Tagging pathogenicity genes inUstilago maydis by restriction enzyme-mediated integration (REMI)

In the maize pathogenic fungusUstilago maydis integration of transforming DNA at homologous or heterologous sites is often accompanied by duplications of the DNA. We show that it is possible to generate single-copy integration events with high efficiency by restriction enzyme-mediated integration (REMI). In about 50% of cases, a plasmid that contains a singleBamHI site is integrated at chromosomalBamHI sites, ifBamHI is added to the transformation mixtures. In the other cases it appears that integration events have also occurred preferentially atBamHI sites, but without restoration of the recognition sites. Using REMI we have generated approximately 1000 insertion mutants. Pathogenicity tests demonstrated that about 1–2% of these mutants were unable to induce symptoms when testedin planta. For two of the mutants we have shown that the phenotype is linked to the insertion event.     

Restriction enzyme-mediated DNA integration in Coprinus cinereus

Restriction enzyme-mediated DNA integration (REMI) has recently received attention as a new technique for the generation of mutants by transformation in fungi. Here we analyse this method in the basidiomycete Coprinus cinereus using the homologous pab1 gene as a selectable marker and the restriction enzymes BamHI, EcoRI and PstI. Addition of restriction enzymes to transformation mixtures results in an earlier appearance of transformants and influences transformation rates in an enzyme- and concentration-dependent manner. Low concentrations of restriction enzyme result in increased numbers of transformants compared to no addition of enzymes. Transformation rates decrease with higher enzyme concentrations. If protoplasts are made from cells stored in the cold, the transformation rates drop drastically even in the presence of low amounts of enzyme. In several transformants, plasmid integration directly correlated with the action of restriction enzyme at random chromosomal restriction sites. In some cases, restriction enzymes appear to reduce the number of integration events per transformant. Simultaneously, mutation rates can be enhanced due to the presence of restriction enzymes. Although restriction enzymes clearly promote plasmid integration into the host genome they also have cytotoxic and possibly mutagenic effects that result from processes other than plasmid integration. In consequence, for any given enzyme used in REMI mutagenesis, the enzyme concentration that gives the highest number of transformants must be defined experimentally. Such optimal transformation conditions should give the highest probability of obtaining mutations caused by a single restriction enzyme-mediated integration of the selection marker. Received: 2 September 1996 / Accepted: 7 April 1997     

Restriction enzyme-mediated DNA integration in Coprinus cinereus

Restriction enzyme-mediated DNA integration (REMI) has recently received attention as a new technique for the generation of mutants by transformation in fungi. Here we analyse this method in the basidiomycete Coprinus cinereus using the homologous pab1 gene as a selectable marker and the restriction enzymes BamHI, EcoRI and PstI. Addition of restriction enzymes to transformation mixtures results in an earlier appearance of transformants and influences transformation rates in an enzyme- and concentration-dependent manner. Low concentrations of restriction enzyme result in increased numbers of transformants compared to no addition of enzymes. Transformation rates decrease with higher enzyme concentrations. If protoplasts are made from cells stored in the cold, the transformation rates drop drastically even in the presence of low amounts of enzyme. In several transformants, plasmid integration directly correlated with the action of restriction enzyme at random chromosomal restriction sites. In some cases, restriction enzymes appear to reduce the number of integration events per transformant. Simultaneously, mutation rates can be enhanced due to the presence of restriction enzymes. Although restriction enzymes clearly promote plasmid integration into the host genome they also have cytotoxic and possibly mutagenic effects that result from processes other than plasmid integration. In consequence, for any given enzyme used in REMI mutagenesis, the enzyme concentration that gives the highest number of transformants must be defined experimentally. Such optimal transformation conditions should give the highest probability of obtaining mutations caused by a single restriction enzyme-mediated integration of the selection marker.     

Stable transformation and regulated expression of an inducible reporter construct inCandida albicans using restriction enzyme-mediated integration

To allow the regulated expression of cloned genes inCandida albicans, a plasmid was constructed using the inducible promoter of theC. albicans MAL2 gene. To demonstrate that theMAL2 promoter could regulate cloned genes placed under its control, a fusion construct was made with the coding sequence of theC. albicans URA3 gene. This plasmid was introduced into a Ura^– strain ofC. albicans using the process of restriction enzyme-mediated integration (REMI). This procedure involves the transformation of theBamHI-linearized plasmid in the presence ofBamHI enzyme. The majority of transformants generated contained insertions of the plasmid at chromosomalBamHI sites. All transformants examined were inducible forURA3 expression, which was determined by growth analysis and by measuring the level ofURA3 gene product activity. The Ura⁺ phenotype of the transformants was stable during growth under nonselective conditions. This system offers the advantages of stable transformation, easy recovery of integrated DNA, and inducible expression of genes inC. albicans.Deceased, December 15, 1995     

Insertional mutagenesis of Aspergillus fumigatus

We have investigated transformation with heterologous DNA as a method for insertional mutagenesis of Aspergillus fumigatus. Two methods, polyethylene glycol-mediated transformation of protoplasts and electroporation of germinating spores, were used to establish conditions leading to single-copy integration of transforming DNA at different genomic sites. We have assessed the effect of restriction enzyme-mediated integration (REMI) for both methods. Non-REMI protoplast transformation led to integration of multiple copies of transforming DNA in the majority of transformants. Results of REMI with protoplast transformation varied depending on the enzyme used. Low concentrations of several restriction enzymes stimulated transformation, but of ten enzymes investigated only REMI with XhoI and KpnI resulted in single-copy integration of transforming DNA for the majority of transformants. For protoplast transformation with XhoI- or KpnI-based REMI, 50% and 76% of insertions, respectively, were due to integrations at a genomic enzyme site corresponding to the enzyme used for REMI. Electroporation of spores without addition of restriction enzyme resulted in a high transformation efficiency, with up to 67% of transformants containing a single copy of transforming DNA. In contrast to protoplast transformation, electroporation of spores in the presence of a restriction enzyme did not improve transformation efficiency or lead to insertion at genomic restriction sites. Southern analysis indicated that for both protoplast transformation with REMI using KpnI or XhoI and for electroporation of spores without addition of restriction enzymes, transforming DNA inserted at different genomic sites in a high proportion of transformants. Received: 6 March 1998 / Accepted: 25 May 1998     

Restriction analysis of lambda EMBL3 background recombinants: occurrence of lambda phages carrying a head to tail oriented left arm DNA sequence

Summary Eight representative recombinant background clones of λEMBL3 were analysed usingKpnI,BamHI,SalI,EcoRI andHindIII digestion. We found that λEMBL3 carries its own left arm in theBamHI cloning site. In this way, recombinant molecules were found to be generated which can grow onEscherichia coli strain NM539. In all cases analysed, the left arm DNA was inserted in a head to tail orientation. Seven clones carried a restoredBamHI site at thecos site-BamHI site connection. In the region where the inserted left arm and the right arm were ligated,BamHI cloning produces a large palindromic sequence consisting of two polylinkers. ThisBamHI site was incompletely cleaved in all cases analysed. We assume that a part of the λ DNA molecule in this region shows a cruciform structure prohibiting recognition or cleavage of this site by restriction endonucleaseBamHI.     

Sequence analysis of Vicia faba highly repeated DNA: the BamHI repeated sequence families

Cleavage of Vicia faba nuclear DNA with the restriction endonuclease BamHI yielded discrete size classes of 250, 850, 900, 990, 1 150, 1 500 and 1 750 bp of highly repetitive DNA. Each of these sequence families comprised about 3% of the total genomic DNA. Some sequence members from each sequence family were cloned in pBR322 and their primary structures determined. Computer analyses of nucleotide sequences suggested the existence of about 60 bp sequence periodicity within the repeating unit of the 990 bp sequence family, though the extent of homology among the surmised shorter subrepeat units was very low. With other BamHI sequence families, however, the data did not show any clear internal sequence periodicity. The repeat units of the 850 bp and 1 750 bp sequence families contained nucleotide sequences homologous to the 250 bp family sequence. No sequence relationship between or among other sequence families was observed. There was 13–25% sequence variation among 6 cloned members of the 250 bp family and probably also among those of other BamHI repeat families. DNA sequences homologous to these V. faba BamHI repeat families were detected in Pisum sativum DNA by Southern blot hybridization. Furthermore, very weak cross-hybridization was observed with plant DNAs from Phaseolus vulgaris, Triticum aestivum, Cucumis sativus and Trillium kamtschaticum.     

Restriction enzyme-mediated integration used to produce pathogenicity mutants of Colletotrichum graminicola

We have developed a restriction enzyme-mediated insertional mutagenesis (REMI) system for the maize pathogen Colletotrichum graminicola. In this report, we demonstrate the utility of a REMI-based mutagenesis approach to identify novel pathogenicity genes. Use of REMI increased transformation efficiency by as much as 27-fold over transformations with linearized plasmid alone. Ninety-nine transformants were examined by Southern analysis, and 51% contained simple integrations consisting of one copy of the vector integrated at a single site in the genome. All appeared to have a plasmid integration at a unique site. Sequencing across the integration sites of six transformants demonstrated that in all cases the plasmid integration occurred at the corresponding restriction enzyme-recognition site. We used an in vitro bioassay to identify two pathogenicity mutants among 660 transformants. Genomic DNA flanking the plasmid integration sites was used to identify corresponding cosmids in a wild-type genomic library. The pathogenicity of one of the mutants was restored when it was transformed with the cosmids.     

Towards an integrated linkage map of common bean

Summary Two genomic libraries were established to provide markers to develop an integrated map combining molecular markers and genes for qualitative and quantitative morpho-agronomic traits in common bean. Contrasting characteristics were observed for the two libraries. While 89% of the PstI clones were classified as single-copy sequences, only 21% of the EcoRIBamHI clones belonged in that category. Clones of these two libraries were hybridized against genomic DNA of nine genotypes chosen according to their divergent evolutionary origin and contrasting agronomic traits. Eight restriction enzymes were used in this study. PstI clones revealed 80–90% polymorphism between the Andean and Middle American gene pools and 50–60% polymorphism within these gene pools. However, under the same conditions only 30% of the EcoRI-BamHI clones showed polymorphism between the Middle American and Andean gene pools. Hybridization with PstI clones to EcoRI-, EcoRV-, or HindIII-digested genomic DNA resulted in a cumulative frequency of polymorphism of approximately 80%. Hybridizations to BamHI-, HaeIII-, HinfI-, PstI-, and XbaI-digested genomic DNA detected no additional polymorphisms not revealed by the former three enzymes. In the PstI library, a positive correlation was observed between the average size of hybridizing restriction fragments and the frequency of polymorphism detected by each restriction enzyme. This relationship is consistent with the higher proportion of insertion/deletion events compared with the frequency of nucleotide substitutions observed in that library.     

Characterization of eight excision plasmids of Pseudomonas syringae pv. phaseolicola

Summary Pseudomonas syringae pv. phaseolicola strain LR719 contains a 150 kilobase pair (kb) plasmid pMC7105, stably integrated into its chromosome. Occasionally, single colony isolates of this strain contain an excision plasmid. Eight unique excision plasmids were selected and characterized by BamHI restriction endonuclease and blot hybridization analyses. These plasmids ranged in size from 35 to 270 kb; the largest contained approximately 130 kb of chromosomal DNA sequences. Restriction maps of pMC7105 were developed to deduce the site of integration and to identify the fragments in which recombination occurred to produce each excision plasmid. The eight excision plasmids were arranged into five classes based on the sites where excision occurs. A 20 kb region of pMC7105, which includes BamHI fragment 9 and portions of adjacent fragments, is present in all excision plasmids and thought to contain the origin of replication. The site of integration on pMC7105 maps within BamHI fragment 8. This fragment shows homology with seven other BamHI fragments of pMC7105 and with five chromosomal fragments identified among the excision plasmids. The data strongly suggest that the integration of pMC7105 may have occurred at a repetitive sequence present on the chromosome and on the plasmid.     

Insertional mutagenesis of Aspergillus fumigatus

We have investigated transformation with heterologous DNA as a method for insertional mutagenesis of Aspergillus fumigatus. Two methods, polyethylene glycol-mediated transformation of protoplasts and electroporation of germinating spores, were used to establish conditions leading to single-copy integration of transforming DNA at different genomic sites. We have assessed the effect of restriction enzyme-mediated integration (REMI) for both methods. Non-REMI protoplast transformation led to integration of multiple copies of transforming DNA in the majority of transformants. Results of REMI with protoplast transformation varied depending on the enzyme used. Low concentrations of several restriction enzymes stimulated transformation, but of ten enzymes investigated only REMI with XhoI and KpnI resulted in single-copy integration of transforming DNA for the majority of transformants. For protoplast transformation with XhoI- or KpnI-based REMI, 50% and 76% of insertions, respectively, were due to integrations at a genomic enzyme site corresponding to the enzyme used for REMI. Electroporation of spores without addition of restriction enzyme resulted in a high transformation efficiency, with up to 67% of transformants containing a single copy of transforming DNA. In contrast to protoplast transformation, electroporation of spores in the presence of a restriction enzyme did not improve transformation efficiency or lead to insertion at genomic restriction sites. Southern analysis indicated that for both protoplast transformation with REMI using KpnI or XhoI and for electroporation of spores without addition of restriction enzymes, transforming DNA inserted at different genomic sites in a high proportion of transformants.     

Increased transformation frequency and tagging of developmental genes in Aspergillus nidulans by restriction enzyme-mediated integration (REMI)

We have used a plasmid containing the argB gene to transform an Aspergillus nidulansargB-deleted strain in the presence of restriction enzymes and show a 20- to 60-fold increase in transformation frequency via restriction enzyme-mediated integration (REMI). This procedure was used to try to tag new genes involved in the asexual development of this fungus. More than 2000 transformants isolated following electroporation of conidia and ∼3700 transformants recovered following protoplast fusion were screened for sporulation defects. Unexpectedly, developmental mutants were obtained only when the protoplast fusion approach was used. Southern blot analysis of these mutants, and of randomly selected transformants obtained by electroporation, was consistent with the occurrence of single plasmid integration events in 33 and 65% of the cases, respectively. The argB marker was shown to be tightly linked to the mutant phenotype in only 62% of the mutants analyzed by sexual crosses. Partial DNA sequencing of a tagged gene, whose mutation delays asexual sporulation and results in a fluffy phenotype, showed no homology to previously reported sequences. Our results indicate that REMI can be used in A. nidulans to increase the transformation frequency and illustrate the advantages and potential problems when using REMI to tag genes of interest in this and other fungi. Received: 22 August 1997 / Accepted: 20 November 1997     

Cercosporin-deficient mutants by plasmid tagging in the asexual fungus<Emphasis Type="Italic"> Cercospora nicotianae</Emphasis>

We have successfully adapted plasmid insertion and restriction enzyme-mediated integration (REMI) to produce cercosporin toxin-deficient mutants in the asexual phytopathogenic fungus Cercospora nicotianae. The use of pre-linearized plasmid or restriction enzymes in the transformation procedure significantly decreased the transformation frequency, but promoted a complicated and undefined mode of plasmid integration that leads to mutations in the C. nicotianae genome. Vector DNA generally integrated in multiple copies, and no increase in single-copy insertion was observed when enzymes were added to the transformation mixture. Out of 1873 transformants tested, 39 putative cercosporin toxin biosynthesis ( ctb) mutants were recovered that showed altered levels of cercosporin production. Seven ctb mutants were recovered using pre-linearized plasmids without the addition of enzymes, and these were considered to be non-REMI mutants. The correlation between a specific insertion and a mutant phenotype was confirmed using rescued plasmids as gene disruption vectors in the wild-type strain. Six out of fifteen rescued plasmids tested yielded cercosporin-deficient transformants when re-introduced into the wild-type strain, suggesting a link between the insertion site and the cercosporin-deficient phenotype. Sequence analysis of a fragment flanking the insert site recovered from one insertion mutant showed it to be disrupted in sequences with high homology to the acyl transferase domain of polyketide synthases from other fungi. Disruption of this polyketide synthase gene ( CTB1) using a rescued plasmid resulted in mutants that were defective in cercosporin production. Thus, we provide the first molecular evidence that cercosporin is synthesized via a polyketide pathway as previously hypothesized.Communicated by E. Cerdá-Olmedo     

Genetic analysis of the parB+ locus of plasmid R1

Summary Megaplasmid DNA from mutants has been analysed physically for deletions and insertions in order to identify the location of hydrogenase (hox) genes in Alcaligenes eutrophus. Four classes of mutants have been examined: mutants defective in genes coding for soluble NAD-dependent hydrogenase (hoxS), mutants impaired in the membrane-bound hydrogenase (hoxP), mutants altered in the regulation of hox gene expression (hoxC) and mutants with lesions in the carbon dioxide fixing enzyme system (cfx). A comparison of the restriction patterns with EcoRI, BamHI and HindIII, complementation studies with cloned DNA and DNA - DNA hybridization experiments showed that genes coding for hox and cfx are clustered on a 100-kb region of the 450-kb plasmid pHG1.     

Mutant invertase proteins accumulate in the yeast endoplasmic reticulum

Summary Intercompartmental transport of secreted proteins in yeast was analysed using invertase mutants. Deletions and insertions at the BamHI (position +787) or the Asp718 (position +1159) sites of the SUC2 gene led to mutant proteins with different behaviour regarding secretion, localization and enzyme activity. The deletion mutants showed accumulation of core glycosylated material in the endoplasmic reticulum (ER) a decrease of secreted protein by 5%–30% and loss of enzyme activity. The secreted material was localized in the culture medium and not — as is normal for invertase-in the cell wall. No delay in transport from the Golgi to the cell surface was observed, indicating that the rate-limiting step for secretion is at the ER-Golgi stage. Two insertion mutants, pIPA and pIPB, retained enzyme activity. Mutant pIPB showed 10% secretion, while 60%–70% secretion was observed for pIPA. While the non-secreted material accumulated in the ER, the secreted material was present in the cell wall. The results suggest that the presence of structures incompatible with secretion leads to ER accumulation of mutated invertase.     

Stable transformation and regulated expression of an inducible reporter construct inCandida albicans using restriction enzyme-mediated integration

To allow the regulated expression of cloned genes inCandida albicans, a plasmid was constructed using the inducible promoter of theC. albicans MAL2 gene. To demonstrate that theMAL2 promoter could regulate cloned genes placed under its control, a fusion construct was made with the coding sequence of theC. albicans URA3 gene. This plasmid was introduced into a Ura^? strain ofC. albicans using the process of restriction enzyme-mediated integration (REMI). This procedure involves the transformation of theBamHI-linearized plasmid in the presence ofBamHI enzyme. The majority of transformants generated contained insertions of the plasmid at chromosomalBamHI sites. All transformants examined were inducible forURA3 expression, which was determined by growth analysis and by measuring the level ofURA3 gene product activity. The Ura⁺ phenotype of the transformants was stable during growth under nonselective conditions. This system offers the advantages of stable transformation, easy recovery of integrated DNA, and inducible expression of genes inC. albicans.     

Nonhomologous End Joining during Restriction Enzyme-Mediated DNA Integration in Saccharomyces cerevisiae

The BamHI restriction enzyme mediates integration of nonhomologous DNA into the Saccharomyces cerevisiae genome (R. H. Schiestl and T. D. Petes, Proc. Natl. Acad. Sci. USA 88:7585–7589, 1991). The present study investigates the mechanism of such events: in particular, the mediating activity of various restriction enzymes and the processing of resultant fragment ends. Our results show that in addition to BamHI, BglII and KpnI increase DNA integration efficiencies severalfold, while Asp718, HindIII, EcoRI, SalI, SmaI, HpaI, MscI, and SnaBI do not. Secondly, the three active enzymes stimulated integrations only of fragments containing 5′ or 3′ overhangs but not of blunt-ended fragments. Thirdly, integrations mediated by one enzyme and utilizing a substrate created by another required at least 2 bp of homology. Furthermore, an Asp718 fragment possessing a 5′ overhang integrated into a KpnI (isoschizomer) site possessing a 3′ overhang, most likely by filling of the 5′ overhang followed by 5′ exonuclease digestion to produce a 3′ end. We classified and analyzed the restriction enzyme-mediated integration events in the context of their genomic positions. The majority of events integrated into single sites. In the remaining 6 of 19 cases each end of the plasmid inserted into a different sequence, producing rearrangements such as duplications, deletions, and translocations.DNA double-strand breaks occur either as a result of assaults by external agents or spontaneously during DNA metabolism, repair, or replication. Double-strand breaks may cause genome rearrangements, such as deletions, duplications, and translocations, which have been implicated in carcinogenesis. For any cell, double-strand break repair is essential, since these cytotoxic DNA lesions may cause potentially lethal losses of chromosomes. In the yeast Saccharomyces cerevisiae, DNA repair enzymes encoded by genes belonging to the RAD52 epistasis group repair double-strand breaks by homologous recombination. This process requires homologous DNA sequences, usually present on sister chromatids and on homologous chromosomes in diploids. In mammalian cells, however, the majority of double-strand breaks are repaired by nonhomologous end joining (NHEJ) (32). This event in S. cerevisiae occurs either in rad52 mutants in the presence of homology (18) or in the wild type in the absence of homology (26, 36). Joining reactions of restriction enzyme-produced DNA ends have frequently been used to study NHEJ both in vivo and in vitro. NHEJ of substrates with defined terminal configurations produced by different enzyme digestions were studied in vitro in the presence of Xenopus laevis extracts (2, 30, 43) and in vivo in mammalian cells (32) and fission yeast cells (12). In S. cerevisiae, illegitimate repair of a double-strand break in a plasmid was studied by Mezard and Nicolas (25) and the repair of double-strand breaks produced by an inducible HO endonuclease in the absence of homology was studied by Moore and Haber (26) (for the conclusions of those studies see Discussion).Schiestl and Petes (36) studied illegitimate integration events by transforming a BamHI URA3 fragment into yeast cells lacking homology to the transforming DNA (in a ura3 deletion mutant), so that integration into the genome was by illegitimate recombination. With BamHI in the transformation mixture, the URA3 fragment integrated into genomic BamHI sites and the frequency of integration increased sixfold (36). These experiments suggest that the BamHI restriction enzyme can cut chromosomal DNA in vivo and thus mediate integration of the transforming DNA into that site. Subsequently, restriction enzyme-mediated integration (REMI) has been used in a variety of organisms for insertional mutagenesis. For example, Kuspa and Loomis (20) first adapted this technology to Dictyostelium discoideum, where previously cloning of developmental genes by complementation of mutant phenotypes was not feasible. Application of REMI has led to construction of REMI-restriction fragment length polymorphism maps (19, 23) and the cloning of most developmental genes in Dictyostelium. REMI has also been adapted successfully to the ascomycete Cochliobolus heterostrophus (24) and the maize pathogenic fungus Ustilago maydis (3) to tag genes by insertional mutagenesis.Here we find that enzymes vary in their ability to mediate integration into the yeast genome. Furthermore, we present model mechanisms based on the products created from various blunt 5′ protruding single strand (PSS) and 3′ PSS joining combinations.     

Indication for deletion of two introns in theoxi-3 gene of a respiratory-competentSaccharomyces cerevisiae strain

Physical mapping of the mitochondrial DNA of the wild-typeSaccharomyces cerevisiae strainRXII revealed that most of the restriction sites as well as the location of the apocytochromeb gene were identical in comparison with the known maps of the mitochondrial genome in otherSaccharomyces cerevisiae strains. In the middle of theSalI linearized map of theRXII mitochondrial DNA, a deletion was detected which resulted in the loss of twoEcoRI and oneBamHI restriction sites. The corresponding region, however, exists in most other laboratory strains ofSaccharomyces mapped so far. This region overlaps the introns aI2 and aI3 surrounding exon A3 sequences of the subunit 1 of the cytochrome oxidase gene. The nucleotide sequence of the subunit 1 gene showed that theBamHI site was located close to the aI3-A4 intron-exon junction and the distalEcoRI site close to the aI2-A2 boundary. I therefore conclude that these two introns are deleted in the mitochondrial genome of strainRXII. The exon A3 must have been conserved since this strain was respiratory competent. This result, while being a good example of the morphological diversity of a genome with the same function, may contribute to an understanding of the role of introns in the mitochondrial split genes in yeast.     

Intra-individual heterogeneity of rDNA allows the distinction between two closely related species in the Genus Helianthus

The Ribosomal DNAs of Helianthus annuus and H. argophyllus were analysed. Total DNA from single individuals of six cultivated lines, one wild ecotype ofH. annuus, and three ecotypes of H. argophyllus, were digested with various restriction enzymes. Hybridisation of Southern blots with sunflower ribosomal probes containing most of the interspacer regions (R3) or the 25 s coding region (R2) reveals different patterns from those expected: while no difference between H. annuus and H. argophyllus had been observed in previous rDNA RFLP analysis, our study clearly distinguished the two species on the basis of two different patterns when using R3 and BamHI, BstYI, or EcoRI/BamHI. Furthermore, the sum of the fragment weights of the BamHI restriction patterns was much greater than that of the rDNA entire unit-weight space. The co-existence of different rDNA units within single individuals is proposed as a model to explain these results. Four rDNA units were distinguished, which differed in their state of methylation and by the presence of mutations at two BamRI restriction sites. H. annuus individuals displayed two types of rDNA units while H. argophyllus individuals displayed four types.     

Mapping and genetic organization of pTiChry5, a novel Ti plasmid from a highly virulent Agrobacterium tumefaciens strain

Agrobacterium tumefaciens Chry5, a wild-type strain originally isolated from chrysanthemum, is unusually tumorigenic, particularly on soybean. We have mapped the Chry5 Ti plasmid by genomic walking and restriction endonuclease analysis, and have located its virulence, T-DNA, plasmid incompatibility, and l,l-succinamopine utilization loci. Southern analysis has revealed that about 85% of the Chry5 Ti plasmid is highly homologous to another Ti plasmid, pTiBo542. Although all the functions that we have located on pTiChry5 are encoded by pTiBo542-homologous regions, the two Ti plasmids differ in their genetic organization. The overall patterns of restriction sites in the plasmids also differ, with the exception of an approximately 12 kb segment of the virulence region, where the BamHI sites appear to be conserved. Complementation analysis has shown that deletion of a DNA segment which flanks the oncogenic T-DNA results in severe attenuation of virulence. This region also contains a sequence that is repeated in the Chry5 genome outside the Ti plasmid, and that is widely distributed in the Rhizobiaceae.