Differentiation of dorsal-spined elaphostrongyline larvae by polymerase chain reaction amplification of ITS-2 of rDNA

Molecular genetics was used to devise the first reliable diagnostic tool for differentiating morphologically indistinguishable dorsal-spined, first-stage larvae (L1's) and other stages of the nematode protostrongylid subfamily Elaphostrongylinae. A polymerase chain reaction (PCR) assay employing specifically designed primers was developed to selectively amplify DNA of the ITS-2 region of the ribosomal gene. Amplification of the entire ITS-2 region differentiated between larvae of the genera Elaphostrongylus and Parelaphostrongylus, based on the lengths of fragments produced. Three sets of primers were designed and used successfully to distinguish larvae at the species level. Although it was demonstrated that one primer set in a single PCR assay was capable of distinguishing each of the three Parelaphostrongylus spp., a second primer set would be required for confirmation in routine diagnostic use. Two of the three primer sets were capable of amplifying DNA from all six elaphostrongyline species and of identifying Elaphostrongylus alces and Parelaphostrongylus odocoilei. Although two separate fragments were produced from each Elaphostrongylus cervi and Elaphostrongylus rangiferi, it was not possible to distinguish these two parasites from each other based on the fragment size. The use of various nematodes, hosts, and fecal controls demonstrated the reliability of the primers for all developmental stages including L1's, third-stage larvae, and adult worms. These primers also have potential for identifying other lungworms as was shown by the amplification of Umingmakstrongylus pallikuukensis, the muskox protostrongylid, and Dictyocaulus sp. from white-tailed deer. Although this assay may benefit from further refinement, its present design provides researchers, wildlife managers, clinicians, and animal health regulators with a practical tool for the control, management, and study of meningeal and tissue worms and their close relatives.     

Comprehensive detection of bacterial populations by PCR amplification of the 16S-23S rRNA spacer region

PCR amplification of the spacer region between the 16S and 23S rRNA genes is commonly employed for the analysis of bacterial communities. In this analysis, the intergenic spacers are amplified by PCR using primers complementary to conserved regions in the 3' 16S rDNA and 5' 23S rDNA. By this method, the observation of every bacterial population may be limited by several causes. To explore the extent of bacterial populations overlooked by this method, we have used an empirical approach. In a sample containing about 50 colonies, we tested the capability to amplify by PCR the spacers from each colony. We also examined the ability to observe the spacers from each colony in the product obtained after amplification of the DNA extracted from the whole sample, as it is usually performed by this method. Contrarily to our expectations that a significant fraction of colonies would not yield amplification products, spacers were successfully amplified from every colony of two different samples examined. Overall, our results suggest that in spite of well-based theoretical limitations, the analysis of bacterial communities by amplification of the spacer regions can render a comprehensive representation of the more abundant bacterial clades in the sample.     

Rapid Detection of Phytophthora nicotianae in Infected Tobacco Tissues and Soil Samples Based on Its Ypt1 Gene

This paper describes the development of a polymerase chain reaction (PCR) assay for the detection of Phytophthora nicotianae , the causal agent of Phytophthora blight of tobacco and other plants. The PCR primers were designed based on a Ras-related protein ( Ypt 1) gene, and 115 isolates representing 26 species of Phytophthora and 29 fungal species of plant pathogens were used to test the specificity of the primers. PCR amplification with species-specific (Pn) primers resulted in a product of 389 bp only from isolates of P. nicotianae . The detection sensitivity with Pn primers was 1 ng of genomic DNA. Using Ypt 1F/ Ypt 1R as first-round amplification primers, followed by a second round using the primer pair Pn1/Pn2, a nested PCR procedure was developed, which increased the detection sensitivity 100-fold to 10 pg. PCR with the Pn primers could also be used to detect P. nicotianae from naturally infected tobacco tissues and soil. The PCR-based methods developed here could simplify both plant disease diagnosis and pathogen monitoring as well as guide plant disease management.     

Sequence Variation in the Ribosomal DNA Internal Transcribed Spacer of Tridacna crocea

DNA-based genetic markers are needed to augment existing allozyme markers in the assessment of genetic diversity of wild giant clam populations. The dearth of polymorphic mitochondrial DNA regions amplified from known universal polymerase chain reaction (PCR) primers has led us to search other regions of the genome for viable sources of DNA polymorphism. We have designed tridacnid-specific PCR primers for the amplification of internal transcribed spacer regions. Sequences of the first internal transcribed spacer segment (ITS-1) revealed very high polymorphism, showing 29% variation arising from base substitutions alone. Preliminary restriction analysis of the ITS regions using 8 restriction enzymes revealed cryptic changes in the DNA sequence. These mutations are promising as marker tools for differentiating geographically separated populations. Such variation in the ITS region can possibly be used for population genetic analysis. Received February 1, 2000; accepted May 8, 2000.     

Vector PCR.

A strategy employing PCR technology to facilitate the amplification of DNA segments inserted in plasmid vectors is described. Nine oligonucleotide primers specific for vector sequences bracketing cloning sites in seven commonly used vectors were designed. We used these primers for the amplification of 25 different inserts ranging in size from 0.4-4.8 kb. Vector PCR-generated products used as radiolabeled DNA probes in Southern hybridization compared favorably with conventionally prepared probes. This strategy was successfully applied to single colonies of bacteria containing recombinant plasmids for direct amplification of the plasmids insert from the bacterial lysate. Vector PCR enabled the production of microgram quantities of DNA from limited amounts of starting material without the time-consuming steps required for bacterial culture and purification of plasmid DNA. The amplification reaction is independent of the DNA segment to be amplified, rendering the method universally applicable.     

Multiple primer PCR for the identification of anisakid nematodes from Taiwan Strait

There were six major larval anisakid species found in commercial marine fishes caught in the Minnan fishing ground in the Taiwan Strait: Anisakis physeteris, Anisakis pegreffii, Raphidascaris trichiuri, Contracaecum aduncum, Contracaecum muraenesoxi, Contracaecum sp. For rapid identification of the parasite species above, a single and a multiple primer PCR (multiplex PCR) method, using specific primers based on aligned sequences of the internal transcribed spacer ITS-1, 5.8S, and ITS-2 of nuclear ribosomal DNA, were jointly used for the rapid identification of these anisakid larvae. The primers yielded distinct PCR products for each of the anisakid nematodes, providing rapid and accurate tools for identifying anisakid nematodes with distinct geographical distribution.     

Universal primers for amplification of three non-coding regions of chloroplast DNA

Six primers for the amplification of three non-coding regions of chloroplast DNA via the polymerase chain reaction (PCR) have been designed. In order to find out whether these primers were universal, we used them in an attempt to amplify DNA from various plant species. The primers worked for most species tested including algae, bryophytes, pteridophytes, gymnosperms and angiosperms. The fact that they amplify chloroplast DNA non-coding regions over a wide taxonomic range means that these primers may be used to study the population biology (in supplying markers) and evolution (inter- and probably intraspecific phylogenies) of plants.     

Detection of Mycoplasma ovipneumoniae and M. arginini in bighorn sheep using enrichment culture coupled with genus- and species-specific polymerase chain reaction

Mycoplasma species are of interest as possible primary pathogens in the pneumonia complex of bighorn sheep (Ovis canadensis). Previous investigations have not commonly detected low frequencies of Mycoplasma spp. from free-ranging bighorn sheep, possibly due to the fastidious and slow growth of these organisms. We developed a culture protocol that employed an average initial 3-day enrichment culture in liquid Hayflick broth in a CO(2)-enhanced atmosphere. The broth was plated to solid Hayflick medium and the cultures observed for growth for up to 30 days. Polymerase chain reaction (PCR) was performed on DNA isolated from the enrichment broth and on isolates obtained from culture using Mycoplasma genus-specific PCR assays and species-specific PCR assays for M. arginini and M. ovipneumoniae. Some cultures that grew on Hayflick plates were picked as single colonies but were mixed because two organisms may grow together and appear as a single colony. Culture and PCR tests produced similar results for M. arginini, but for M. ovipneumoniae, culture alone was less accurate than PCR. Use of genus-specific primers also may allow detection of other species in samples negative for M. arginini and M. ovipneumoniae. Two methods of transport from field to laboratory (Port-a-Cul? tubes, cryoprotectant in liquid N(2) and Fisher Transport System) gave similar results under our study conditions.     

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.     

A PCR-based method for isolation of genomic DNA flanking a known DNA sequence

We describe a simple PCR-based method for the isolation of genomic DNA that lies adjacent to a known DNA sequence. The method is based on the directional cloning of digested genomic DNA into the multiple cloning site of a pUC-based plasmid to generate a limited genomic library. The library is plated onto a number of selective LA plates which are incubated overnight, and recombinant plasmid DNA is then isolated from resistant colonies pooled from each plate. PCR amplification is performed on the pooled recombinant plasmid DNAs using primers specific for the pUC vector and the known genomic sequence. The combination of efficient directional cloning and bacterial transformation gives relative enrichment for the genomic sequence of interest and generates a simple DNA template, enabling easy amplification by PCR.     

A microsampling method for genotyping coral symbionts

Genotypic characterization of Symbiodinium symbionts in hard corals has routinely involved coring, or the removal of branches or a piece of the coral colony. These methods can potentially underestimate the complexity of the Symbiodinium community structure and may produce lesions. This study demonstrates that microscale sampling of individual coral polyps provided sufficient DNA for identifying zooxanthellae clades by RFLP analyses, and subclades through the use of PCR amplification of the ITS-2 region of rDNA and denaturing-gradient gel electrophoresis. Using this technique it was possible to detect distinct ITS-2 types of Symbiodinium from two or three adjacent coral polyps. These methods can be used to intensely sample coral-symbiont population/communities while causing minimal damage. The effectiveness and fine scale capabilities of these methods were demonstrated by sampling and identifying phylotypes of Symbiodinium clades A, B, and C that co-reside within a single Montastraea faveolata colony.     

Combining DNA sequences and morphology in systematics: testing the validity of the dragonfly species Cordulegaster bilineata

Morphological and molecular techniques are rarely combined when answering questions of taxonomic validity. In this study, we combine morphological techniques with DNA sequences to determine the validity of the dragonfly species Cordulegaster bilineata. The two dragonfly species C. bilineata and C. diastatops are very similar in size, body color, and morphological characters, and due to these similarities, the status of C. bilineata as a valid species is in question. In this study we compare morphological measurements of males and internal transcribed spacer 1 (ITS-1) sequences of rDNA between the two taxa. The hamule measurements (where copulation occurs) of males show little difference between the taxa in question, but the anal appendage measurements (where the male first contacts the female) show marked divergence between the two taxa. Cluster analysis with these anal appendage measurements correctly assigns almost all individuals measured into their respective taxon. PCR amplification products of ITS-1 display a approximately 50 bp size difference between C. bilineata (n = 4) and C. diastatops (n = 5) regardless of collection site. Sequence data for these amplifications show 51 bp missing in one locus in the ITS-1 of C. bilineatarelative to C. diastatops. A lone population of C. diastatops from Wisconsin has three individuals with ITS-1 products that match the size of both C. bilineata and C. diastatops. One individual from this population appears to yield two ITS-1 amplification products that match both C. bilineata and C. diastatops. Although this population may be evidence for hybridization between the two taxa, such hybridization is not necessarily sufficient to disqualify the validity of a separate species designation for C. bilineata. Morphology and ITS-1 sequences depict a high degree of divergence that is consistent with species-level differences.     

Chlamydomonas (Chlorophyceae) colony PCR

The ease and effectiveness of colony polymerase chain reaction (PCR) has allowed rapid amplification of DNA fragments and screening of large number of colonies of interest including transformants and mutants with genetic manipulations. Here, we evaluated colony PCR in Chlamydomonas. Individual colonies were treated with 10 mM ethylenediaminetetraacetic acid (EDTA) or Chelex-100 and the resulting clear cell lysate was used for PCR reaction. Either genomic DNA or plasmid DNA incorporated into the genome was equally amplified. We found that the Chelex method is superior to EDTA method in certain cases. This colony PCR technique will bypass the tedious process of isolating genomic DNA for PCR reaction and will make it possible for rapid amplification of genomic DNA fragments as well as rapid large-scale screening of transformants.     

Direct amplification of the entire ITS region from poorly preserved plant material using recombinant PCR

Sequences of the internal transcribed spacers (ITS) of the nuclear ribosomal DNA are important molecular markers in phylogenetic analyses. To obtain sequences from herbarium material in which DNA often is severely degraded, the ITS region has to be amplified in two steps. Two methods that reduce bench time and reagents used are described. (i) Separately amplified preparations of subunits ITS-1 and ITS-2 are combined before purification. The presence of two fragments in the sequencing reaction does not impair the quality of sequences. (ii) Newly designed internal primers amplify partly overlapping regions of the two subunits. A combination of these internal primers with the external primers in one PCR allows the amplification of the entire ITS region even when degraded DNAs are used. This recombinant PCR approach, taking into account the +A bases added by several Taq DNA polymerases, will also be useful with other marker regions used in molecular phylogenetics.     

Solid phase DNA amplification: a Brownian dynamics study of crowding effects

Solid phase amplification (SPA), a new method to amplify DNA, is characterized by the use of surface-bound primers. This limits the amplification to two-dimensional surfaces and therefore allows the easy parallelization of DNA amplification in a single system. SPA leads to the formation of small but dense DNA brushes, called DNA colonies. For a molecule to successfully duplicate itself, it needs to bend so that its free end can find a matching primer, located on the surface. We used Brownian dynamics simulations (with a united-atom model) to model the basic kinetics of an SPA experiment. The simulations mimic the temperature cycles and the molecule duplication process found in SPA. Our results indicate that the steric interaction between molecules leads to a decreased duplication probability for molecules in the center of a colony and to an outward leaning for the molecules on the perimeter. These effects result in slower amplification (compared to solution PCR) and indicate that steric interaction alone can explain the loss of the exponential growth (characteristic of solution PCR) of the number of molecules in an SPA experiment. Furthermore, the growth of the colony as a function of the number of thermal cycles is found to be similar to the one obtained with a simple Monte Carlo simulation.     

Single-tube colony PCR for DNA amplification and transformant screening of oleaginous microalgae

Recently, several colony PCR methods have been developed to simplify DNA isolation procedure and facilitate PCR-based colony screening efforts in microalgae. A main drawback of current protocols is that cell collection, disruption, and genomic DNA extraction are required preceding the PCR step, making the colony PCR process laborious and costly. In the present study, we have developed a novel procedure that eliminates any steps of DNA extraction and allows the colony screening to be performed in a single PCR tube: algal cells (as low as 5,000) from agar plates or liquid cultures were directly transferred into a PCR tube containing 2× PCR buffer and boiled for 5–10 min depending on different algal strains, followed by addition of other PCR components (dNTPs, primers, and polymerase) and then subjected to conventional PCR reaction. The procedure documented here worked well not only for the model alga Chlamydomonas reinhardtii, but also for the thick-walled oleaginous strains such as Chlorella, Haematococcus, Nannochloropsis, and Scenedesmus with its efficacy independent on amplicon sizes and primer pairs. In addition, screening of Chlorella zofingiensis transformants was achieved using this method. Collectively, our single-tube colony PCR is a much simpler and more cost-effective procedure as compared to those previously reported and has broad applications including gene cloning, strain determination, and high-throughput screening of algae colonies and transformants for biomass and biofuel production.     

Amplification of single bulb mites by nested PCR: Species-specific primers to detect Rhizoglyphus robini and R. setosus (Acari: Acaridae)

A major problem of using molecular amplicons for DNA amplification in mite systematics is that sufficient template cannot always be acquired from an individual mite. To solve this problem, we developed a nested PCR for DNA amplification of single Rhizoglyphus robini and R. setosus bulb mites. A dilution up to 10⁵ of the DNA from a single egg, larva, nymph or adult contained enough templates for amplification of the target ribosomal region. However, the use of specific primers in the second PCR is necessary to reduce the generation of non-target DNAs from symbiotic organisms. Identification of bulb mites collected from seven sampling locations in Taiwan or of bulb mites that were used in simulated experiments in the presence of host plant tissues was unambiguous with specific PCR primers.     

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.     

Species specific identification of nine human Bifidobacterium spp. in feces

Based on the 16S rDNA sequences, species specific primers were designed for the rapid identification by DNA amplification of nine human Bifidobacterium spp., namely B. adolescentis, B. angulatum, B. bifidum, B. breve, B. catenulatum, B. dentium, B. infantis, B. longum, B. pseudocatenulatum. B. lactis currently included in dairy products was added to the series. The primers were designed to target different positions of the 16S rDNA, allowing the simultaneous identification of these ten species of Bifidobacterium using two mixtures of primers. The identification procedure described in this paper was validated by establishing a correlation with an AluI restriction pattern of the different full length amplified 16S rDNA. This multiple primer DNA amplification technique was applied for the identification of pure colonies of Bifidobacterium spp. or directly from total bacteria recovered from human fecal samples. The technique was shown to be useful to detect dominant species and, when primers were used in separate reactions, underrepresented species could be identified as well.     

Multiple displacement amplification as a pre-polymerase chain reaction (pre-PCR) to detect ultra low population of Ralstonia solanacearum (Smith 1896) Yabuchi et al. (1996)

Aims:  To develop a reliable and sensitive protocol for detection of Ralstonia solanacearum using MDA-PCR (Multiple displacement amplification–PCR amplification).
Methods and Results:  MDA-PCR technique was performed on pure cell lysates as well as soil samples. Pure cell lysate as well as that of soil DNA was used as template in MDA reaction. MDA of template DNA was carried out in the presence of sample buffer, reaction buffer and enzyme mix (Φ 29 DNA polymerase and random hexamers). The MDA amplified DNA was used for PCR amplification using R. solanacearum -specific PCR primers. MDA-PCR could detect as low as 1 colony forming unit (CFU ml⁻¹) of bacteria within 8 h including DNA isolation.
Conclusion:  MDA followed by standard PCR facilitated the detection of pathogen from very low count samples. The method is of great importance in managing the brown rot disease of potato.
Significance and Impact of study:  The ultrasensitive detection technique developed in the present study is sensitive and speedy enough to be included into integrated wilt disease control programmes.