase activity associated with a mitochondrial plasmid. Further, they may provide insight into the evolution of DNA polymerases from reverse transcriptases, as presumably occurred in the course of evolution following the transition from the so-called RNA world to the present DNA world.

The LaBelle mitochondrial plasmid of Neurospora intermedia encodes a novel DNA polymerase that may be derived from a reverse transcriptase

The LaBelle-1b strain of Neurospora intermedia contains a 4.1-kb closed-circular mitochondrial plasmid DNA, which encodes a single long open reading frame of 1,151 amino acids reported to have sequence similarity to reverse transcriptases. Here, we show that the LaBelle strain contains a novel DNA polymerase activity that is highly specific for the endogenous LaBelle plasmid DNA in nucleoprotein particles and can be distinguished from the mitochondrial DNA polymerase by several characteristics. Photolabeling experiments indicate that the LaBelle-specific DNA polymerase activity is associated with a polypeptide of 120 kDa, which is in good agreement with the size predicted for the protein encoded by the LaBelle plasmid open reading frame (132 kDa). This 120-kDa polypeptide is found only in the LaBelle strain that contains the mitochondrial plasmid, and it cosegregates with mitochondria in sexual crosses, suggesting that it is encoded by the plasmid. The LaBelle-specific DNA polymerase efficiently uses the artificial DNA substrates, poly(dA)-oligo(dT) and poly(dC)-oligo(dG), but despite its reported sequence similarity to reverse transcriptases, it has very low activity with analogous RNA substrates, poly(rA)-oligo(dT), poly(rC)-oligo(dG), or poly(rCm)-oligo(dG). Considered together with the previous sequence comparisons, our results suggest that the LaBelle plasmid encodes a novel DNA polymerase, which was derived from a protein that was at one time a reverse transcriptase but lost its ability to use RNA templates. This DNA polymerase now presumably functions in replication of the plasmid. Our results constitute the first biochemical evidence for a DNA polymerase activity associated with a mitochondrial plasmid. Further, they may provide insight into the evolution of DNA polymerases from reverse transcriptases, as presumably occurred in the course of evolution following the transition from the so-called RNA world to the present DNA world.

Sequence of the cloned pyr4 gene of Trichoderma reesei and its use as a homologous selectable marker for transformation

We have cloned and sequenced the Trichoderma reesei pyr4 gene encoding orotidine-5'-monophosphate decarboxylase. Comparison of this sequence with that of the equivalent gene from other filamentous fungi suggests that T. reesei is closely related to Cephalosporium acremonium and Neurospora crassa. The cloned pyr4 gene has been used as a homologous selectable marker for transformation of T. reesei. The majority of transformants obtained with circular plasmid were mitotically unstable and contained non-integrated plasmid molecules, sometimes in addition to plasmid integrated in the genome, Linearization of plasmid prior to transformation decreased the transformation frequency but increased the proportion of stable transformation obtained.

A novel extrachromosomally maintained transformation vector for the lignin-degrading basidiomycete Phanerochaete chrysosporium

A stable extrachromosomally maintained transformation vector (pG12-1) for the lignin-degrading filamentous fungus Phanerochaete chrysosporium is described. The vector is 6.3 kb and contains a Kanr marker, pBR322 ori, and a 2.2-kb fragment (ME-1) derived from an endogenous extrachromosomal DNA element of P. chrysosporium. Vector pG12-1 was able to transform P. chrysosporium to G418 resistance and was readily and consistently recoverable from the total DNA of transformants via Escherichia coli transformation. Southern blot analyses indicated that pG12-1 is maintained at a low copy number in the fungal transformants. The vector is demonstrable in the total DNA of individual G418-resistant basidiospore progeny of the transformants only after amplification by polymerase chain reaction. Exonuclease III and dam methylation analyses, respectively, indicated that pG12-I undergoes replication in P. chrysosporium and that it is maintained extrachromosomally in a circular form. The vector is stably maintained in the transformants even after long-term nonselective growth. There is no evidence for integration of the vector into the chromosome at any stage.

Characterization of a leuA gene and an ARS element from Mucor circinelloides

A 4.4-kb PstI restriction endonuclease fragment of Mucor circinelloides DNA has previously been shown to both complement a leuA- mutation, and to enable the autonomous replication of plasmids within this organism. The complete nucleotide (nt) sequence of this fragment has been determined and an open reading frame of 1935 bp with no introns has been identified, which exhibits significant similarity (75% at the nt level) with 114 bp of the 5' coding region of the Saccharomyces cerevisiae LEU1 gene. Based on this and on the fact that the fragment weakly complements a leu1 auxotroph of S. cerevisiae, we concluded that the Mucor leu gene encodes alpha-isopropylmalate (alpha-IPM) isomerase and designated it leuA+ accordingly. Primer extension analysis of leuA mRNA and Northern-blot hybridization, indicated the leuA transcript to be approx. 2.3 kb in size, with 5'- and 3'-untranslated regions of 16-20 nt and approx. 450 nt, respectively. Specific Mucor ARS sequence(s) were not identified, although the general location of ARS was indicated by subcloning experiments. Nucleotide sequences are present within this region, which show some similarity with the core consensus of the S. cerevisiae ARS; however, any functional homology is doubtful, since insertion of the 4.4-kb PstI fragment into YIp5 did not increase the transformation frequency of S. cerevisiae with such a vector.

Characterization of the termini of linear plasmids from Nectria haematococca and their use in construction of an autonomously replicating transformation vector

The mitochondria of isolate FS37 from Nectria haematococca mating population I (Fusarium solani f. sp. cucurbitae) contain two linear plasmids, pFSC1 and pFSC2, of 9.2 and 8.3 kbp, respectively. Evidence for a protein blocking the 5' termini of these plasmids was obtained from exonuclease digestion experiments. A single protein band with an apparent Mr of 80 K was labeled when the DNA-protein complex of either plasmid was reacted with [125I] Bolton-Hunter reagent and then digested with DNase I. DNA sequence analysis of the termini of both plasmids revealed long inverted repeats of 1,211 bp (pFSC1) and 1,027 bp (pFSC2). No sequence similarity was found between the terminal inverted repeats (TIRs) of pFSC1 and pFSC2, nor was any similarity identified between the TIRs of these plasmids and sequences of TIRs from other linear DNAs. A restriction fragment containing the TIR of pFSC1 conferred autonomous replication when incorporated into an integrative transformation vector of Ustilago maydis.

The mitochondrial plasmid from Neurospora intermedia strain Labelle-1b contains a long open reading frame with blocks of amino acids characteristic of reverse transcriptases and related proteins

We have determined the DNA sequence of the 4070 base pair mitochondrial plasmid from the Labelle-1b strain of Neurospora intermedia. Analysis of the sequence revealed that the plasmid contains a long open reading frame (ORF) that could encode a protein of up to 1151 amino acids. Codon usage in the long ORF shows no clear relationship to Neurospora mitochondrial genes, nuclear genes, nor to the ORF of a different Neurospora mitochondrial plasmid. The long ORF contains regions of similarity to yeast mitochondrial RNA polymerase as well as blocks of amino acids that are characteristic of reverse transcriptases and the ORFs of certain group II mtDNA introns (Michel and Lang, (1985) Nature 316,641). The plasmid gives rise to specific transcripts, some of which may be unit length, and which carry the information for expression of the long ORF. The genetic organization and content of the plasmid suggest that it is related to mobile genetic elements.

Transformation in fungi

Transformation with exogenous deoxyribonucleic acid (DNA) now appears to be possible with all fungal species, or at least all that can be grown in culture. This field of research is at present dominated by Saccharomyces cerevisiae and two filamentous members of the class Ascomycetes, Aspergillus nidulans and Neurospora crassa, with substantial contributions also from fission yeast (Schizosaccharomyces pombe) and another filamentous member of the class Ascomycetes, Podospora anserina. However, transformation has been demonstrated, and will no doubt be extensively used, in representatives of most of the main fungal classes, including Phycomycetes, Basidiomycetes (the order Agaricales and Ustilago species), and a number of the Fungi Imperfecti. The list includes a number of plant pathogens, and transformation is likely to become important in the analysis of the molecular basis of pathogenicity. Transformation may be maintained either by using an autonomously replicating plasmid as a vehicle for the transforming DNA or through integration of the DNA into the chromosomes. In S. cerevisiae and other yeasts, a variety of autonomously replicating plasmids have been used successfully, some of them designed for use as shuttle vectors for Escherichia coli as well as for yeast transformation. Suitable plasmids are not yet available for use in filamentous fungi, in which stable transformation is dependent on chromosomal integration. In Saccharomyces cerevisiae, integration of transforming DNA is virtually always by homology; in filamentous fungi, in contrast, it occurs just as frequently at nonhomologous (ectopic) chromosomal sites. The main importance of transformation in fungi at present is in connection with gene cloning and the analysis of gene function. The most advanced work is being done with S. cerevisiae, in which the virtual restriction of stable DNA integration to homologous chromosome loci enables gene disruption and gene replacement to be carried out with greater precision and efficiency than is possible in other species that show a high proportion of DNA integration events at nonhomologous (ectopic) sites. With a little more trouble, however, the methodology pioneered for S. cerevisiae can be applied to other fungi too. Transformation of fungi with DNA constructs designed for high gene expression and efficient secretion of gene products appears to have great commercial potential.

Mitotic gene conversion, reciprocal recombination and gene replacement at the benA, beta-tubulin, locus of Aspergillus nidulans

We have developed a procedure for determining the rates of mitotic recombination of an interrupted duplication created by integration of transforming plasmid sequences at the benA, beta-tubulin, locus of Aspergillus nidulans. Transformation of a strain carrying a benomyl-resistant benA allele with plasmid AIpGM4, which carries the wild-type benA allele and the pyr4 (orotidine-5'-phosphate decarboxylase) gene of Neurospora crassa, creates an interrupted duplication with plasmid sequences flanked by two benA alleles, one wild type and one benomyl resistant. Such transformants will not grow in the presence of high levels of benomyl. Mitotic recombination causes the loss of the wild-type benA allele or conversion of the wild-type to the mutant allele resulting in nuclei carrying only the benomyl-resistant allele. Conidia containing such nuclei can be selected on media with high benomyl allowing easy quantitation of mitotic recombination. We found that the rate of recombination giving rise to benomyl-resistant conidia was 4.6 x 10(-4). Reciprocal recombination leading to benomyl-resistant conidia lacking plasmid sequences occurred at a rate of 2.0 x 10(-4) and gene conversion leading to benomyl-resistant conidia occurred at a rate of 2.6 x 10(-4). We selected for reciprocal recombination leading to loss of pyr4 sequences on 5-fluoro-orotic acid and used this selection for two-step gene replacement of a mutant benA allele with the wild-type allele.

Transformation of Phycomyces with a bacterial gene for kanamycin resistance

Phycomyces protoplasts transformed with a plasmid containing the bacterial gene for kanamycin resistance grow in the presence of G418, a kanamycin analogue. The plasmid also contains a Phycomyces DNA sequence that supports autonomous replication in yeast. We obtained about 250 transformants per microgram DNA or one per 5000 viable protoplasts. The transformant phenotype is retained under selective conditions and lost in the majority of the vegetative spores. Recovered plasmids and Southern analysis indicate that the plasmid probably replicates autonomously in Phycomyces.

Recombinant DNA in filamentous fungi: progress and prospects

Recombinant DNA technology enables the creation of well-defined alterations in the genetic material of an organism. Methods to manipulate recombinant DNA in the filamentous fungi (a group of microorganisms that includes species of academic as well as commercial interest) have recently been developed. This has been the result of adaptation of procedures successfully employed in the manipulation of other microorganisms. There are a number of similarities in the behavior of recombinant DNA in different fungi, but a number of differences have also been observed between the filamentous and the nonfilamentous fungi. Such differences include the ability to identify DNA replication origins and the host range of expression of fungal genes.

Characterization of inl+ transformants of Neurospora crassa obtained with a recombinant cosmid-pool

We constructed a Neurospora crassa gene library in a cosmid vector and used the cosmid-pool DNA to transform an inl, rg Neurospora crassa strain to inositol prototrophy. The inl+ colonies obtained in this experiment proved to be integrative type transformants. Genetic analysis revealed that the integration event occurred at or near the inl locus. In one of the transformants the inl+ trait exhibited mitotic and meiotic instability. In hybridization experiments free plasmids were detected in the F1 progeny of the transformants. We were able to recover eleven different plasmids from the F1 progeny of the transformants. None of these plasmids proved to carry a functional copy of the inl+ gene as judged by its transforming ability. Possible explanations for the observed phenomena are discussed.

General method for cloning Neurospora crassa nuclear genes by complementation of mutants

We have developed a sib selection procedure for cloning Neurospora crassa nuclear genes by complementation of mutants. This procedure takes advantage of a modified N. crassa transformation procedure that gives as many as 10,000 to 50,000 stable transformants per microgram of DNA with recombinant plasmids containing the N. crassa qa-2+ gene. Here, we describe the use of the sib selection procedure to clone genes corresponding to auxotrophic mutants, nic-1 and inl. The identities of the putative clones were confirmed by mapping their chromosomal locations in standard genetic crosses and using restriction site polymorphisms as genetic markers. Because we can obtain very high N. crassa transformation frequencies, cloning can be accomplished with as few as five subdivisions of an N. crassa genomic library. The sib selection procedure should, for the first time, permit the cloning of any gene corresponding to an N. crassa mutant for which an appropriate selection can be devised. Analogous procedures may be applicable to other filamentous fungi before the development of operational shuttle vectors.

Behaviour of recombinant plasmids in Aspergillus nidulans: structure and stability

A pyrG- Aspergillus strain was transformed with plasmid pDJB-1, derived from pBR325 by insertion of the Neurospora crassa pyr4 gene (orotidine 5'-phosphate carboxylase), giving mitotically unstable transformants. Aspergillus DNA which acted as an "autonomously replicating sequence" (ARS) in yeast was inserted into pDJB-1 and the resulting construct, pDJB12.1, gave mitotically stable transformants when introduced into Aspergillus. Transformants obtained with pDJB-1 and pDJB12.1 gave few pyr- progeny in crosses to a pyrG+ strain. Southern hybridisation analysis of pyr+ transformants obtained with pDJB-1 revealed restriction fragments expected for integrated plasmid but transformants obtained with pDJB12-1 showed only bands derived from free plasmid. pDJB-1 and derivatives of pDJB12.1 could be recovered from transformants. These derivatives could not be explained by straightforward excision of integrated pDJB12.1 sequences but could result from recombination between plasmid molecules. Hybridisation of undigested transformant DNAs showed that the transforming DNA was present in a high molecular weight form. These results suggest: (1) pDJB12.1 derivatives and possibly pDJB-1 can replicate autonomously in Aspergillus; (2) A. nidulans DNA acting as an ARS in yeast enhances replication and/or segregation of transforming plasmids in Aspergillus; and (3) recombinant plasmids may undergo rearrangements when introduced into Aspergillus.

General method for cloning Neurospora crassa nuclear genes by complementation of mutants

We have developed a sib selection procedure for cloning Neurospora crassa nuclear genes by complementation of mutants. This procedure takes advantage of a modified N. crassa transformation procedure that gives as many as 10,000 to 50,000 stable transformants per microgram of DNA with recombinant plasmids containing the N. crassa qa-2+ gene. Here, we describe the use of the sib selection procedure to clone genes corresponding to auxotrophic mutants, nic-1 and inl. The identities of the putative clones were confirmed by mapping their chromosomal locations in standard genetic crosses and using restriction site polymorphisms as genetic markers. Because we can obtain very high N. crassa transformation frequencies, cloning can be accomplished with as few as five subdivisions of an N. crassa genomic library. The sib selection procedure should, for the first time, permit the cloning of any gene corresponding to an N. crassa mutant for which an appropriate selection can be devised. Analogous procedures may be applicable to other filamentous fungi before the development of operational shuttle vectors.

Genetic analysis of transformation in a microconidiating strain of Neurospora crassa

We have characterized Neurospora crassa transformants obtained with plasmid pDV1001 bearing the cloned catabolic dehydroquinase (qa-2+) gene (Hughes et al. 1983a) and fluffy 268 host strain producing only uninucleate microconidia allowing to isolate individual transformation products. The percentage of transformed nuclei in the mycelium and their stability were determined by genetic analysis of microconidia produced on selective or non-selective medium. About half of the transformants originating from mycelial spheroplasts were apparently homokaryotic. Catabolic dehydroquinase activity was in agreement with the proportion of transformed nuclei. The DNAs from four transformants analyzed by Southern hybridization showed restriction fragments expected for integration of pDV1001 into genomic DNA by non-homologous recombination. No plasmids could be rescued from the undigested DNAs of the transformants by transformation of E. coli. One transformant, fl268-6, was unstable and generated a high proportion of segregants. Plasmid pDV1001 sequences were absent in their DNA. Colonies originating from microconidia of strain fl268-6 on selective plates often lost the transformed character. These results suggest that instability in this transformant is due to the loss of integrated plasmid sequences during vegetative growth.

Development of a high-frequency transforming vector for Aspergillus nidulans

The pyr4 gene of Neurospora crassa, which codes for orotidine-5'-phosphate decarboxylase, is capable of transforming an Aspergillus nidulans pyrG mutant by chromosomal integration, despite low homology between the transforming DNA and the recipient genome. Integration of pFB6, a plasmid carrying pyr4 and capable of replication in Escherichia coli, was not observed at the pyrG locus. The efficiency of transformation was considerably enhanced (50-100 fold) by inclusion in the transforming vector of a 3.5-kb A.nidulans chromosomal sequence, ans1. Although this sequence was isolated on the basis of replicating activity in Saccharomyces cerevisiae, there was no evidence for such activity in A.nidulans. Part of the ans1 fragment appears to be reiterated in the A.nidulans genome, though it is not yet clear whether this is directly responsible for the high transformation frequency. The efficiency of transformation of A.nidulans by plasmids bearing ans1, using an improved protocol, was approx. 5 X 10(3) stable transformants per microgram of plasmid DNA.

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

We have conducted a detailed study of 108 qa-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 the qa-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 the qa-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-BglII qa-2+ DNA fragment might possess an ars sequence. Transformation with linear plasmid DNAs and DNA fragments carrying the qa-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 resident qa-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.