DNA fingerprinting for differentiating aggressivity groups of the rape seed pathogen Leptosphaeria maculans

Molecular phylogeny of the Leptosphaeria maculans-L. biglobosa species complex

Leptosphaeria maculans (anamorph Phoma lingam), the ascomycete causing stem canker of crucifers, is a species complex that can be separated into at least seven distinct subgroups using a combination of biochemical and molecular criteria. In the present study sequences of the entire ITS region, including the 5.8S rDNA, of 38 isolates representing the seven subgroups, along with specimens from culture collections, were analysed, compared to those of closely related Leptosphaperia species, and the phylogeny inferred using parsimony and distance analyses. A well-supported clade encompassed all isolates of the seven subgroups along with L. conferta, a known saprobe of dried crucifer stems. The L. maculans isolates were further separated into two well-supported clades corresponding to L. maculans s. str. and the recently named L. biglobosa. Parsimony and distance analyses further separated groups within both species, usually corresponding to specific host plants or geographic origin, e.g. L. maculans 'brassicae' from cultivated Brassica, L. maculans 'lepidii'. from Lepidium sp., L. biglobosa 'brassicae', from various Brassica species, L. biglobosa 'thlaspii' from Thlaspi arvense, L. biglobosa 'erysimii' from Erysimum sp., and L. biglobosa 'canadensis' mostly found in central Canada. The oldest L. maculans specimens maintained in international collections clustered with either L. maculans 'brassicae', L. biglobosa 'brassicae', or a still different group closely related to L. biglobosa 'thlaspii'. The evolutionary relationships between the seven infraspecific groups are discussed in terms of phytopathological relevance and species isolation linked with specific life cycle, geographic isolation or host specificity.

Assessment of Genetic Variation Among Leptosphaeria maculans Isolates Using Pathogenicity Data and AFLP Analysis

Increased production of rapeseed in the north central and southeastern regions of the United States has been accompanied by an increase in the incidence of blackleg disease caused by Leptosphaeria maculans. In order to assess the genetic variability and relatedness of isolates from these regions to others from around the world, we analyzed 49 aggressive isolates representing three pathogenicity groups (PG2, 3, and 4) of L. maculans from North Dakota, Georgia, Ontario, Western Canada, the United Kingdom (UK), France, Germany, and Australia using pathogenicity data and amplified fragment length polymorphism (AFLP). Approximately 10% of the 400 amplified fragments were polymorphic, scored as discrete characters and analyzed by cluster analysis. The isolates from North Dakota, Western Canada, Georgia, and PHW1252 from the UK formed one tightly clustered group and were mostly of the same pathogenicity group; whereas isolates from Ontario, Australia, France, Germany, and the remaining isolates from the UK formed a second group, which exhibited greater variation and consisted of three pathogenicity groups. The similarity between North Dakota isolates collected in 1995-96 and Western Canadian isolates collected in the 1980s suggests that L. maculans was introduced into North Dakota from Western Canada, and that the populations have remained relatively unchanged over the past 10 years.

Conidia as a Substrate for Internal Transcribed Spacer-Based PCR Identification of Members of the Leptosphaeria maculans Species Complex

ABSTRACT The blackleg disease of oilseed rape is caused by an ascomycete species complex termed Leptosphaeria maculans (anamorph Phoma lingam). L. maculans isolates collected worldwide were gathered in the International Blackleg of Crucifers Network (IBCN) collection. Representative IBCN isolates, along with one P. nigrificans isolate, were further analyzed using polymerase chain reaction (PCR) amplification of the internal transcribed spacer (ITS) region. ITS size polymorphism discriminated three groups: (i) P. nigrificans, (ii) Tox(+) and 'Lepidium' isolates, and (iii) NA1, NA2, NA3, 'Thlaspi', and 'Erysimum' isolates. Digestion of the ITS region with 19 selected endonucleases showed restriction site polymorphism between the different subgroups: digestion with RsaI could discriminate Tox(+) from 'Lepidium' isolates, whereas digestion with four enzymes, i.e., HaeIII, EcoRII, RsaI, and AluI, was needed to discriminate between NA1, NA2, NA3, 'Thlaspi', and 'Erysimum' isolates. No restriction site polymorphism was observed between isolates within the 'Thlaspi', Tox(+), NA1, and NA2 subgroups. Direct amplification of the ITS region could be achieved using intact conidia, collected either in axenic cultures or on leaf lesions, with only a 4-min 95 degrees C denaturation step prior to PCR reaction. A routine identification protocol requiring no DNA extraction and a sequential use of a few restriction enzymes following PCR has been used successfully for large-scale identification of French field isolates.

Genetic Analysis and Identification of Amplified Fragment Length Polymorphism Markers Linked to the alm1 Avirulence Gene of Leptosphaeria maculans

ABSTRACT A gene-for-gene interaction was previously suggested by mapping of a single major locus (LEM 1) controlling cotyledon resistance to Leptosphaeria maculans isolate PHW1245 in Brassica napus cv. Major. In this study, we obtained further evidence of a gene-for-gene interaction by studying the inheritance of the corresponding avirulence gene in L. maculans isolate PHW1245. The analysis of segregating F(1) progenies and 14 test crosses suggested that a single major gene is involved in the interaction. This putative avirulence gene was designated alm1 after the resistance locus identified in B. napus. Amplified fragment length polymorphism (AFLP) markers were used to generate a rudimentary genetic linkage map of the L. maculans genome and to locate markers linked to the putative avirulence locus. Two flanking AFLP markers, AC/TCC-1 and AC/CAG-5, were linked to alm1 at 3.1 and 8.1 cM, respectively. Identification of markers linked to the avirulence gene indicated that the differential interaction is controlled by a single gene difference between parental isolates and provides further support for the gene-for-gene relationship in the Leptosphaeria-Brassica system.

Population structure and genetic variation in Nectria fuckeliana

Population structure and genetic variation in Nectria fuckeliana Booth isolated from Picea abies (L.) Karst. in Sweden and Lithuania was studied using somatic incompatibility tests and DNA fingerprinting. All incompatibility pairings between different isolates of N. fuckeliana resulted in demarcation zones; thus, no vegetative compatibility groups were detected. Each isolate was distinguishable from all other isolates on the basis of banding patterns produced by amplification of DNA using the M13 primer. No country-specific markers were observed. Principal component analysis of amplified banding patterns separated the isolates from Sweden and Lithuania into two clusters, showing genetic differentiation between the geographical populations across the Baltic sea. An analysis of similarity matrix, calculated by the program SIMQUAL from the numerical taxonomy package NTSYS-pc, confirmed the separation of the isolates into the two groups. Low genetic differentiation was revealed within both the Swedish and Lithuanian geographical populations of the fungus. Local distances in the forest stand (100 m) had no influence on the genetic similarity of the N. fuckeliana isolates (R2 = 0.003). Key words: Nectria fuckeliana, DNA fingerprinting, genetic variation, somatic incompatibility, population structure.

Polymerase chain reaction fingerprinting in fungi using single primers specific to minisatellites and simple repetitive DNA sequences: strain variation in Cryptococcus neoformans

Minisatellites and simple repetitive DNA sequence motifs are used as conventional oligonucleotide probes in DNA-hybridization-based fingerprinting. The same oligonucleotides can be used as single primers in the polymerase chain reaction (PCR) to generate individual PCR fingerprints. In this study, the simple repetitive sequences, (CA)8, (CT)8, (CAC)5, (GTG)5, (GACA)4 and (GATA)4, and a minisatellite core sequence derived from the wild-type phage M13 (5' GAGGGTGGCGGTTCT 3') were used as specific, single primers to amplify hypervariable repetitive DNA sequences during PCR analysis. The potential applications of this techniques are demonstrated with clinical isolates of the human pathogenic yeast, Cryptococcus neoformans. PCR fingerprint patterns have remained stable after long-term in vitro passage ( > 2 1/2 years to date). Hybridization of the primers to blots of electrophorectically separated chromosomes demonstrated that the target sequences recognized by most of the primers are dispersed through the entire yeast genome. Sequence analysis of the cloned bands obtained by PCR fingerprinting indicated that if the same or extremely similar, inversely oriented tandem repeats are located close to each other, when only one repeat-specific primer is used in the PCR, the region between these repeats is amplified. PCR fingerprinting has a wide range of current and potential applications to fungi, such as clarifying taxonomic questions, facilitating epidemiological studies and improving the diagnosis of mycotic diseases.

Genetic variability in Gibberella fujikuroi and some related species of the genus Fusarium based on random amplification of polymorphic DNA (RAPD)

One of the most important rice pathogens is Fusarium moniliforme (perfect stage: Gibberella fujikuroi), the causal agent of the super-elongation ("bakanae") disease. Thirty-seven strains of this species from different geographical regions were analyzed for their ability to produce gibberellins (GA) and for genetic relatedness by random amplified polymorphic DNA (RAPD). All GA-producing isolates showed nearly identical RAPD patterns using 51 oligonucleotide nona- and deca-mers as arbitrary primers. On the other hand, large differences between GA-nonproducing isolates were obtained. Comparison of the RAPD patterns with those of the tester strains of the six known mating populations (A, B, C, D, E, F) of G. fujikuroi showed that all producer strains belong to mating population C and all nonproducer isolates to other mating populations. Evidence for the usefulness of the RAPD technique to distinguish between mating populations was provided by sexual crossings. Consensus phylogenetic trees based on RAPDs were constructed by the Phylogenetic Analysis Using Parsimony (PAUP) system. In combination with morphological analysis, RAPD can distinguish between different species of the genus Fusarium. These investigations may find an application in the diagnosis of unknown Fusarium spp. and in distinguishing isolates of G. fujikuroi within the section Liseola.

Variability in genome organization of the zygomycete Parasitella parasitica

In addition to conventional methods for the identification of fungi, molecular techniques at the DNA level are increasingly being employed. In order to check the validity of such experimental approaches, we have analyzed the well-defined species Parasitella parasitica, which belongs to the family Mucoraceae (Mucorales, Zygometes). The seven strains of this species, which are available from international strain collections, were analyzed by several molecular methods: restriction fragment length polymorphism analysis (RFLP), the random primer-dependent polymerase chain reaction (RAPD-PCR), and electrophoretic karyotyping. Unexpectedly, these strains are highly diverse at the molecular level. By these techniques they can be divided consistently into two different groups. Nevertheless, all seven strains belong to a single species. They show no morphological differences and sexual spores (zygospores) were found in all possible combinations either within or between the two groups. Southern-blot analysis of genomic DNA of all P. parasitica strains with RAPD-PCR-derived labelled probes shows the existence of repetitive elements characteristic for only one group of P. parasitica. In addition, chromosome sizes, which were separated by rotating-field electrophoresis, were highly divergent, and ranged from 3 to 6.5 Mb in one group and between 2 and 4.5 Mb in the other. The RAPD-PCR patterns also discriminate both groups of P. parasitica. However, they are very similar if strains of a single group are compared. Therefore, we propose that the determination of fungal species by molecular techniques should be vetted at least by morphological and physiological parameters and, whenever possible, by mating experiments.

Microbes in food processing technology

There is an increasing understanding that the microbial quality of a certain food is the result of a chain of events. It is clear that the microbial safety of food can only be guaranteed when the overall processing, including the production of raw materials, distribution and handling by the consumer are taken into consideration. Therefore, the microbiological quality assurance of foods is not only a matter of control, but also of a careful design of the total process chain. Food industry has now generally adapted quality assurance systems and is implementing the Hazard Analysis Critical Control Point (HACCP) concept. Rapid microbiological monitoring systems should be used in these cases. There is a need for rapid and simple microbiological tests which can be adapted to the technology and logistics of specific production processes. Traditional microbiological methods generally do not meet these high requirements. This paper discusses the tests, based on molecular biological principles, to detect and identify microbes in food-processing chains. Tests based on DNA technology are discussed, including in vitro DNA amplification like the polymerase chain reaction (PCR) method and identifications based on RFLP, RAPD and DNA fingerprinting analysis. PCR-based methodology can be used for the rapid detection of microbes in food manufacturing environments. In addition, DNA fingerprinting methods are suitable for investigating sources and routes of microbial contamination in the food cycle.

Oligonucleotide fingerprinting detects genetic diversity among Ascochyta rabiei isolates from a single chickpea field in Tunisia

Fifty isolates of Ascochyta rabiei (Pass.) Labr. were hierarchically sampled from four well-separated locations of a single chickpea field in Beja (Tunisia), and single-spored. DNA was isolated from in-vitro-grown mycelia, digested with HinfI or RsaI, and hybridized to a set of synthetic oligonucleotides complementary to simple repetitive sequences. According to the fingerprint patterns derived from the probes (CA)8, (CAA)5, (CAT)5 and (GATA)4, 12 different fungal haplotypes were found at various frequencies within the investigated field. Seven haplotypes were confined to one location only, four occurred at two, one at three, and none at all four locations. Most of the genetic variability originated from diversity within, rather than between, locations. In some cases, more than one haplotype was isolated from the same lesion of a single host plant. Genetic distances between isolates, as calculated from band-sharing data, varied between 0.05 and 0.22. Relatedness between the different haplotypes was evaluated by cluster analysis using UPGMA.

Fingerprinting reveals gamma-ray induced mutations in fungal DNA: implications for identification of patent strains of Trichoderma harzianum

We have analyzed different patent strains and gamma-ray induced mutants of Trichoderma harzianum by DNA fingerprinting and PCR fingerprinting (RAPD). Applying wild-type phage M13 DNA, with the oligonucleotides (CT)8 and (GTG)5 as probes for hybridization, as well as the oligonucleotides GGCATCGGCC, (GTG)5, (CAC)5 and the M13 sequence GAGGGTGGCGGTTCT as primers in PCR, we were able to obtain different and discriminative fingerprint patterns for all strains and mutants investigated. Irradiation of fungi led to mutations which resulted in new fingerprint patterns. Consequently, irradiation-induced mutants can be clearly distinguished from the original wild-type isolates by genomic fingerprinting which is of importance for the patent protection of fungal strains. Sequencing of the ITS-1 and ITS-2 regions of the rDNA gene complex revealed the same sequence for all mutant strains and the original wild-type strain.

Multilocus DNA fingerprinting and genetic relatedness in plants: a case study with banana and tomato

The technique of DNA fingerprinting is frequently used for studies of genetic diversity and relatedness in a wide range of organisms. In humans and animals, multilocus fingerprints are mainly applied to paternity and identity test cases, behavioral ecology, and the analysis of population structures. In plants and fungi, the frequent occurrence of "low-variability" fingerprint patterns additionally allows to use multilocus fingerprinting for studying taxonomical problems at an intraspecific level. In the present article, we (1) present an overview of such approaches in a series of plant species, (2) summarize our attempts to estimate genetic relationships within two cultivated plant species, banana and tomato, by band sharing data derived from oligonucleotide fingerprints, and (3) discuss the limitations and potentials of multilocus fingerprinting for the determination of genetic relatedness.

A simple, sensitive, and rapid method for detecting seed contaminated with highly virulent Leptosphaeria maculans

A primer-directed DNA amplification polymerase chain reaction assay for detection of seed contaminated with highly virulent Leptosphaeria maculans was developed. The primers were derived from a 5,238-bp repetitive sequence present only in the highly virulent isolates of the fungus. A procedure for isolating DNA from organisms infesting germinating seed was also developed. Seeds were added to liquid fungal minimal medium, and the culture was incubated for 3 days at room temperature with shaking. The organisms were collected from the cultures by centrifugation and lysed with a combination of sodium dodecyl sulfate and proteinase K. The DNA was extracted with organic solvents and with a high-salt-cetyltrimethylammonium bromide solution. It was also precipitated with a low-salt-cetyltrimethylammonium bromide solution. The extensive treatments used for minimizing polysaccharide contamination greatly improved the reliability of the assay. The minimum contamination level (2 of 1,000 seeds) that was tested was successfully detected with this DNA isolation procedure. The reliability of the assay was 96% at the 1 to 2% level of seed contamination. The described method is less laborious and requires only 4 to 5 days for completion in comparison to the 11 to 22 days required for the currently employed methods. In addition, large sample sizes can be easily handled, thus reducing the probability of contaminated seed escaping detection.

Identification of clinical strains of Candida albicans by DNA fingerprinting with the polymerase chain reaction

DNA polymorphisms generated by the polymerase chain reaction (PCR) were used to differentiate clinical isolates of Candida. This PCR method employed single primers that were originally designed as hybridization probes for DNA fingerprinting experiments to probe minisatellite and microsatellite DNA sequences. To evaluate this procedure, 35 isolates from 20 patients in several intensive care units and 12 isolates obtained from the oral cavities of healthy dental patients were fingerprinted. The PCR-fingerprint patterns of isolates of Candida albicans from the immunocompromised patients revealed fewer differences than isolates from the dental service. Multiple isolates from different body sites of the same patients revealed that patients may harbour isolates of Candida with the same or different PCR-fingerprints. Since this method is generally simpler and faster than established methods of biotyping medically important yeasts, PCR-fingerprinting may prove useful for the surveying of large numbers of pathogens for epidemiological studies.

DNA- and PCR-fingerprinting in fungi

DNA-fingerprinting has been successfully used to detect hypervariable, repetitive DNA sequences (minisatellites and microsatellites) in fungi. Combined with methods used to identify random amplified polymorphic DNA (RAPD), conventional DNA-fingerprinting hybridization probes can also be used as single primers to detect DNA polymorphisms among fungal species and strains. The oligonucleotides (CA)8, (CT)8, (CAC)5, (GTG)5, (GACA)4 and (GATA)4, as well as the phage M13 and its core sequence, have been used as specific probes in hybridization experiments and as primers for PCR analysis. Both methods have enabled the differentiation of all the fungal species and strains that were examined, including species of Penicillium, Trichoderma, Leptosphaeria, Saccharomyces, Candida and Cryptococcus. These methods have been used 1) to clarify the taxonomic relationships among relevant species of the Trichoderma aggregate, 2) to discriminate between aggressive and non-aggressive isolates of the rape seed phytopathogen, Leptosphaeria maculans, and 3) to identify strains of the pathogenic yeasts, Cryptococcus neoformans and Candida albicans. PCR-fingerprinting allowed serotypes of C. neoformans to be distinguished. The application of DNA- and PCR-fingerprinting to fungal DNA should aid in clarification of their taxonomy and improved diagnosis of mycotic disease.