Application of polymerase chain reaction with specific and arbitrary primers to identification and differentiation of Leishmania parasites

Abstract Two oligonucleotide primers Lsmc1 and Lsmv1 derived from the conserved and the variable region of a major class kinetoplast DNA (kDNA) minicircle (pLURkE3) of Leishmania strain UR6 were used for the polymerase chain reaction (PCR) in order to amplify a 461-bp fragment from the kDNAs of different Leishmania species. These primers amplify the specific fragment from the kDNAs of cutaneous species only. The cutaneous species can further be distinguished by randomly amplified polymorphic DNA (RAPD) analysis of the kDNAs of these organisms using arbitrarily chosen oligonucleotides. The arbitrary primers also generate polymorphic DNA fingerprints at the genomic level with different L. donovani isolates. The results indicate that the PCR and arbitrarily primed PCR (AP-PCR) may be extremely useful approaches for identifying and distinguishing Leishmania parasites.     

A microsatellite marker for studying the ecology and diversity of fungal endophytes (Epichloë spp.) in grasses.

Randomly amplified polymorphic DNA fingerprinting, which is based on PCR with arbitrary 10-nucleotide primers, were used to analyze genetic diversity among isolates of the endophytic ascomycete Epichloë typhina, which were collected at a single field site from a population of one of its hosts, the grass Bromus erectus. One of the polymorphic randomly amplified polymorphic DNA PCR products occurred in all isolates as single bands with different but closely related sizes. Two of the size variants of this product were cloned and sequenced, and they were found to represent the same DNA sequence, except for a stretch of tandem repeats of the trinucleotide AAG.TTC, which differed in size, consisting of 8 and 18 repeats, respectively. Tandem repeats of this type are called microsatellites. Oligonucleotides were synthesized corresponding to portions of the sequence flanking the microsatellite and were used for PCR amplification of the loci from the genomic DNAs of different Epichloë isolates. A single PCR product was found for most isolates, indicating that the sequence represented a single genetic locus. Five alleles that could clearly be distinguished in size were found in a population of 91 field isolates. PCR with (AAC)8 and (AAG)8 as primers yielded a number of amplified bands from genomic DNA of Epichloë isolates, indicating that these types of microsatellites occur frequently in the genome of this fungus. A survey of all fungal DNA sequences currently deposited in the DNA sequence databases of EMBL and GenBank revealed that microsatellites of different repeating units are widespread in fungi.(ABSTRACT TRUNCATED AT 250 WORDS)     

Strain-specific fingerprints of Rhizobium galegae generated by PCR with arbitrary and repetitive primers

Strain-specific genomic patterns of Rhizobium galegae were generated by PCR using both arbitrary and repetitive (BOX, ERIC and REP) primers. The identification of the strains was achieved also by RFLP analysis. However, the PCR genomic fingerprinting has significant advantages: it is not only simpler and faster, but it is also much more discriminative because it deals with the full bacterial genome and not only with parts of it as is the case with RFLP. In addition, both kinds of PCR fingerprinting (using arbitrary or repetitive primers) generated highly specific and reproducible patterns when parallel reactions with total bacterial DNA, extracted from independent liquid cultures were performed. The latter shows that AP- and rep-PCR are convenient for controlling the production and application of Rhizobium inoculants.     

Characterization of Rhizobium 'hedysari' by RFLP analysis of PCR amplified rDNA and by genomic PCR fingerprinting

The taxonomic and discriminatory power of RFLP analysis of PCR amplified parts of rhizobial rrn operons was compared to those of genomic PCR fingerprinting with arbitrary and repetitive primers. For this purpose, the two methods were applied for characterization of a group of bacterial isolates referred to as Rhizobium 'hedysari'. As outgroups, representatives of the family Rhizobiaceae, belonging to the Rhizobium galegae, Rhizobium meliloti, Rhizobium leguminosarum and Agrobacterium tumefaciens species were used. By the RFLP analysis of the PCR products corresponding to the variable 5'-half of the 23S rRNA gene and of the amplified spacer region between the 16S and 23S rRNA genes all Rh. 'hedysari' strains studied were tightly clustered together while the outgroups were placed in an outer position. The PCR products of the 3' end parts of the 23S rDNA did not show significant RFL polymorphism and no species differentiation on their basis was possible. In parallel, analysis of the same strains was performed by PCR amplification of their total DNA with 19, 18 and 10 bp long arbitrary primers (AP-PCR) as well as with single primers corresponding to several bacterial repetitive sequences (rep-PCR). By both AP and rep-PCR an identification of every particular strain was achieved. In general, all primers provided taxonomic results that are in agreement with the species and group assignments based on the RFLP analysis of the rrn operons. On the basis of the results presented here it can be concluded that AP and rcp-PCR are more informative and discriminative than rDNA and RFLP analysis of the rhizobial strains studied.     

Identification of Candida albicans by polymerase chain reaction amplification of CaYST1 gene intron fragment

A single pair of primers, deduced from the intron nucleotide sequence of the Candida albicans CaYST1 gene, was used in PCR analysis performed with both genomic DNA and whole cells of clinical isolates of Candida species and other microorganisms. All the clinical C. albicans isolates generated the expected 310 bp amplicon; other Candida species as well as laboratory strains belonging to other fungal genera failed to amplify any DNA fragment, except for Candida pseudotropicalis (amplicon of 1200 bp), Kluyveromices marxianus (amplicon of 1250 bp) and Cryptococcus neoformans (several amplicons longer than 1200 bp). Unusual C. albicans isolates from Africa also yielded the expected 310 bp amplicon. These results indicate that genes containing intron sequences may be useful to design species-specific primers for identification of fungal strains by PCR. The sensitivity of the method was evaluated for C. albicans genomic DNA by using both various DNA concentrations (224 ng to 2.7 pg) and different cell amounts (10(7); to 5 cells). The results obtained may be useful in earlier detection of candidiasis.     

Molecular characterization of Macrophomina phaseolina and Fusarium species by a single primer RAPD technique

Charcoal root rot and wilt, are two economically important diseases of many crop plants in North and South America, Asia and Africa and some parts of Europe. Genetic variation in 43 isolates of Macrophomina phaseolina and 22 isolates of Fusarium species, collected from geographically distinct regions over a range of hosts, was studied using random amplified polymorphic DNA (RAPD) markers. Initially, 210 arbitrary nucleotide (10-mer) primers were tested for amplification of genomic DNA of one M. phaseolina isolate, 70 primers amplified the genomic DNA of M. phaseolina. One primer OPA-13 (5'-CAGCACCCAC-3') produced fingerprint profiles, which clearly distinguished between the different isolates of M. phaseolina. UPGMA analysis classified these isolates into five major groups. By primer OPA-13, 22 isolates of pathogenic and non-pathogenic Fusarium species of different formae-speciales and races, were also distinguished from M. phaseolina. This marker is useful for distinguishing between these two important plant pathogens irrespective of hosts, virulence spectrum and races. This is the first report of reliable diagnosis of two soilborne pathogens (root/collar rot and wilt causing pathogens) at the level of isolates, formae-speciales and races by a single primer RAPD procedure with uniform PCR conditions.     

RAPD (arbitrary primer) PCR is more sensitive than multilocus enzyme electrophoresis for distinguishing related bacterial strains.

The RAPD (random amplified polymorphic DNA) fingerprinting method, which utilizes low stringency PCR amplification with single primers of arbitrary sequence to generate strain-specific arrays of anonymous DNA fragments, was calibrated relative to the widely used, protein-based multilocus enzyme electrophoretic (MLEE) typing method. RAPD fingerprinting was carried out on five isolates from each of 15 major groups of Escherichia coli strains that cause diarrheal disease worldwide (75 isolates in all). Each group consisted of isolates that were not distinguishable from one another by MLEE typing using 20 diagnostic enzyme markers. In our RAPD tests, three or more distinct subgroups in each MLEE group were distinguished with each of five primers, and 74 of the 75 isolates were distinguished when data obtained with five primers were combined. Thus, RAPD typing is far more sensitive than MLEE typing for discriminating among related strains of a species. Despite their different sensitivities, the same general relationships among strains were inferred from MLEE and RAPD data. Thus, our results recommend use of the RAPD method for studies of bacterial population genetic structure and evolution, as well as for epidemiology.     

Molecular typing of Histoplasma capsulatum isolated from infected bats, captured in Mexico

The present paper represents data on the genetic polymorphism of 13 Histoplasma capsulatum isolates recovered from infected bats randomly captured in the Mexican states of Morelos, Puebla, and Oaxaca. The polymorphic DNA patterns were analyzed by two-primer RAPD-PCR (random amplified polymorphic DNA-polymerase chain reaction) method. To amplify the fungal genome by PCR, the following primer arrangements were used: 5'-AACGCGCAAC-3' and 5'-AAGAGCCCGT-3'; 5'-AACGCGCAAC-3' and 5'-GTTTCCGCCC-3'; or 5'-AACGCGCAAC-3' and 5'-GCGATCCCCA-3'. A common polymorphic DNA pattern of H. capsulatum was revealed in different assays. This pattern is shared by 7 H. capsulatum isolates recovered from different specimens of nonmigratory bats (Artibeus hirsutus) captured in a cave in Morelos, by 5 isolates recovered from infected migratory bats (Leptonycteris nivalis) captured in Morelos and Puebla, and by 1 isolate from another migratory bat (L. curasoae) captured in Oaxaca. This polymorphic DNA pattern of H. capsulatum could represent fungal markers for the geographic areas studied, and considering its distribution in three different states of the Mexican Republic, the role of bats as responsible for H. capsulatum spreading in nature, in relation to their movements and migrations besides their shelter habits, is suggested. Analyses of DNA patterns of H. capsulatum isolated from infected bats, from clinical cases, and from blackbird excreta, have shown a major relatedness between bats and clinical isolates, in contrast to those isolates from bird excreta.     

Fingerprinting genomes by use of PCR with primers that encode protein motifs or contain sequences that regulate gene expression

PCR primers of arbitrary nucleotide sequence have identified DNA polymorphisms useful for genetic mapping in a large variety of organisms. Although technically very powerful, the use of arbitrary primers for genome mapping has the disadvantage of characterizing DNA sequences of unknown function. Thus, there is no reason to anticipate that DNA fragments amplified by use of arbitrary primers will be enriched for either transcribed or promoter sequences that may be conserved in evolution. For these reasons, we modified the arbitrarily primed PCR method by using oligonucleotide primers derived from conserved promoter elements and protein motifs. Twenty-nine of these primers were tested individually and in pairwise combinations for their ability to amplify genomic DNA from a variety of species including various inbred strains of laboratory mice and Mus spretus. Using recombinant inbred strains of mice, we determined the chromosomal location of 27 polymorphic fragments in the mouse genome. The results demonstrated that motif sequence-tagged PCR products are reliable markers for mapping the mouse genome and that motif primers can also be used for genomic fingerprinting of many divergent species.     

A polymerase chain reaction-based test for Verticillium fungicola causing dry bubble disease on the cultivated mushroom,Agaricus bisporus

A polymerase chain reaction (PCR)-based test is described for the specific detection of Verticillium fungicola var. aleophilum (Vfa), the fungal pathogen causing dry bubble disease on the cultivated button mushroom, Agaricus bisporus. PCR primers were tailored to target a 162-bp arbitrary sequence in the Vfa genome. In PCR amplifications using the primer pair, all of 20 isolates of Vfa that had been collected during a 29-year period at commercial mushroom operations located primarily in North America were found to generate the diagnostic 162-bp DNA product. Conversely, the primers failed to produce the specific amplicon with DNA from isolates representing 5 other species of Verticillium, the pathogenic subspecies V. fungicola var. fungicola from Europe, and 12 other fungal species commonly inhabiting mushroom compost. A protocol was designed enabling a confirmed diagnosis of dry bubble disease in less than 3 h. The PCR-based test should find application for the rapid diagnosis and detection of the fungal pathogen in disease management programs and, potentially, in screening for on-the-farm sources of infection.     

Quick and accurate detection of <Emphasis Type="Italic">Fusarium oxysporum</Emphasis> f. sp. <Emphasis Type="Italic">carthami</Emphasis> in host tissue and soil using conventional and real-time PCR assay

Safflower wilt, caused by Fusarium oxysporum f. sp. carthami (Foc) is a major limiting factor for safflower (Carthamus tinctorius) production worldwide. In India alone, about 40–80% disease incidence has been reported. A rapid, efficient, specific, and sensitive diagnostic technique for Foc is therefore crucial to manage Fusarium wilt of safflower. Twenty-five isolates of F. oxysporum formae speciales infecting other crops, 17 isolates of Fusarium spp. and seven isolates of other fungal pathogens of safflower along with 75 Foc isolates were used for identification of band specific to Foc using inter-simple sequence repeat (ISSR) analysis. Out of 70 ISSR primers, the one that specifically amplified a 490 bp fragment from all the Foc isolates was selected. Sequence of the amplified fragment was utilized to design sequence characterized amplified region (SCAR) primers (FocScF/FocScR). The primer pair unambiguously and exclusively amplified a DNA fragment of approximately 213 bp in all the 75 Foc isolates. The primer set was able to detect as low as 10 pg of Foc genomic DNA using conventional PCR, while the SCAR primers when coupled with real-time qPCR demonstrated detection limits of 1 pg for Foc genomic DNA and 1000 conidia/g for soil. The assay enabled reliable diagnosis of Foc DNA in contaminated safflower fields and expedited Foc detection at 72 h post inoculation in asymptomatic seedlings. This method facilitates quick and precise detection of Foc in plant and soil samples and can be exploited for timely surveillance and sustainable management of the disease.     

Identification of pathogenic yeast species by polymerase chain reaction amplification of the RPS0 gene intron fragment

Aims: This work focuses on the development of a method for the identification of pathogenic yeast. With this aim, we target the nucleotide sequence of the RPS0 gene of pathogenic yeast species with specific PCR primers. PCR analysis was performed with both the genomic DNA, whole cells of clinical isolates of Candida species and clinical samples. Methods and Results: A single pairs of primers, deduced from the nucleotide sequence of the RPS0 gene from pathogenic yeast, were used in PCR analysis performed with both the genomic DNA and whole cells of clinical isolates of Candida species and clinical samples. The primers designed are highly specific for their respective species and produce amplicons of the expected sizes and fail to amplify any DNA fragment from the other species tested. The set of primers was tested successfully for the identification of yeast from colonies, blood cultures and clinical samples. These results indicate that genes containing intron sequences may be useful for designing species‐specific primers for the identification of fungal strains by PCR. The sensitivity of the method with genomic DNA was evaluated with decreasing DNA concentrations (200 ng to 1 pg) and different cell amounts (10⁷–10⁵ cells). Conclusion: The results obtained show that the amplification of RPS0 sequences may be suitable for the identification of pathogenic and other yeast species. Significance and Impact of the Study: Identification of Candida species using molecular approaches with high discriminatory power is important in determining adequate measures for the interruption of transmission of this yeast. The approach described in this work is based on standard technology, and it is specific, sensitive and does not involve complex and expensive equipment. Furthermore, the method developed in this work not only can be used in eight yeast species, but also provides the basis to design primers for other fungi species of clinical, industrial or environmental interest.     

Genetic similarity among Cercospora apii-group species and their detection in host plant tissue by PCR/RFLP analyses of the rDNA internal transcribed spacer (ITS)

The objective of this study was to determine the genetic relatedness among the Cercospora and Pseudocercospora species closely related to Cercospora apii by using a polymerase chain reaction/restriction fragment length polymorphism (PCR/RFLP) analysis of the internal transcribed spacer (ITS) region. A single PCR fragment (about 550 bp) was obtained from all Cercospora species categorized as the C. apii-group, Pseudocercospora purpurea, Pseudocercospora conyzae, and Pseudocercospora cavarae. Cercospora caricis yielded a 680 bp PCR fragment. The similarity in the PCR fragment size and RFLP profiles among the C. apii-group isolates, including Pseudocercospora purpurea, and Pseudocercospora conyzae strongly suggests that these species are conspecific. Synonymy with C. apii (lectotype) at a subspecific rank has been proposed. Amplified ITS regions of genomic DNA extracted from spinach leaves showing 12 and 233% leaf spot disease symptoms caused by Cercospora beticola yielded two PCR fragments (i.e., one from the fungus and one from the host plant) and were resolved by electrophoresis of the PCR product in 3% LMP agarose. Digestion of the total PCR product with HinfI restriction enzyme yielded RFLP profiles similar to those obtained from amplified DNA from the causative agent, C. beticola. The method described in this preliminary study offers rapid detection and diagnosis of fungal infections in plants for disease prediction and management and screening of plant materials for quarantine purposes.     

PCR assay based on a microsatellite-containing locus for detection and quantification of Epichloë endophytes in grass tissue.

A PCR assay which allows detection and quantification of Epichloë endophytes in tissues of the grass Bromus erectus is described. PCR with specific primers flanking a microsatellite-containing locus (MS primers) amplified fragments 300 to 400 bp in length from as little as 1.0 pg of fungal genomic DNA in 100 ng of DNA from infected plant material. When annealing temperatures were optimized, all Epichloë and Acremonium strains tested, representing many of the known taxonomic groups, yielded an amplification product, indicating that the MS primers may be useful for in planta detection of a variety of related species, including agronomically important Acremonium coenophialum and Acremonium lolii. No fragments were generated from DNA isolates from uninfected plant material or from unrelated fungi isolated from B. erectus. For diagnostic applications, a B. erectus-specific primer pair was designed for use in multiplex PCR to allow simultaneous amplification of plant and fungal DNA sequences, providing an internal control for PCR failure caused by inhibitory plant compounds present in DNA extracts. For quantitative applications, a heterologous control template in primer binding sites complementary to the MS primers was constructed for use in competitive PCR, allowing direct quantification of Epichloë in plant DNA extracts. The fungal DNA present in infected leaves of B. erectus between 1 and 20 pg per 100 ng of leaf DNA, but the amounts of fungal DNA present in the sheath and blade of a given leaf were correlated, indicating that the degree of infection varied between plant individuals but that leaves were colonized in a uniform way.     

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.     

Development of specific PCR primers for the detection of Rhizoctonia solani AG 2-2 LP from the leaf sheaths exhibiting large-patch symptom on zoysia grass

Detection of Rhizoctonia solani AG 2-2 LP isolates causing large-patch disease on zoysia grass was done using polymerase chain reaction (PCR). Specific primers were designed based on an amplified region using random amplified polymorphic DNA (RAPD)-PCR. Fifteen primers and three cultural types of R. solani AG 2-2 (types IIIB, IV and LP) were used for RAPD-PCR. The banding patterns by RAPD-PCR showed that the three cultural types were clearly distinguishable. A dendrogram constructed from the results of RAPD-PCR showed that the three cultural types of AG 2-2 clustered separately. The sequence of one PCR-amplified region which appeared only in LP isolates using primer A09 was selected for designing specific primers. Primer pair A091-F/R gave a single product from pure fungal DNA of LP isolates but not from those of the other two types (IIIB and IV), R. solani AG 1, 2-1, 2-3, 2-tulip, 3-10 and BI isolates and other turfgrass fungal pathogens. Primer pair A091-F/R also gave a single product from diseased leaf sheaths and this product was in accordance with those of pure fungal DNA of LP isolates. Primer pair A091-F/R did not yield PCR product from healthy leaf sheaths. The frequencies of detection of LP isolates from leaf sheaths of zoysia grass using PCR with primer pair A091-F/R were higher than those of the conventional isolation technique. These results showed that the PCR-based technique using specific primers A091-F/R is useful for the rapid detection of LP isolates from leaf sheaths of zoysia grass exhibiting large-patch symptoms.     

Detection of Genetic Variation in Alternaria brassicae by RAPD Fingerprints

Genetic variation in fourteen isolates of Alternaria brassicae collected from different geographical regions of the world was determined by RAPD (random amplified polymorphic DNA) analysis. Twenty random primers were tried to amplify genomic DNA of A. brassicae. Based on the PCR (polymerase chain reaction) amplification of genomic DNA of A. brassicae with four oligonucleotide random primers, fingerprints were generated for each isolate and the amplifed products were compared. Using this technique, intra- and intercontinental genetic variation among isolates of A. brassicae could be distinguished.     

RFLP analysis of cry1 and cry2 genes of Bacillus thuringiensis isolates from India

The PCR-RFLP method has been useful for detection of known genes and identification of novel genes. In the present study, degenerate primers were designed from five groups of cry1 genes for PCR-RFLP analysis. Bacillus thuringiensis (Bt) isolates from different regions were evaluated for PCR amplification of various cry1 genes using newly designed primers and cry2 genes using reported primers. PCR analysis showed an abundance of cry1A genes and especially cry1Ac genes in isolates from all regions. RFLP analysis revealed the presence of multiple cry1A genes in isolates from central and southern regions. Unique digestion patterns of cry1A genes were observed in isolates from each region. Few of the isolates represented a digestion pattern of cry1A genes that did match to any of the known cry1A genes. RFLP analysis suggested an abundance of cry2Ab along with a novel cry2 gene in Bt isolates from different regions of India. Sequence analysis of the novel cry2 gene revealed 95% sequence identity to cry2Ab and cry2Ah genes. Phylogenetic analysis revealed that the novel cry2 gene could have diverged earlier than the other cry2 genes. Our results encourage finding of more diverse cry2 genes in Bt isolates. Rarefaction analysis was used to compare cry1A gene diversity in isolates from different soil types. It showed a higher degree of cry1A gene diversity in isolates from central region. In the present study, we propose the use of novel degenerate primers for cry1 genes and the PCR-RFLP method using a single enzyme to distinguish multiple cry1A and cry2 genes as well as identify novel genes.