The molecular evolution and structural organization of group I introns at position 1389 in nuclear small subunit rDNA of myxomycetes

The number of nuclear group I introns from myxomycetes is rapidly increasing in GenBank as more rDNA sequences from these organisms are being sequenced. They represent an interesting and complex group of intervening sequences because several introns are mobile (or inferred to be mobile) and many contain large and unusual insertions in peripheral loops. Here we describe related group I introns at position 1389 in the small subunit rDNA of representatives from the myxomycete family Didymiaceae. Phylogenetic analyses support a common origin and mainly vertical inheritance of the intron. All S1389 introns from the Didymiaceae belong to the IC1 subclass of nuclear group I introns. The central catalytic core region of about 100 nt appears divergent in sequence composition even though the introns reside in closely related species. Furthermore, unlike the majority of group I introns from myxomycetes the S1389 introns do not self-splice as naked RNA in vitro under standard conditions, consistent with a dependence on host factors for folding or activity. Finally, the myxomycete S1389 introns are exclusively found within the family Didymiaceae, which suggests that this group I intron was acquired after the split between the families Didymiaceae and Physaraceae.     

长白山黏菌区系多样性研究

对长白山地区黏菌区系进行初步研究,结果如下：含20种以上的大科有5个,分别为绒泡菌科、团毛菌科、钙皮菌科、发网菌科和筛菌科,共含195种,占总种数的92．86％;含10种以上的属有绒泡菌属、团网菌属、筛菌属、双皮菌属、团毛菌属、钙皮菌属和发网菌属,共含144种,占总数的68．57％。从物种的区系成分上看,世界分布和北温带成分占绝对优势,二者占总种数的66．66％。另外,特有成分也较多。说明长白山黏菌区系丰富多彩并具有特色。     

Rapid detection and identification of the metabolically diverse genus Gordonia by 16S rRNA-gene-targeted genus-specific primers

The importance of the emerging genus Gordonia in industrial and environmental biotechnology is evidenced by the recent increase in associated publications and patents. But, investigations into potentially valuable Gordonia members are restricted by the limitations of current isolation and detection techniques. This motivated us to design a genus-specific oligonucleotide primer pair which could assist in rapid detection of species of the genus Gordonia by means of PCR-specific amplification. The Gordonia-specific 16S rDNA fragment (829 bp) was successfully amplified for all the reference Gordonia species with the designed primer pair G268F/G1096R. No amplification was noted for closely related species from other genera. The genus specificity was validated with 47 strains including wild-type isolates. Interestingly, two strains assigned earlier as Gordonia nitida (DSM 777) and Gordonia rubripertinctus (ATCC 21930) failed to produce a Gordonia-specific fragment with this primer pair. Further analysis of these two isolates based on 16S rDNA sequencing and phylogenetic analysis classified them to the genus Rhodococcus. Preliminary screening of soil samples with the Gordonia-specific primers was successful in terms of the rapid detection of nine Gordonia wild-type isolates.     

PCR primers and functional probes for amplification and detection of bacterial genes for extracellular peptidases in single strains and in soil

A set of primers and functional probes was developed for the detection of peptidase gene fragments of proteolytic bacteria. Based on DNA sequence data, degenerate PCR primers and internal DIG-labeled probes specific for genes encoding alkaline metallopeptidases (apr) (E.3.4.24), neutral metallopeptidases (npr) (E.3.4.24) and serine peptidases (sub) (E.3.4.21) were derived by multiple sequence alignments.Type strains with known peptidase genes and proteolytic bacteria from a grassland rhizosphere soil, a garden soil and an arable field were investigated for their genotypic proteolytic potential. For 52 out of 53 proteolytic bacterial isolates, at least one of the three peptidase classes could be identified by this approach. The amplified gene fragments were of the expected sizes with each of the three primer sets. The functional probes APR, NPR and SUB have been shown to hybridize specifically to the corresponding gene fragments. sub and npr genes were mainly found in Bacillus species. apr genes were only found in the Pseudomonas fluorescens biotypes and in two morphologically identical Flavobacterium-Cytophaga strains from two different sites. In most of the Bacillus spp., both sub and the npr and in the Flavobacterium-Cytophaga strains even all the three genes could be detected. PCR with DNA isolated from soil led to one main product of the expected size with each primer pair whose identity was additionally confirmed by Southern blot hybridization with the corresponding probes.     

Identification of a universally primed-PCR-derived sequence-characterized amplified region marker for an antagonistic strain of Clonostachys rosea and development of a strain-specific PCR detection assay

We developed a PCR detection method that selectively recognizes a single biological control agent and demonstrated that universally primed PCR (UP-PCR) can identify strain-specific markers. Antagonistic strains of Clonostachys rosea (syn. Gliocladium roseum) were screened by UP-PCR, and a strain-specific marker was identified for strain GR5. No significant sequence homology was found between this marker and any other sequences in the databases. Southern blot analysis of the PCR product revealed that the marker represented a single-copy sequence specific for strain GR5. The marker was converted into a sequence-characterized amplified region (SCAR), and a specific PCR primer pair was designed. Eighty-two strains, isolated primarily from Danish soils, and 31 soil samples, originating from different localities, were tested, and this specificity was confirmed. Two strains responded to the SCAR primers under suboptimal PCR conditions, and the amplified sequences from these strains were similar, but not identical, to the GR5 marker. Soil assays in which total DNA was extracted from GR5-infested and noninoculated field soils showed that the SCAR primers could detect GR5 in a pool of mixed DNA and that no other soil microorganisms present contained sequences amplified by the primers. The assay developed will be useful for monitoring biological control agents released into natural field soil.     

Simultaneous detection of Fusarium asiaticum and Fusarium graminearum in wheat seeds using a real-time PCR method

Aims:  To develop a PCR-based method for quantitative detection of Fusarium asiaticum ( Fa ) and Fusarium graminearum ( Fg ) in wheat seeds.
Methods and Results:  Based on the sequences of the cyp51A gene, two primer pairs FaF + FaR and FgF + FgR were developed for the species-specific detection of Fa and Fg , respectively. To simultaneously detect these two phylogenetic species, a pair of primers FgaF + FgaR was developed based on the first and the second introns of β -tubulin gene. This primer pair amplified a 228-bp fragment only from Fa and Fg isolates, but not from 22 other Fusarium spp. and 13 other fungal species. A real-time PCR with this primer pair was able to quantify minute amounts of Fa and Fg DNA in wheat seeds rapidly.
Conclusions:  PCR primers designed based on the sequence of cyp51A or intron region of β -tubulin gene could allow differentiation of genetically related fungal species.
Significance and Impact of the Study:  The sensitive and quantitative detection method can be readily used in epidemiological studies and in assessing risk of Fusarium mycotoxin contamination in wheat samples.     

Use of intersimple sequence repeats markers to develop strain-specific SCAR markers for Lentinula edodes

Although Lentinula edodes is the second most important cultivated mushroom worldwide, most industrially cultivated strains have been identified only through traditional phenotypic analysis. Here, we report for the first time the use of sequence characterized amplified region (SCAR) markers for strain differentiation. SCAR markers were created by first generating and sequencing single intersimple sequence repeats fragments, and then designing primers based on these sequences to amplify strain-specific fragments of a certain size. One SCAR primer pair, ISL450F/R7 (amplifying a band of c. 450 bp), was designed to identify one strain of L. edodes (strain No. 7). The SCAR primer pair was then used to correctly amplify the single unique fragment from DNA samples taken from a total of 85 strains representing three separate species. Our data provide the foundation for a precise and rapid PCR-based strain-diagnostic system for L. edodes.     

Comparison of Phenotypic and Genotypic Methods Used for the Species Identification of Lactobacillus NP51 and Development of a Strain-Specific PCR Assay

The species level identity of Lactobacillus NP51, a commercial direct-fed microbial previously identified as Lactobacillus acidophilus NP51, was re-evaluated to determine whether new technologies resulted in changes in the original identification. The phenotypic methods for species identification included API 50 CHL kit and two automated systems, Vitek 2 and MIDI (FAME analysis; a total of three independent FAME analyses). Discrepancies among the identification results with all methods of phenotypic analysis were reported. MicroSeqID 500 16S rRNA system (SeqWright Inc., Houston, TX), a genotypic method, identified the organism as Lactobacillus animalis. Cloning, sequencing and subsequent sequence comparison of NP51 16S–23S intergenic spacer region (ISRs) to nucleotide sequence databases using the BLAST search tool indicated that NP51 can now be named L. animalis. When NP51 was originally identified as L. acidophilus, the designation of L. animalis did not exist taxonomically. The NP51 sequence comparisons using BLAST also revealed that NP51 and a strain previously identified as L. animalis LA51 HOFG1 by Flint and Angert are identical strains under different names. A strain-specific primer pair was also identified for HOFG1 by the same research group. A primer pair (using HOFG1 forward pair) also produced an amplicon unique to NP51. These methods demonstrate the significance of genetic-based detection methods both for scientific identification of organisms from biological samples and to prevent misidentification in food and health industry related microorganisms in which proprietary considerations are an important concern.     

Development of a specific PCR assay for the detection of Rhizoctonia solani AG 1-IB using SCAR primers

AIMS: The aim of this study was to develop a specific and sensitive identification method for Rhizoctonia solani AG 1-IB isolates based on phylogenetic relationships of R. solani AG-1 subgroups using rDNA-internal transcribed spacer (rDNA-ITS) sequence analysis. METHODS AND RESULTS: A neighbour-joining tree analysis of 40 rDNA-ITS sequences demonstrated that R. solani AG-1 isolates cluster separately in six subgroups IA, IB, IC, ID, IE and IF. A molecular marker was generated from a random amplified polymorphic DNA fragment (RAPD). After conversion into a sequence-characterized amplified region (SCAR), a specific primer set for identification of subgroup AG 1-IB was designed for use in a polymerase chain reaction (PCR). The primer pair amplified a single DNA product of 324 bp. CONCLUSIONS: R. solani AG-1 subgroups were discriminated by sequence analysis of the ITS region. The designed SCAR primer pair allowed an unequivocal and rapid detection of R. solani AG 1-IB in plant and soil samples. SIGNIFICANCE AND IMPACT OF THE STUDY: Sequence analysis of the rDNA-ITS region can be used for differentiation of subgroups within AG-1. The use of the developed SCAR primer set allowed a reliable and fast identification of R. solani AG 1-IB and provides a powerful tool for disease diagnosis.     

Characterization of horA and its flanking regions of Pediococcus damnosus ABBC478 and development of more specific and sensitive horA PCR method

AIMS: To characterize horA and its flanking regions of Pediococcus damnosus ABBC478 and, on the basis of this insight, to develop a more specific and sensitive horA PCR method. METHODS AND RESULTS: A plasmid harbouring the homologue of a hop-resistance gene, horA, was sequenced and designated pRH478. The nucleotide sequence and open reading frame structure of horA and its flanking regions of pRH478 were found to be highly similar to those of pRH45, a horA-harbouring plasmid previously identified in Lactobacillus brevis ABBC45. The nucleotide sequence of the horA homologue of P. damnosus ABBC478 was 99.6% identical with that of horA. Based on this insight, new primers specific to horA were designed and compared with the previously reported specific primer pair. As a consequence, it was demonstrated that the new primer pair is superior in specificity and sensitivity. CONCLUSIONS: The newly developed horA PCR method allows more specific and sensitive determination of the beer-spoilage ability of lactic acid bacteria (LAB). SIGNIFICANCE AND IMPACT OF THE STUDY: The nucleotide sequences of the horA homologues were found to be essentially identical among distinct species of LAB, indicating that horA-specific primers can be designed from almost any region of the horA gene.     

Archaeal diversity and community structure in a Swedish barley field: Specificity of the EK510R/(EURY498) 16S rDNA primer

The aim of this study was to analyze a total euryarchaeal community at DNA and RNA levels in a Swedish barley field with relation to soil depth (0-10 and 20-30 cm layers), soil fraction (bulk soil and rhizosphere) and time (August and November sample collection). Amplification of 16S rRNA gene using the archaeal universal A2F and Euryarchaea specific EK510R/(EURY498) primer pair, combined with denaturing gradient gel electrophoresis (DGGE), revealed distinct differences between rDNA and rRNA DGGE profiles. The soil depth, time, or rhizosphere effects did not significantly influence Archaeal community structure. Surprisingly, sequence analysis of DGGE-derived amplicons revealed the presence of Euryarchaea as well as uncultured soil Crenarchaea affiliated with group 1. In agreement, sequence comparison analyses showed that the majority of uncultured Crenarchaea group 1 had almost 100% sequence complementarity to the 3' end of the EK510R/(EURY498) primer. Therefore, we propose that EK510R/(EURY498R) is a universal archaeal primer rather than a Euryarchaea specific SSUrRNA primer. Hence, considerable care should be taken during application of this primer in studies of euryarchaeal biodiversity in soil environments.     

Identification of a Universally Primed-PCR-Derived Sequence-Characterized Amplified Region Marker for an Antagonistic Strain of Clonostachys rosea and Development of a Strain-Specific PCR Detection Assay

We developed a PCR detection method that selectively recognizes a single biological control agent and demonstrated that universally primed PCR (UP-PCR) can identify strain-specific markers. Antagonistic strains of Clonostachys rosea (syn. Gliocladium roseum) were screened by UP-PCR, and a strain-specific marker was identified for strain GR5. No significant sequence homology was found between this marker and any other sequences in the databases. Southern blot analysis of the PCR product revealed that the marker represented a single-copy sequence specific for strain GR5. The marker was converted into a sequence-characterized amplified region (SCAR), and a specific PCR primer pair was designed. Eighty-two strains, isolated primarily from Danish soils, and 31 soil samples, originating from different localities, were tested, and this specificity was confirmed. Two strains responded to the SCAR primers under suboptimal PCR conditions, and the amplified sequences from these strains were similar, but not identical, to the GR5 marker. Soil assays in which total DNA was extracted from GR5-infested and noninoculated field soils showed that the SCAR primers could detect GR5 in a pool of mixed DNA and that no other soil microorganisms present contained sequences amplified by the primers. The assay developed will be useful for monitoring biological control agents released into natural field soil.     

Species Diversity of Uncultured and Cultured Populations of Soil and Marine Ammonia Oxidizing Bacteria

Although molecular techniques are considered to provide a more comprehensive view of species diversity of natural microbial populations, few studies have compared diversity assessed by molecular and cultivation-based approaches using the same samples. To achieve this, the diversity of natural populations of ammonia oxidising bacteria in arable soil and marine sediments was determined by analysis of 16S rDNA sequences from enrichment cultures, prepared using standard methods for this group, and from 16S rDNA cloned from DNA extracted directly from the same environmental samples. Soil and marine samples yielded 31 and 18 enrichment cultures, respectively, which were compared with 50 and 40 environmental clones. There was no evidence for selection for particular ammonia oxidizer clusters by different procedures employed for enrichment from soil samples, although no culture was obtained in medium at acid pH. In soil enrichment cultures, Nitrosospira cluster 3 sequences were most abundant, whereas clones were distributed more evenly between Nitrosospira clusters 2, 3, and 4. In marine samples, the majority of enrichment cultures contained Nitrosomonas, whereas Nitrosospira sequences were most abundant among environmental clones. Soil enrichments contained a higher proportion of identical sequences than clones, suggesting laboratory selection for particular strains, but the converse was found in marine samples. In addition, 16% of soil enrichment culture sequences were identical to those in environmental clones, but only 1 of 40 marine enrichments was found among clones, indicating poorer culturability of marine strains represented in the clone library, under the conditions employed. The study demonstrates significant differences in species composition assessed by molecular and culture-based approaches but indicates also that, employing only a limited range of cultivation conditions, 7% of the observed sequence diversity in clones of ammonia oxidizers from these environments could be obtained in laboratory enrichment culture. Further studies and experimental approaches are required to determine which approach provides better representation of the natural community.     

Molecular characterization of ‘Clover proliferation’ phytoplasma subgroup-D (16SrVI-D) associated with vegetables crops in India

Nine vegetable plants species exhibiting phytoplasma suspected symptoms of white/purple leaf, little leaf, flat stem, witches’ broom, phyllody and leaf yellowing were observed in experimental fields at Indian Agricultural Research Institute, New Delhi from December 2015 to July 2016. Total DNA extracted from the three healthy and three symptomatic leaves of all the nine vegetables were subjected to PCR assays using phytoplasma specific primers P1/P7 followed by R16F2n/R16R2 and 3Far/3Rev to amplify the 16S rDNA fragments. No amplifications of DNA were observed in first round PCR assays with primer pair P1/P7 from any of the symptomatic samples. However, phytoplasma DNA specific fragments of ~ 1.3 kb were amplified from Apium graveolens L. (two isolates), Brassica oleracea vr. capitata L. (one isolate) and Solanum melongena L. (one isolate) by using 3Far/3Rev primer pair and 1.2 kb fragment was amplified from Lactuca sativa L. (one isolate) by using R16F2n/R16R2 primer pair. No DNA amplification was seen in other symptomatic vegetable samples of tomato, carrot, cucurbit, bitter gourd and Amaranthus species utilizing either P1/P7 primer pair followed by 3Far/3Rev or R16F2n/R16R2 primer pairs. Out of three leafhopper species collected from the symptomatic vegetable fields, only Hishimonus phycitis was found positive for association of phytoplasma. No DNA amplifications were observed in healthy plant samples and insects collected from non-symptomatic fields. Comparative sequence comparison analyses of 16S rDNA of positive found vegetable phytoplasma strains revealed 100% sequence identities among each other and with phytoplasma strains of ‘clover proliferation’ (16SrVI) group. Phytoplasma sequences, virtual RFLPs and phylogenetic analyses of 16S rDNA sequence comparison confirmed the identification of 16SrVI subgroup D strain of phytoplasmas in four vegetables and one leafhopper (HP) species. Further virtual RFLP analysis of 16S rDNA sequence of the vegetables phytoplasma strains confirmed their taxonomic classification with strains of ‘clover proliferation’ subgroup D. Since, H. phycitis feeding on symptomatic vegetable species in the study was also tested positive for the 16SrVI phytoplasma subgroup-D as of vegetables; it may act as potent natural reservoir of 16SrVI-D subgroup of phytoplasmas infecting vegetable and other important agricultural crops.     

Amplification of soil fungal community DNA using the ITS86F and ITS4 primers

Internal transcribed spacer (ITS) 86F and ITS4 and the ITS1-F and ITS86R primer pairs were tested to specifically amplify fungal community DNA extracted from soil. Libraries were constructed from PCR-amplified fragments, sequenced and compared against sequences deposited in GenBank. The results confirmed that the ITS86F and ITS4 primer pair was selectively specific for the Ascomycetes, Basidiomycetes and Zygomycetes fungal clades. Amplified products generated by the ITS1F and ITS86R primer pair also aligned with sequences from a range of species within the Ascomycete and Basidiomycete clades but not from the Zygomycete. Both primer sets demonstrated fungal specificity and appear to be well suited for rapid PCR-based (fingerprinting) analysis of environmental fungal community DNA. This is the first reported use and assessment of the ITS86F and ITS4 and the ITS1-F and ITS86R primer pairs in amplifying fungal community DNA from soil.     

Detection of the biocontrol agent Colletotrichum coccodes (183088) from the target weed velvetleaf and from soil by strain-specific PCR markers

Diagnostic molecular markers, generated from random amplified polymorphic DNA (RAPD) and used in polymerase chain reaction (PCR), were developed to selectively recognize and detect the presence of a single strain of the biocontrol fungus Colletotrichum coccodes (183088) on the target weed species Abutilon theophrasti and from soil samples. Several isolates of C. coccodes, 15 species of Colletotrichum, a variety of heterogeneous organisms and various plant species were first screened by RAPD-PCR, and a strain specific marker was identified for C. coccodes (183088). No significant sequence similarity was found between this marker and any other sequences in the databases. The marker was converted into a sequence-characterised amplified region (SCAR), and specific primer sets (N5F/N5R, N5Fi/N5Ri) were designed for use in PCR detection assays. The primer sets N5F/N5R and N5Fi/N5Ri each amplified a single product of 617 and 380 bp, respectively, with DNA isolated from strain 183088. The specificity of the primers was confirmed by the absence of amplified products with DNA from other C. coccodes isolates, other species representing 15 phylogenetic groups of the genus Colletotrichum and 11 other organisms. The SCAR primers (N5F/N5R) were successfully used to detect strain 183088 from infected velvetleaf plants but not from seeded greenhouse soil substrate or from soil samples originating from deliberate-released field experiments. The sensitivity of the assay was substantially increased 1000-fold when nested primers (N5Fi/N5Ri) were used in a second PCR run. N5Fi/N5Ri selectively detected strain 183088 from seeded greenhouse soils as well as from deliberate-released field soil samples without any cross-amplification with other soil microorganisms. This rapid PCR assay allows an accurate detection of C. coccodes strain 183088 among a background of soil microorganisms and will be useful for monitoring the biocontrol when released into natural field soils.     

Molecular method to assess the diversity of Burkholderia species in environmental samples

In spite of the importance of many members of the genus Burkholderia in the soil microbial community, no direct method to assess the diversity of this genus has been developed so far. The aim of this work was the development of soil DNA-based PCR-denaturing gradient gel electrophoresis (DGGE), a powerful tool for studying the diversity of microbial communities, for detection and analysis of the Burkholderia diversity in soil samples. Primers specific for the genus Burkholderia were developed based on the 16S rRNA gene sequence and were evaluated in PCRs performed with genomic DNAs from Burkholderia and non-Burkholderia species as the templates. The primer system used exhibited good specificity and sensitivity for the majority of established species of the genus Burkholderia. DGGE analyses of the PCR products obtained showed that there were sufficient differences in migration behavior to distinguish the majority of the 14 Burkholderia species tested. Sequence analysis of amplicons generated with soil DNA exclusively revealed sequences affiliated with sequences of Burkholderia species, demonstrating that the PCR-DGGE method is suitable for studying the diversity of this genus in natural settings. A PCR-DGGE analysis of the Burkholderia communities in two grassland plots revealed differences in diversity mainly between bulk and rhizosphere soil samples; the communities in the latter samples produced more complex patterns.     

Development of a species-specific AFLP-based SCAR marker for authentication of black muntjac (Muntiacus crinifrons)

Black muntjac is a rare and endangered deer endemic to eastern China. Due to the economic and pharmaceutical value of the meat, antlers and skin, the species has chronically suffered from poaching though it is regarded as the state key protected animal. To provide an effective molecular method for authentication of tissue specimen (such as meat, skin etc.) of the species, we developed a Sequence Characterized Amplified Region (SCAR) derived from a species specific Amplification Fragment Length Polymorphism (AFLP) marker. Initially, a 707-bp species specific DNA fragment of the animal was detected by a pair of AFLP primers (Ep7/Mp8). Subsequently, a species-specific primer pair (P-F/P1-R) was designed based on the specific AFLP fragment sequence, obtaining a 298-bp SCAR for the species. Finally, the reliability of the SCAR primers was verified by two separate PCRs using the designed SCAR primers and a cyt b universal primer pair. As expected, all black muntjac samples presented two bands but the others failed to produce the SCAR by merely showing one band. Our results indicated that the SCAR primers developed in this study may provide a useful tool for forensic authentication of black muntjac samples though further testing with larger sample sizes is warranted.     

Genetic diversity of Desulfovibrio spp. in environmental samples analyzed by denaturing gradient gel electrophoresis of [NiFe] hydrogenase gene fragments.

The genetic diversity of Desulfovibrio species in environmental samples was determined by denaturing gradient gel electrophoresis (DGGE) of PCR-amplified [NiFe] hydrogenase gene fragments. Five different PCR primers were designed after comparative analysis of [NiFe] hydrogenase gene sequences from three Desulfovibrio species. These primers were tested in different combinations on the genomic DNAs of a variety of hydrogenase-containing and hydrogenase-lacking bacteria. One primer pair was found to be specific for Desulfovibrio species only, while the others gave positive results with other bacteria also. By using this specific primer pair, we were able to amplify the [NiFe] hydrogenase genes of DNAs isolated from environmental samples and to detect the presence of Desulfovibrio species in these samples. However, only after DGGE analysis of these PCR products could the number of different Desulfovibrio species within the samples be determined. DGGE analysis of PCR products from different bioreactors demonstrated up to two bands, while at least five distinguishable bands were detected in a microbial mat sample. Because these bands most likely represent as many Desulfovibrio species present in these samples, we conclude that the genetic diversity of Desulfovibrio species in the natural microbial mat is far greater than that in the experimental bioreactors.