A specific primer pair for the diagnosis and identification of Acanthamoeba astronyxis by random amplified polymorphic DNA-polymerase chain reaction

Random amplified polymorphic DNA (RAPD) is a useful tool for species identification. The obtained band patterns can be used for specific primer pair design that is useful for species identification. In this study, a distinctive 485-bp band in Acanthamoeba astronyxis band patterns was found, using the OPC20 primer (ACTTCGCCAC). The band specificity was confirmed by hybridization, using it as a probe, against all OPC20 amplifications from different Acanthamoeba species. Once the fragment was sequenced, we used it to design a specific primer pair that was useful for the identification of different isolates as A. astronyxis species.     

Evaluation of suitable DNA regions for molecular identification of high value medicinal plants in genus Kaempferia

DNA barcoding coupled high resolution melting (Bar-HRM) is an emerging method for species discrimination based on DNA dissociation kinetics. The aim of this work was to evaluate the suitability of different primer sets, derived from selected DNA regions, for Bar-HRM analysis of species in Kaempferia (Zingiberaceae). Four primer pairs were evaluated (rbcL, rpoC, trnL and ITS1). It was observed that the ITS1 barcode was the most useful DNA barcoding region overall for species discrimination out of all of the regions and primers assessed. Thus, the primer pair derived from the ITS1 region was the single most effective region for the identification of the tested species, whereas the rbcL primer pair gave the lowest resolution. Our Bar-HRM developed here would not only be useful for identification of Kaempferia plant specimens lacking essential parts for morphological identification but will be useful for authenticating products in powdered form of a high value medicinal species Kaempferia parviflora, in particular.     

Random amplified polymorphic DNA profiles as a tool for the identification of Acanthamoeba divionensis

In the present study, we demonstrated the Random Amplified Polymorphism DNA (RAPD) diagnostic validity. In our study, we have analyzed RAPD profiles searching for characteristic and useful bands for Acanthamoeba diagnosis at the species level. We found a distinctive 370-bp band in A. divionensis RAPD patterns, using the OPC14 primer (TGCGTGCTTG) (Operon Technologies, Inc., Alameda, CA). The band specificity was confirmed by hybridization, using it as a probe, against all OPC14 amplifications from 10 different Acanthamoeba species. Once we sequenced this band, we used it to design a specific primer pair which showed positive amplification only in A. divionensis isolates.     

Specific Detection and Identification of <Emphasis Type="Italic">Xylella fastidiosa</Emphasis> Strains Causing Oleander Leaf Scorch Using Polymerase Chain Reaction

A pair of PCR primers, QH-OLS05/QH-OLS08 specific for strains of Xylella fastidiosa causing oleander leaf scorch was developed. The primers were designed according to a DNA sequence of a randomly amplified polymorphic DNA (RAPD)-polymerase chain reaction (PCR) product unique to oleander strains. The PCR assay using primer pair QH-OLS05/QH-OLS08 allowed quick and simple detection and identification of oleander strains in cultured bacterium and infected plant samples. The assay also can be applied to insect samples. Specific detection and identification of oleander strains of X. fastidiosa by PCR is useful for epidemiologic and etiologic studies of oleander leaf scorch by identifying what plants and insect vectors harbor or carry this particular strain of X. fastidiosa, especially in locations where mixed natural infections by oleander and other strains of X. fastidiosa occur.     

Identification of <Emphasis Type="Italic">Ganoderma</Emphasis>, the causal agent of basal stem rot disease in oil palm using a molecular method

From comparison of the alignments of the internally transcribed spacers (ITS) of ribosomal DNA from Ganoderma associated with oil palm basal stem rot (BSR) and other Ganoderma species, two specific primer pairs were selected to provide a specific DNA amplification of pathogenic Ganoderma in oil palm. Each primer pair produced a single PCR product of about 450 bp (for primer pair IT1–IT2) and 334 bp (for primer pair IT1–IT3) when oil palm Ganoderma DNA was used. No PCR amplification product was observed when other Ganoderma species DNA was used in PCR amplification with these primer pairs. Three specific restriction enzyme sites were identified in the ITS and intergenic spacer (IGS1) regions. The restriction enzymes MluI, SacI and HinfI were used to digest the ITS-PCR product and restriction enzymes TfiI, ScaI and HincII were used to digest the IGS1-PCR product. Of the three restriction enzymes used in each rDNA region, MluI specifically digested the ITS regions, and TfiI specifically digested the IGS1 region of oil palm Ganoderma. Analysis of the published ITS nucleotide sequences of 31 Ganoderma species showed that the MluI restriction site was not present in other Ganoderma species. The use of both specific primers and restriction enzyme analysis can be applied as a standard protocol to identify pathogenic Ganoderma in oil palm. In this study, the use of specific primers and PCR-RFLP analyses of the rDNA gave consistent results for the characterisation of pathogenic Ganoderma, and indicated that Ganoderma strains associated with BSR disease in oil palms belong to a single species.     

Development of a SCAR marker and a strain‐specific genomic marker for the detection of the biocontrol agent strain CPA‐8 Bacillus amyloliquefaciens (formerly B. subtilis)

In this work, reliable tools were developed to detect and identify the biocontrol strain CPA‐8 using DNA amplification techniques. As a first approach, the RAPD (random amplified polymorphic DNA) technique was applied to a collection of 77 related Bacillus species. Among the primers tested, the primer pair OPG1/OPG6 amplified a 668 bp specific product to the strain CPA‐8 that was sequenced and used to design SCAR (sequence‐characterised amplified regions) primer pairs. The SCAR‐4 marker amplified a semi‐specific fragment of 665 bp not only for the strain CPA‐8 but also for other 12 strains whose morphology was completely different from CPA‐8. Another approach was developed to obtain a strain‐specific genomic marker related to ecological adaptations of Bacillus amyloliquefaciens species. The primer pair F2/R2 obtained from RBAM 007760, a gene involved in surface adhesion, amplified a 265 bp fragment unique for strain CPA‐8. Our results revealed that these two molecular markers, SCAR‐4 and RBAM 007760 F2/R2 provide suitable monitoring tools to specifically identify the biocontrol CPA‐8 when applied against brown rot caused by Monilinia spp. in stone fruit. Moreover, our findings demonstrate that the strain CPA‐8 is affiliated with B. amyloliquefaciens species that was formerly designated as Bacillus subtilis.     

Identification ofporphyra lines (rhodophyta) by AFLP DNA fingerprinting and molecular markers

Twenty-sevenPorphyra lines from 5 classes, including lines widely used in China, wild lines, and lines introduced to China from abroad in recent years, were screened by means of amplified fragment length polymorphism (AFLP) with 24 primer pairs. From the generated AFLP products, 13 bands that showed stable and repeatable AFLP patterns amplified by primer pairs M-CGA/E-AA and M-CGA/E-TA were scored and used to develop the DNA fingerprints of the 27Porphyra lines. Moreover, the DNA fingerprinting patterns were converted into computer language expressed with digitals 1 and 0, which represented the presence (numbered as 1) or absence (numbered as 0) of the corresponding band. On the basis of these results, computerized AFLP DNA fingerprints were constructed in which each of the 27Porphyra lines has its unique AFLP fingerprinting pattern and can be easily distinguished from others. Software called PGI-AFLP (Porphyra germ-plasm identification-AFLP) was designed for identification of the 27Porphyra lines. In addition, 21 specific AFLP markers from 15Porphyra lines were identified; 6 AFLP markers from 4Porphyra lines were sequenced, and 2 of them were successfully converted into SCAR (sequence characterized amplification region) markers. The developed AFLP DNA fingerprinting and specific molecular markers provide useful ways for the identification, classification, and resource protection of thePorphyra lines.     

Characterizing homologues of crop domestication genes in poorly described wild relatives by high‐throughput sequencing of whole genomes

Wild crop relatives represent a source of novel alleles for crop genetic improvement. Screening biodiversity for useful or diverse gene homologues has often been based upon the amplification of targeted genes using available sequence information to design primers that amplify the target gene region across species. The crucial requirement of this approach is the presence of sequences with sufficient conservation across species to allow for the design of universal primers. This approach is often not successful with diverse organisms or highly variable genes. Massively parallel sequencing (MPS) can quickly produce large amounts of sequence data and provides a viable option for characterizing homologues of known genes in poorly described genomes. MPS of genomic DNA was used to obtain species‐specific sequence information for 18 rice genes related to domestication characteristics in a wild relative of rice, Microlaena stipoides. Species‐specific primers were available for 16 genes compared with 12 genes using the universal primer method. The use of species‐specific primers had the potential to cover 92% of the sequence of these genes, while traditional universal primers could only be designed to cover 80%. A total of 24 species‐specific primer pairs were used to amplify gene homologues, and 11 primer pairs were successful in capturing six gene homologues. The 23 million, 36‐base pair (bp) paired end reads, equated to an average of 2X genome coverage, facilitated the successful amplification and sequencing of six target gene homologues, illustrating an important approach to the discovery of useful genes in wild crop relatives.     

Occurrence of 16SrIV Subgroup A Phytoplasmas in Roystonea regia and Acrocomia mexicana Palms with Lethal Yellowing‐like Syndromes in Yucatán,Mexico

The lethal yellowing (LY) disease and LY‐type syndromes affecting several palm species are associated with 16SrIV phytoplasmas in the Americas. In Mexico, palms of the species Roystonea regia and the native Acrocomia mexicana were found to exhibit LY‐type symptoms, including leaf decay, starting with mature leaves, necrosis and atrophy of inflorescences. DNA extracts obtained from these palms could be amplified by nested‐PCR using phytoplasma‐universal primer pair P1/P7 followed by LY‐group‐specific primer pair LY16Sr/LY16Sf. Blast analysis of the sequences obtained revealed an identity of 100% for R. regia and 99.27% for A. mexicana with 16SrIV‐A strain associated with LY in Florida, USA (Acc. AF498309 ). Computer‐simulated RFLP analysis showed that the patterns for the phytoplasma DNA of the two palm species were highly similar to that for 16SrIV subgroup A strain. A neighbour‐joining tree was constructed, and the sequences of the two palm species clustered in the same clade of group 16SrIV subgroup A. The results therefore support that LY‐type syndromes observed in palms of R. regia and A. mexicana in the Yucatan region of Mexico are associated with 16SrIV subgroup A phytoplasmas.     

Use of 5´-anchored primers for the enhanced recovery of specific microsatellite markers in Brassica napus L.

Microsatellite markers have assumed great significance in biological research. The isolation and characterisation of microsatellites involves DNA library construction and screening, DNA sequencing, primer design and PCR optimisation. When a microsatellite is situated close to the beginning or end of a cloned fragment, specific primers cannot be designed for one of the flanking sequences, thus hindering the utilisation of such microsatellites as markers. The present approach was to use one 5′-anchored primer complementary to the microsatellite sequence in combination with one specific Cy5- labelled primer with a view to retrieving useful microsatellites, which would otherwise be lost. Six pairs of a 5′ anchored primer and a specific primer were used across a set of 31 Brassica napus winter cultivars and one accession each of five additional Brassica species. Using laser fluorometry a single labelled product was observed after amplification with each of four primer pairs, and one primer pair gave two labelled products. Three products corresponded in size with the products expected if 5′ anchoring was effective, indicating the amplification of locus-specific full-length products including all of the microsatellite repeats. All six primer pairs showed polymorphisms across the Brassica species examined, but only one primer pair showed polymorphisms within B. napus, making it useful for genetic analysis in rapeseed cultivars. The other primer pairs could be useful in studying gene introgression into B. napus or for investigating interspecific crosses involving different Brassica species. Received: 5 August 1999 / Accepted: 1 November 1999     

Random Amplified Polymorphic DNA Profiles as a Tool for the Identification of Acanthamoeba divionensis

In the present study, we demonstrated the Random Amplified Polymorphism DNA (RAPD) diagnostic validity. In our study, we have analyzed RAPD profiles searching for characteristic and useful bands for Acanthamoeba diagnosis at the species level. We found a distinctive 370-bp band in A. divionensis RAPD patterns, using the OPC14 primer (TGCGTGCTTG) (Operon Technologies, Inc., Alameda, CA). The band specificity was confirmed by hybridization, using it as a probe, against all OPC14 amplifications from 10 different Acanthamoeba species. Once we sequenced this band, we used it to design a specific primer pair which showed positive amplification only in A. divionensis isolates. RID= ID= <E5>Correspondence to:</E5> A. Ortega-Rivas; <E5>email</E5>: aortega&commat;ull.es Received: 5 August 2002 / Accepted: 23 September 2002     

Identification of 27 <Emphasis Type="Italic">Porphyra</Emphasis> lines (Rhodophyta) by DNA fingerprinting and molecular markers

Twenty-seven Porphyra lines, including lines widely used in China, wild lines and lines introduced to China from abroad in recent years, were screened by random amplified polymorphic DNA (RAPD) technique with 120 operon primers. From the generated RAPD products, 11 bands that showed stable and repeatable RAPD patterns amplified by OPC-04, OPJ-18 and OPX-06, respectively were scored and used to develop the DNA fingerprints of the 27 Porphyra lines. Moreover, the DNA fingerprinting patterns were converted into computer language expressed with two digitals, 1 and 0, which represented the presence (numbered as 1) or absence (numbered as 0) of the corresponding band, respectively. Based on the above results, computerized DNA fingerprints were constructed in which each of the 27 Porphyra lines has its unique fingerprinting pattern and can be easily distinguished from others. Software named PGI (Porphyra germplasm identification) was designed for identification of the 27 Porphyra lines. In addition, seven specific RAPD markers from seven Porphyra lines were identified and two of them were successfully converted into SCAR (sequence characterized amplification region) markers. The developed DNA fingerprinting and specific molecular markers provide useful ways for the identification, classification and resource protection of the Porphyra lines.     

Development of species-specific primers for rapid identification by PCR of the ecologically important pathogen Fusarium keratoplasticum from isolated and environmental samples

The genus Fusarium contains many fungal species known to be pathogenic to animals and plants alike. One species complex within this genus, the Fusarium solani species complex (FSSC), is of particular concern due to its high numbers of pathogenic members. FSSC members are known to contribute significantly to plant, human and other animal fungal disease. One member of the FSSC, Fusarium keratoplasticum, is of particular ecological concern and has been implicated in low hatching success of endangered sea turtle eggs, as well as contribute to human and other animal Fusarium pathogenesis. Species-specific primers for molecular identification of F. keratoplasticum currently do not exist to our knowledge, making rapid identification, tracking and quantitation of this pathogenic fungus difficult. The objective of this study was to develop primers specific to F. keratoplasticum that could be applied to DNA from isolated cultures as well as total (mixed) DNA from environmental samples. RPB2 sequence from 109 Fusarium isolates was aligned and analysed to determine nucleotide polymorphisms specific to F. keratoplasticum useful for primer design. A set of primers were generated and found to be effective for identification of F. keratoplasticum from total DNA extracted from sand surrounding sea turtle nesting sites.     

Rapid detection and identification of the free-living nitrogen fixing genus <Emphasis Type="Italic">Azospirillum</Emphasis> by 16S rRNA-gene-targeted genus-specific primers

The modern agricultural practice utilizing plant growth promoting rhizobacteria (PGPR) has brought great benefits in the promotion of crop growth. Among PGPR, Azospirillum is considered as an important genus which is not only closely-associated with plants but also shows potential in the degradation of organic contaminants. However, lack of media for selective isolation or techniques for specific detection or identification limit the exploration of these rhizobacteria. This motivated us to design a genus-specific oligonucleotide primer pair which could assist in rapid detection of species of the genus Azospirillum by means of PCR-specific amplification. The sensitivity and specificity of the newly designed primer pair Azo494-F/Azo756-R were tested against 12 Azospirillum type strains and other closely-related genera. The Azospirillum-specific 16S rRNA gene fragment (263 bp) was successfully amplified for all the reference Azospirillum species with the designed primer pair. No amplification was noted for closely-related species from other genera. The genus specificity was validated with 18 strains including environmental isolates. Interestingly, two strains assigned earlier as Azospirillum amazonense (DSM 2787^T) and Azospirillum irakense (DSM 11586^T) failed to produce an Azospirillum-specific fragment with this primer pair. Further phylogenetic analysis of these two isolates based on 16S rRNA gene sequences shows that these two strains might belong to other genera rather than Azospirillum. Preliminary screening of isolates and soil samples with the Azospirillum-specific primers was successful in terms of the rapid detection of Azospirillum isolates. By using real-time PCR analysis the minimum limit of Azospirillum detection was 10² CFU g⁻¹ in the seeded soil sample. The newly designed primers can be used to study the diversity of Azospirillum in ecosystems and aid in the exploration of novel species.     

Molecular detection and differentiation of Brazilian and African isolates of the entomopathogen Neozygites tanajoae (Entomophthorales: Neozygitaceae) with PCR using specific primers

Neozygites tanajoae is an entomopathogenic fungus which has been used for biocontrol of the cassava green mite (Mononychellus tanajoa, CGM) in Africa. Establishment and dispersal of Brazilian isolates which have been introduced into some African countries in recent years to improve CGM control was followed with specific PCR assays. Two primer pairs, NEOSSU_F/NEOSSU_R and 8DDC_F/8DDC_R, were used to differentiate isolates collected from several locations in Brazil and from three countries in Africa, Benin, Ghana and Tanzania. The first primer pair enabled the species-specific detection of Neozygites tanajoae, while the second differentiated the Brazilian isolates from those of other geographical origin. PCR assays were designed for detection of fungal DNA in the matrix of dead infested mites since N. tanajoae is difficult to isolate and culture on selective artificial media. Our results show that all isolates (Brazilian and African) that sporulated on mummified mites were amplified with the first primer pair confirming their Neozygites tanajoae identity. The second pair amplified DNA from all the Brazilian isolates, but did not amplify any DNA samples from the African isolates. None of the two primers showed amplification neither from any of the non-sporulating mite extracts nor from the dead uninfected mites used as negative controls. We confirmed that the two primer pairs tested are suitable for the detection and differential identification of N. tanajoae isolates from Brazil and Africa and that they are useful to monitor the establishment and spread of the Brazilian isolates of N. tanajoae introduced into Benin or into other African countries for improvement of CGM biocontrol.     

Novel primer sets for species‐specific amplification of the mitochondrial 12S rRNA genes in four Japanese woodpeckers (Picidae,Piciformes)

In birds, feathers and faeces can be used as a source of DNA for genetic analyses. If the materials are derived from an absentee bird(s), however, the species must first be identified. Here, we developed four pairs of primers for amplification of mitochondrial 12S ribosomal RNA fragments in the black woodpecker Dryocopus martius, a vulnerable species in Japan, and three other sympatric woodpeckers including Dendrocopos leucotos, D. major and Picus awokera. Because each primer pair gave a PCR product in only one of the examined species, these primer sets will be useful in identifying the species of woodpeckers.     

Species-specific PCR primers for the rapid identification of yeasts of the genus Zygosaccharomyces

Species-specific primer pairs that produce a single band of known product size have been developed for members of the Zygosaccharomyces clade including Zygosaccharomyces bailii, Zygosaccharomyces bisporus, Zygosaccharomyces kombuchaensis, Zygosaccharomyces lentus, Zygosaccharomyces machadoi, Zygosaccharomyces mellis and Zygosaccharomyces rouxii. An existing primer pair for the provisional new species Zygosaccharomyces pseudorouxii has been confirmed as specific. The HIS3 gene, encoding imidazole-glycerolphosphate dehydratase, was used as the target gene. This housekeeping gene evolves slowly and is thus well conserved among different isolates, but shows a significant number of base pair changes between even closely related species, sufficient for species-specific primer design. The primers were tested on type and wild strains of the genus Zygosaccharomyces and on members of the Saccharomycetaceae. Sequencing of the D1/D2 region of rDNA was used to confirm the identification of all nonculture collection isolates. This approach used extracted genomic DNA, but in practice, it can be used efficiently with a rapid colony PCR protocol. The method also successfully detected known and new hybrid strains of Z. rouxii and Z. pseudorouxii. The method is rapid, robust and inexpensive. It requires little expertise by the user and is thus useful for preliminary, large-scale screens.     

Development of species‐specific primers for rapid diagnosis of Tetranychus urticae,T. kanzawai,T. phaselus and T. truncatus (Acari: Tetranychidae)

Species diagnosis is of the utmost importance to both pest management and plant quarantine services. Because of difficulties in the morphological diagnosis of spider mites, molecular techniques are of great value to rapidly and accurately diagnose closely related species. We examined four species of genus Tetranychus (the green and red forms of T. urticae, and T. kanzawai, T. phaselus and T. truncatus), which are found in Korea and are of significance to plant quarantine services. DNA samples isolated from a single egg, larva or adult weighed 64–188 ng. We designed species‐specific primers by performing sequence alignment for 107 sequences of the ribosomal internal transcribed spacer 2 (ITS2) region, which we obtained from GenBank, and sequences generated in this study. Specific nucleotides of each species were selected for designing primers specific for each species. Each species‐specific primer pair, when used to perform PCR analyses, detected only the species from which it originated. However, a T. urticae‐specific primer pair did not discriminate between the green and red forms of this species. These species‐specific primers can be applied in practice for the rapid and accurate diagnosis of spider mite species in plant quarantine and in agricultural fields.     

A novel specific DNA marker in Saccharomyces bayanus for species identification of the Saccharomyces sensu stricto complex

This study was based on RAPD fingerprinting for species identification of the Saccharomyces sensu stricto complex. 40 random primers were used for RAPD analysis. The results showed that one of these primers, OPT-18, produced a 974 bp species-specific band, which was only found in the tested S. bayanus. Afterward this specific fragment was isolated from agarose gel and ligated into vector for DNA sequencing. A pair of primer SpeOPT18Sbay-F2 and SpeOPT18Sbay-R2 were designed according to the cloned species-specific sequence, which was employed for PCR with the template DNA of the S. sensu stricto strains, single 779 bp species-specific band was only found in S. bayanus. Therefore, we conclude that our novel species DNA marker could be used to rapidly and accurately identify the species of S. bayanus from S. sensu stricto complex by direct PCR.     

Sex Identification of Four Penguin Species Using Locus‐Specific PCR

Traditional methods for sex identification are not applicable to sexually monomorphic species, leading to difficulties in the management of their breeding programs. To identify sex in sexually monomorphic birds, molecular methods have been established. Two established primer pairs (2550F/2718R and p8/p2) amplify the CHD1 gene region from both the Z and W chromosomes. Here, we evaluated the use of these primers for sex identification in four sexually monomorphic penguin species: king penguins (Aptenodytes patagonicus), rockhopper penguins (Eudyptes chrysocome), gentoo penguins (Pygoscelis papua), and Magellanic penguins (Spheniscus magellanicus). For all species except rockhopper penguins, primer pair 2550F/2718R resulted in two distinct CHD1Z and CHD1W PCR bands, allowing for sex identification. For rockhopper penguins, only primer pair p8/p2 yielded different CHD1Z and CHD1W bands, which were faint and similar in size making them difficult to distinguish. As a result, we designed a new primer pair (PL/PR) that efficiently determined the gender of individuals from all four penguin species. Sequencing of the PCR products confirmed that they were from the CHD1 gene region. Primer pair PL/PR can be evaluated for use in sexing other penguin species, which will be crucial for the management of new penguin breeding programs. Zoo Biol 32:257–261, 2013. © 2012 Wiley Periodicals, Inc.