Patterns of evolution in Discula fungi and the origin of dogwood anthracnose in North America, studied using arbitrarily amplified and ribosomal DNA.

The anthracnose epidemic caused by exotic filamentous fungi of the genus Discula threatens the future of the prized flowering (Cornus florida L.) and Pacific (C. nuttalli Aud.) dogwoods in North America. A cross-section of fungi that cause anthracnose in broadleaf temperate trees was characterized using DNA amplification fingerprinting, sequence and secondary structure analysis of the internal transcribed spacers (ITS) of nuclear ribosomal DNA (rDNA), and compatibility of hyphal anastomosis. ITS-inferred phylogenies rejected the null hypothesis of only one fungal lineage, by defining four monophyletic and well differentiated groups, corresponding to Discula sp., D. quercina, D. umbrinella and D. destructiva, with the last two species sharing a common and recent ancestor. In turn, they showed that the dogwood pathogen, D. destructiva, did not evolve directly from an indigenous population related to Discula sp. In this study, rDNA spacers that are generally considered important for protein synthesis but are selectively neutral, appeared functionally constrained and subject to selective sequence diversification. Results confirmed the high variability of D. umbrinella and the remarkable homogeneity and exotic nature of D. destructiva at the genetic level, clarified the taxonomy and phylogeny of Discula, and provided clues as to the origin and diversification of dogwood anthracnose-causing fungi.

DAF optimization using Taguchi methods and the effect of thermal cycling parameters on DNA amplification.

Taguchi methods, which are widely applied in industrial process design, were used to optimize DNA amplification finger-printing (DAF). Quadratic loss functions that penalize deviations from prediction values and L9 (3(4)) and L18 (3(8)) orthogonal arrays revealed effects and interactions of amplification reaction components and thermal cycling parameters. Analysis of variance (ANOVA) decomposed the contribution of individual factors to the experimental response (amplification yield and product number), while verification experiments established that optimum conditions were predictable, verifiable and reproducible. While several amplification components (primer, magnesium and enzyme) conditioned the amplification reaction, annealing temperature and time were the only important thermal cycling contributing factors. The Taguchi strategy defined a robust and transportable amplification protocol based on high annealing temperatures (typically 48 degrees C) and primer concentrations (typically 8 microM), which can be applied to the fingerprinting of a wide range of DNA templates of plant and fungal origin. The general strategy of robust experimental design holds potential as an optimization tool for other methods in molecular biology.

Sequence signatures from DNA amplification fingerprints reveal fine population structure of the dogwood pathogen Discula destructiva.

Isolates of Discula destructiva Redlin and an undescribed species of Discula, the filamentous fungi that cause anthracnose of flowering (Cornus florida L.) and Pacific (Cornus nuttalli Aud.) dogwoods, were analyzed for genetic variation by nucleic acid scanning with arbitrary mini-hairpin oligonucleotide primers. While the fungal population was highly homogeneous throughout the disease range in eastern and western North America, the generation of arbitrary signatures from amplification profiles (ASAP) distinguished isolates from the northeast, middle and southern Appalachian mountain range, and western United States and Canada. ASAP involves a dual-step arbitrary primer-based amplification procedure that generates a large number of informative allelic characters by amplification of monomorphic DNA fingerprints. ASAP analyses showed a fine fungal population structure consistent with the recent and separate introduction of the pathogen on the west and east coasts of North America.

Nucleic acid scanning-by-hybridization of enterohemorrhagic Escherichia coli isolates using oligodeoxynucleotide arrays.

Nucleic acid scanning by hybridization (NASBH) is a non-electrophoretic typing strategy that uses gridded oligonucleotides to reproducibly characterize arbitrarily amplified nucleic acid sequences. Membrane-bound arrays of terminally-degenerate oligonucleotides were hybridized to DNA amplification fingerprinting (DAF) products from enterohemorrhagic Escherichia coli O157:H7 isolates. Numerical and cluster analysis of 64 isolates, selected by DAF to represent a single dominant amplification type identified 14 hybridization types. Results show that NASBH is a powerful alternative for the identification of closely related bacteria, can be used successfully in epidemiological studies, and holds potential in general nucleic acid diagnostics.

Scanning of nucleic acids by in vitro amplification: new developments and applications.

Nucleic acids can be characterized using a variety of "fingerprinting" techniques usually based on nucleic acid hybridization or enzymatic amplification. The scanning of nucleic acids by amplification with arbitrary oligonucleotide primers has become popular because it can generate simple-to-complex patterns from anonymous DNA or RNA templates without requiring prior knowledge of nucleic acid sequence or cloned or characterized probes. Discrete loci are amplified within genomic DNA, DNA complementary to mRNA populations (cDNA), cloned DNA fragments, and even PCR products. The potential and limitations of the various genome scanning techniques, novel improvements, and their recent use in comparative and experimental biology applications, including the analysis of plant and bacterial genomes are discussed.

Generation of sequence signatures from DNA amplification fingerprints with mini-hairpin and microsatellite primers.

DNA amplification fingerprinting (DAF) with mini-hairpins harboring arbitrary "core" sequences at their 3' termini were used to fingerprint a variety of templates, including PCR products and whole genomes, to establish genetic relationships between plant tax at the interspecific and intraspecific level, and to identify closely related fungal isolates and plant accessions. No correlation was observed between the sequence of the arbitrary core, the stability of the mini-hairpin structure and DAF efficiency. Mini-hairpin primers with short arbitrary cores and primers complementary to simple sequence repeats present in microsatellites were also used to generate arbitrary signatures from amplification profiles (ASAP). The ASAP strategy is a dual-step amplification procedure that uses at least one primer in each fingerprinting stage. ASAP was able to reproducibly amplify DAF products (representing about 10-15 kb of sequence) following careful optimization of amplification parameters such as primer and template concentration. Avoidance of primer sequences partially complementary to DAF product termini was necessary in order to produce distinct fingerprints. This allowed the combinatorial use of oligomers in nucleic acid screening, with numerous ASAP fingerprinting reactions based on a limited number of primer sequences. Mini-hairpin primers and ASAP analysis significantly increased detection of polymorphic DNA, separating closely related bermudagrass (Cynodon) cultivars and detecting putatively linked markers in bulked segregant analysis of the soybean (Glycine max) supernodulation (nitrate-tolerant symbiosis) locus.

Molecular phylogeny and DNA amplification fingerprinting of Petunia taxa.

The relationship of five species of Petunia and ten cultivars of the cultivated petunia, Petunia x hybrida, were investigated using DNA-amplification fingerprinting (DAF). Reproducible banding profiles were obtained from P. parodii and P. axillaris DNA from different seed sources. In contrast, other petunias such as P. inflata, P. violacea and P. integrifolia produced variable fingerprints when different plants were examined. However, representative profiles of the variable Petunia taxa were obtained by bulking the leaf tissue from ten different individual plants. Each of ten octamer primers revealed polymorphic loci between taxa. Among a total of 201 bands produced, 146 (73%) loci were polymorphic and distinguished all species and cultivars. Phenetic and cluster analysis using DAF markers separated P. axillaris from P. parodii and distinguished between the violet-flowered species, P. inflata, P. violacea, and P. integrifolia. P. parodii grouped together with the monophyletic set of the ten cultivars of P. x hybrida examined, indicating that it had made a major contribution to the development of these cultivars. Cultivars were distributed within the dendograms by flower color. The results demonstrated the utility of DAF in establishing relationships among closely related species and cultivars of Petunia.

DNA amplification fingerprinting analysis of bermudagrass (Cynodon): genetic relationships between species and interspecific crosses.

We have used DNA amplification fingerprinting (DAF) to study the genetic variation of bermudagrass (Cynodon) species and cultivars of interspecific crosses that exhibit leaf-blade textural characteristics ranging from coarse to fine. Arbitrary octamer primers produced complex and reproducible amplification profiles with high levels of polymorphic DNA. Phylogenetic analysis using parsimony (PAUP) and unweighted pair group cluster analysis using arithmetic means (UPGMA) grouped 13 bermudagrass cultivars into several clusters, including one containing the African-type bermudagrasses (C. transvaalensis) and another containing the common-type bermudagrasses (C. dactylon). The latter group included C. magennissii ('Sunturf') and a interspecific C. transvaalensisxC. dactylon cross ('Midiron'), 2 cultivars that exhibited leaf textural characteristics closer to the common-types. All other C. transvaalensisxC. dactylon crosses grouped between the African and common types. An extended screen of 81 octamer primers was needed to separate cultivar 'Tifway' from the irradiation-induced mutant 'Tifway II'. The use of either template endonuclease digestion prior to amplification or arbitrary mini-hairpin primers increased detection of polymorphic DNA and simplified the task of distinguishing these closely related cultivars. Alternatively, the use of capillary electrophoresis (CE) resolved fingerprints adequately and detected products with high sensitivity, thereby promising to increase throughput and the detection of polymorphic DNA. When used to fingerprint samples from commercial sources, DAF identified bermudagrass plant material on the basis of unique reference profiles generated with selected primers. DAF represents an excellent technique for bermudagrass cultivar verification, seed certification, varietal protection, and for the identification of mistakes in plantings, mislabeled plant materials, and contamination or substitutions of sod fields.

MAAP: a versatile and universal tool for genome analysis.

Multiple arbitrary amplicon profiling (MAAP) uses one or more oligonucleotide primers (> or = 5 nt) of arbitrary sequence to initiate DNA amplification and generate characteristic fingerprints from anonymous genomes or DNA templates. MAAP markers can be used in general fingerprinting as well as in mapping applications, either directly or as sequence-characterized amplified regions (SCARs). MAAP profiles can be tailored in the number of monomorphic and/or polymorphic products. For example, multiple endonuclease digestion of template DNA or the use of mini-hairpin primers can enhance detection of polymorphic DNA. Comparison of the expected and actual number of amplification products produced with primers differing in length, sequence and GC content from templates of varying complexity reveal severe departures from theoretical formulations with interesting implications in primer-template interaction. Extensive primer-template mismatching can occur when using templates of low complexity or long primers. Primer annealing and extension appears directed by an 8 nt 3'-terminal primer domain, requires sites with perfect homology to the first 5-6 nt fom the 3' terminus, and involves direct physical interaction between amplicon annealing sites.

DNA amplification fingerprinting using arbitrary mini-hairpin oligonucleotide primers.

The enzymatic amplification of DNA directed by very short oligonucleotides of arbitrary sequence produces complex DNA profiles useful for genome analysis and identity testing. Mini-hairpins harboring a "core" arbitrary sequence at the 3' terminus primed the amplification of a wide range of templates ranging from plasmid DNA to plant and animal genomes. Primer core regions of only 3 nucleotides produced complex fingerprints, but the hairpin sequence also influenced the amplification reaction. Oligonucleotide substitution with degenerate bases tailored the complexity of fingerprint patterns. Simulation studies of the amplification of plasmids pUC18 and pBR322 using primers with short arbitrary cores allowed assignment of amplification products to expected regions and revealed physical interaction between annealing sites during amplification of first-round products. Mini-hairpin primers can increase detection of polymorphic DNA, and be used to study subgenomic fragments like yeast artificial chromosomes (YACs), cloned DNA and PCR products.

Kinetics of Nodule Development in Glycine soja.

Nodule development in the interaction of Glycine soja Sieb. & Zucc. PI468.397 with Bradyrhizobium japonicum USDA110 was studied by hypochlorite clearing and methylene blue staining. Even the earliest stages of nodule development could be observed. The entire length of the primary root was examined up to 15 d postinoculation. Markedly curled root hairs and the first cell divisions in the hypodermal layer (stage I) were observed 2 d postinoculation, and by 3 d cell division activity had spread to the outer layers of the cortex (stage II). Cortical cell division centers not associated with curled root hairs, frequently observed in soybean (Glycine max [L.] Merr.), were very rare in G. soja. The cortical cell division centers that had developed a well-defined nodule meristem (at or beyond stage IV) by 6 d postinoculation continued to develop, but the less-advanced stages became arrested. Almost all nodules developed near the position of the root tip at the time of inoculation. In the parts of the root that developed after inoculation, regions with a high density of markedly curled root hairs per root length were observed. The percentage of the curled root hairs associated with cortical cell division centers, however, declined with each successive peak. Regulation of nodule development in G. soja was similar to that previously reported in soybean, although the rate of nodule development was slower.

Enhanced detection of polymorphic DNA by multiple arbitrary amplicon profiling of endonuclease-digested DNA: identification of markers tightly linked to the supernodulation locus in soybean.

Multiple endonuclease digestion of template DNA or amplification products can increase significantly the detection of polymorphic DNA in fingerprints generated by multiple arbitrary amplicon profiling (MAAP). This coupling of endonuclease cleavage and amplification of arbitrary stretches of DNA, directed by short oligonucleotide primers, readily allowed distinction of closely related fungal and bacterial isolates and plant cultivars. MAAP analysis of cleaved template DNA enabled the identification of molecular markers linked to a developmental locus of soybean (Glycine max L. Merrill). Ethyl methane sulfonate (EMS)-induced supernodulating, near-isogenic lines altered in the nts locus, which controls nodule formation, could be distinguished from each other and from the parent cultivar by amplification of template pre-digested with 2-3 restriction enzymes. A total of 42 DNA polymorphisms were detected using only 19 octamer primers. In the absence of digestion, 25 primers failed to differentiate these soybean genotypes. Several polymorphic products co-segregated tightly with the nts locus in F2 families from crosses between the allelic mutants nts382 and nts1007 and the ancestral G. soja Sieb. & Succ. PI468.397. Our results suggest that EMS is capable of inducing extensive DNA alterations, probably around discrete mutational hot-spots. EMS-induced DNA polymorphisms may constitute sequence-tagged markers diagnostic of specific genomic regions.

DNA amplification fingerprinting using arbitrary oligonucleotide primers.

DNA amplification fingerprinting (DAF) is a strategy for genetic typing and mapping that uses one or more very short (> or = 5 nt) arbitrary oligonucleotides to direct the enzymatic amplification of discrete portions of a DNA template resulting in a spectrum of products characteristic of the DNA starting material. Polymorphisms from simple banding patterns are useful as genetic markers while more complex and informative patterns are suitable for DNA fingerprinting. The use of polyacrylamide gel electrophoresis and silver staining can adequately resolve the spectrum of DAF products into detailed and reproducible patterns.

DNA amplification fingerprinting of the Azolla-Anabaena symbiosis.

The Azolla-Anabaena symbiosis has been used for centuries as a nitrogen biofertilizer in rice paddies. Genetic improvement of the symbiosis has been limited by the difficulty in identifying Azolla-Anabaena accessions and Anabaena azollae strains. The recently developed technique of DNA amplification fingerprinting (DAF) was applied to this problem. DAF uses single, short, oligonucleotide primers of arbitrary sequence to direct amplification of a characteristic set of DNA products by a thermostable DNA polymerase in a thermocycling reaction. The products are separated in polyacrylamide gels and detected by silver staining. DAF could easily distinguish and positively identify accessions of Azolla-Anabaena with DNA extracted from the intact symbiosis. The contribution of prokaryotic Anabaena sequences to the fingerprint of the intact symbiosis, however, ranged from 0 to 77%, depending on the primer sequence. Therefore, DNA extracted from the intact symbiosis would not be suitable for Azolla taxonomy studies. The fingerprints of Anabaena strains isolated by sucrose gradient centrifugation from different species of Azolla could be easily distinguished, and DAF patterns were used to confirm the maternal pattern of transmission of Anabaena in a sexual hybrid. Template DNA extracted from roots was used to produce fingerprints for Azolla without interference from the microsymbiont. Comparison of the patterns from the parents and a hybrid gave strong evidence confirming sexual hybridization.

Primer-template interactions during DNA amplification fingerprinting with single arbitrary oligonucleotides.

DNA amplification fingerprinting (DAF) is the enzymatic amplification of arbitrary stretches of DNA which is directed by very short oligonucleotide primers of arbitrary sequence to generate complex but characteristic DNA fingerprints. To determine the contribution of primer sequence and length to the fingerprint pattern and the effect of primer-template mismatches, DNA was amplified from several sources using sequence-related primers. Primers of varying length, constructed by removing nucleotides from the 5' terminus, produced unique patterns only when primers were 8 nucleotides or fewer in length. Larger primers produced either identical or related fingerprints, depending on the sequence. Single base changes within this first 8-nucleotide region of the primer significantly altered the spectrum of amplification products, especially at the 3' terminus. Increasing annealing temperatures from 15 degrees to 70 degrees C during amplification did not shift the boundary of the 8-nucleotide region, but reduced the amplification ability of shorter primers. Our observations define a 3'-terminal oligonucleotide domain that is at least 8 bases in length and largely conditions amplification, but that is modulated by sequences beyond it. Our results indicate that only a fraction of template annealing sites are efficiently amplified during DAF. A model is proposed in which a single primer preferentially amplifies certain products due to competition for annealing sites between primer and terminal hairpin loop structures of the template.