Intraspecies discrimination of Lactobacillus paraplantarum by PCR

Lactobacillus paraplantarum is a species phenotypically close to Lactobacillus plantarum. Several PCR methods were evaluated to discriminate L. paraplantarum strains and among them, a PCR using an enterobacterial repetitive intergenic consensus (ERIC) sequence differentiated L. paraplantarum from other Lactobacillus species. In addition, a combination of ERIC and random amplified polymorphic DNA (RAPD) analysis distinguished among seven strains of L. paraplantarum tested. ERIC-PCR profiles showed several strain-specific DNA fragments in L. paraplantarum, among them, a 2.2-kb ERIC marker, termed LpF1, found to be specific to strain FBA1, which improved the skin integrity in an animal model. The LpF1 encodes three proteins similar to Lactobacillus fermentum AroA, TyrA, and AroK, which are involved in the shikimate pathway. A primer pair specific to FBA1 based on the internal sequence of LpF1 amplified a 950-bp FBA1-specific fragment LpF2. Southern blot analysis of Dra I-digested genomic DNA of L. paraplantarum strains using LpF2 as a probe showed that LpF2 is distinctive of strain FBA1 among 16 L. paraplantarum strains. Because both ERIC- and RAPD-PCR are fast and technically simple methods, they are useful for the rapid discrimination of L. paraplantarum strains and for the development of new strain-specific DNA markers for identifying industrially important strains.     

Development of IRAP-SCAR marker for strain identification in Lentinula edodes

Rapid and correct authentication of commercial strains is still important in today’s mushroom industry. Here for the first time we reported the using of sequence characterized amplified region (SCAR) marker developed from inter-retrotransposon amplified polymorphism (IRAP) marker to identify Lentinula edodes strain. Genomic polymorphism among 44 shiitake cultivars in China were surveyed by 24 IRAP primer combinations, from which primer combination LTR1L/MarY1R could generate a unique and reproducible 1712 bp fragment to distinguish strain No. 4 from other 43 strains. Based on this strain-specific fragment, a SCAR primer pair was designed and its validity was verified by correctly amplifying a single strain-specific fragment from DNA samples of 100 L. edodes strains. Our study lays the foundation for developing strain-specific SCAR marker by retrotransposon-based marker technique in fungi.     

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.     

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.     

Molecular Cloning, Expression of minD Gene from Lactobacillus acidophilus VTCC-B-871 and Analyses to Identify Lactobacillus rhamnosus PN04 from Vietnam Hottuynia cordata Thunb.

The minD gene encoding an inhibitor cell division MinD homolog from Lactobacillus acidophilus VTCC-B-871 was cloned. We showed that there were 97 % homology between minD genes of L. acidophilus VTCC-B-871 and Lactobacillus rhamnosus GG and Lactobacillus rhamnosus Lc705. Based on the analysis of the DNA sequence data from the L. rhamnosus genome project and sequenced minD gene of L. acidophilus VTCC-B-871, a pair of primers was designed to identified the different minD genes from L. acidophilus ATCC 4356, L. rhamnosus ATCC 11443. Besides, the polymerase chain reaction product of minD gene was also obtained in L. rhamnosus PN04, a strain was isolated from Vietnamese Hottuynia cordata Thunb. In addition, we performed a phylogenetic analysis of the deduced amino acid sequence of MinD homologs from L. acidophilus VTCC-B-871 with the other strains and compared the predicted three-dimension structure of L. acidophilus VTCC-B-871 MinD with Escherichia coli MinD, there are similarity that showed evolution of these strains. The overexpression of L. acidophilus VTCC-B-871 MinD in E. coli led to cell filamentation in IPTG and morphology changes in different sugar stresses, interestingly. The present study is the first report characterizing the Lactobacilus MinD homolog that will be useful in probiotic field.     

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.     

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.     

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.     

油菜单显性核雄性不育基因的分子标记

以陕西省杂交油菜研究中心选育的单显性核不育油菜分离群体为材料,利用集群分离法（BSA）对该油菜单显性核不育基因进行了RAPD分析。在随机选取的300个10碱基随机引物中,引物S243（5′CTATGCCGAC3′）在可育集团与不育集团间扩增出特异而可重复的1．5kb的多态性片段OPU-031500,而在细胞质雄性不育和其它核不育类型油菜中均未扩增出上述特异性片段,从而确证此RAPD标记OPU-031500。片段是与甘蓝型油菜单显性核不育基因连锁的。将该多态性片段克隆并测序,发现其序列与拟南芥的一段DNA序列高度同源。根据同源序列及测序结果设计两对特异引物（P1／P2和P3／P4）,引物P3／P4在可育系中可扩增到约1．5kb的单一特异片断,而在不育系中无带,从而将RAPD标记转化为稳定可靠的SCAR标记。     

Assessment of the Genetic Diversity among Strains of Xanthomonas cynarae by Randomly Amplified Polymorphic DNA Analysis and Development of Specific Characterized Amplified Regions for the Rapid Identification of X. cynarae

The randomly amplified polymorphic DNA (RAPD) method was used to investigate the genetic diversity in Xanthomonas cynarae, which causes bacterial bract spot disease of artichoke. This RAPD analysis was also intended to identify molecular markers characteristic of this species, in order to develop PCR-based markers which can be used to detect this pathogenic bacterium in artichoke fields. Among the 340 RAPD primers tested, 40 were selected on their ability to produce reproducible and reliable fingerprints in our genetic background. These 40 primers produced almost similar patterns for the 37 X. cynarae strains studied, different from the fingerprints obtained for other Xanthomonas species and other xanthomonad-like bacteria isolated from artichoke leaves. Therefore, X. cynarae strains form a homogeneous genetic group. However, a little DNA polymorphism within this species was observed and the collection of X. cynarae isolates was divided into two groups (one containing three strains, the second one including all other strains). Out of seven RAPD markers characteristic of X. cynarae that were cloned, four did not hybridize to the genomic DNA of strains belonging to other Xanthomonas species. These four RAPD markers were converted into PCR markers (specific characterized amplified regions [SCARs]); they were sequenced, and a PCR primer pair was designed for each of them. Three derived SCARs are good candidates to develop PCR-based tests to detect X. cynarae in artichoke fields.     

Conversion of an RAPD marker to an STS marker for barley variety identification

Barley (Hordeum vulgare L.) variety identification is important to the malting and brewing industries. Because many new malting cultivars (varieties) are closely related, new and more effective identification techniques are needed. We report on a series of techniques used to convert an RAPD marker to a more stable STS marker that can identify barley Stander from Robust, an important distinction for the American malting and brewing industries. The techniques included DNA extraction, RAPD amplification, random cloning of all amplified fragments, selection of clones by insert size, DNA sequencing of select inserts, design of a barley-based primer pair, and detection of a single nucleotide polymorphism using restriction endonucleaseAlu I. The barley-based primer pair was used to further sequence the RAPD fragment. Five single nucleotide polymorphisms between Robust and Stander exist, one of which was detected by electrophoresing DNA fragments differentially restricted byAlu I. The conversion technique was different from ones previously reported in that it did not require manual extraction of DNA fragments from a gel. This could be applied to other situations in which RAPD marker conversion would be desirable.     

Consensus-Degenerate Hybrid Oligonucleotide Primers for Amplification of Priming Glycosyltransferase Genes of the Exopolysaccharide Locus in Strains of the Lactobacillus casei Group

A primer design strategy named CODEHOP (consensus-degenerate hybrid oligonucleotide primer) for amplification of distantly related sequences was used to detect the priming glycosyltransferase (GT) gene in strains of the Lactobacillus casei group. Each hybrid primer consisted of a short 3′ degenerate core based on four highly conserved amino acids and a longer 5′ consensus clamp region based on six sequences of the priming GT gene products from exopolysaccharide (EPS)-producing bacteria. The hybrid primers were used to detect the priming GT gene of 44 commercial isolates and reference strains of Lactobacillus rhamnosus, L. casei, Lactobacillus zeae, and Streptococcus thermophilus. The priming GT gene was detected in the genome of both non-EPS-producing (EPS⁻) and EPS-producing (EPS⁺) strains of L. rhamnosus. The sequences of the cloned PCR products were similar to those of the priming GT gene of various gram-negative and gram-positive EPS⁺ bacteria. Specific primers designed from the L. rhamnosus RW-9595M GT gene were used to sequence the end of the priming GT gene in selected EPS⁺ strains of L. rhamnosus. Phylogenetic analysis revealed that Lactobacillus spp. form a distinctive group apart from other lactic acid bacteria for which GT genes have been characterized to date. Moreover, the sequences show a divergence existing among strains of L. rhamnosus with respect to the terminal region of the priming GT gene. Thus, the PCR approach with consensus-degenerate hybrid primers designed with CODEHOP is a practical approach for the detection of similar genes containing conserved motifs in different bacterial genomes.     

Recombinant bovine interferon alpha causes only a temporary prolongation of the lifespan of the corpus luteum

Abstract

A method is described for developing a sheep‐ vs. goat‐specific DNA marker using sequence characterized amplified regions (SCARs) derived from a random amplified polymorphic DNA (RAPD) marker from sheep DNA samples. A sheep 645 bp DNA fragment that was absent in goat DNA was identified by analyzing pools of sheep and goat DNA with RAPD primers. This fragment was cloned and partially sequenced to design extended, strand‐specific 24‐mer oligonucleotide primers. Each primer contained the original 10 bases of the RAPD primer and the following 14 internal bases. The pair of primers resulted in the amplification of a single band of 645 bp when used to amplify sheep DNA, and in no amplification when used to amplify goat DNA. These SCAR primers successfully amplified the equivalent of DNA from one nucleated sheep cell in a sample of 5000 nucleated goat cells. This level of sensitivity is especially desirable for research involving the detection of interspecific chimerism.     

Identification and characterization of RAPD–SCAR markers linked to glyphosate-susceptible and -resistant biotypes of Eleusine indica (L.) Gaertn

Eleusine indica is one of the most common weed species found in agricultural land worldwide. Although herbicide-glyphosate provides good control of the weed, its frequent uses has led to abundant reported cases of resistance. Hence, the development of genetic markers for quick detection of glyphosate-resistance in E. indica population is imperative for the control and management of the weed. In this study, a total of 14 specific random amplified polymorphic DNA (RAPD) markers were identified and two of the markers, namely S4R727 and S26R₆976 were further sequence characterized. Sequence alignment revealed that marker S4R727 showing a 12-bp nucleotides deletion in resistant biotypes, while marker S26R₆976 contained a 167-bp nucleotides insertion in the resistant biotypes. Based on these sequence differences, three pairs of new sequence characterized amplified region (SCAR) primers were developed. The specificity of these primer pairs were further validated with genomic DNA extracted from ten individual plants of one glyphosate-susceptible and five glyphosate-resistant (R2, R4, R6, R8 and R11) populations. The resulting RAPD–SCAR markers provided the basis for assessing genetic diversity between glyphosate-susceptible and -resistant E. indica biotypes, as well for the identification of genetic locus link to glyphosate-resistance event in the species.     

Design and Evaluation of a Specific Primer Pair for the Diagnosis and Identification of <Emphasis Type="Italic">Acanthamoeba polyphaga</Emphasis>

Random amplified polymorphism DNA (RAPD) is a useful tool for species identification. The obtained band patterns can be used for specific primer pair design that may be useful for species diagnosis. In this study, a distinctive a 962-bp band in A. polyphaga band patterns was found, by using the OPC20 primer (ACTTCGCCAC). The DNA fragment was used to design a specific primer pair that was useful for the identification of different isolates as A. polyphaga species. A case of A. polyphaga in disseminated acanthamoebiasis affecting mesenteric nodes is also reported.     

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.     

Characterization of Non-Starter Lactic Acid Bacteria from Italian Ewe Cheeses Based on Phenotypic, Genotypic, and Cell Wall Protein Analyses

Non-starter lactic acid bacteria (NSLAB) were isolated from 12 Italian ewe cheeses representing six different types of cheese, which in several cases were produced by different manufacturers. A total of 400 presumptive Lactobacillus isolates were obtained, and 123 isolates and 10 type strains were subjected to phenotypic, genetic, and cell wall protein characterization analyses. Phenotypically, the cheese isolates included 32% Lactobacillus plantarum isolates, 15% L. brevis isolates, 12% L. paracasei subsp. paracasei isolates, 9% L. curvatus isolates, 6% L. fermentum isolates, 6% L. casei subsp. casei isolates, 5% L. pentosus isolates, 3% L. casei subsp. pseudoplantarum isolates, and 1% L. rhamnosus isolates. Eleven percent of the isolates were not phenotypically identified. Although a randomly amplified polymorphic DNA (RAPD) analysis based on three primers and clustering by the unweighted pair group method with arithmetic average (UPGMA) was useful for partially differentiating the 10 type strains, it did not provide a species-specific DNA band or a combination of bands which permitted complete separation of all the species considered. In contrast, sodium dodecyl sulfate-polyacrylamide gel electrophoresis cell wall protein profiles clustered by UPGMA were species specific and resolved the NSLAB. The only exceptions were isolates phenotypically identified as L. plantarum and L. pentosus or as L. casei subsp. casei and L. paracasei subsp. paracasei, which were grouped together. Based on protein profiles, Italian ewe cheeses frequently contained four different species and 3 to 16 strains. In general, the cheeses produced from raw ewe milk contained a larger number of more diverse strains than the cheeses produced from pasteurized milk. The same cheese produced in different factories contained different species, as well as strains that belonged to the same species but grouped in different RAPD clusters.     

Strain identification of probiotic Lactobacillus casei-related isolates with randomly amplified polymorphic DNA and pulsed-field gel electrophoresis methods

Typing of reference strains and isolates identified as Lactobacillus casei, Lactobacillus paracasei or Lactobacillus rhamnosus was carried out using randomly amplified polymorphic DNA (RAPD) and pulsed-field gel electrophoresis (PFGE) analyses. Strains of L. paracasei were mainly grouped in the same cluster as those of L. casei. The RAPD fingerprints of strains ATCC 393 and ATCC 15820 differ from those of the L. rhamnosus and L. paracasei/casei strains further supporting classification of these strains as a separate group. The RAPD profiling could be used for classification and discrimination of isolates belonging to the L. casei group.     

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 strain-specific genomic marker for monitoring a Bacillus subtilis biocontrol strain in the rhizosphere of tomato

A strain-specific molecular marker enabling the detection and tracking of the biological control agent Bacillus subtilis 101, when released into the environment, was developed. Random amplified polymorphic DNA (RAPD) technique was used to differentiate this from other B. subtilis strains. A differentially amplified fragment obtained from RAPD profiles was sequenced and characterized as sequence-characterized amplified region (SCAR) marker, and four primer pairs were designed and evaluated for their specificity towards this strain. The sensibility of the selected SCAR primer pair was evaluated by qualitative PCR and Southern blotting, and the detection limit was assessed around 10(2) CFU (g dry wt soil)(-1), thus providing a reliable tool for the traceability of this B. subtilis strain in greenhouse or field trials. A plating assay coupled to PCR with the SCAR primer pair was then used as a detection method in microcosm experiments for monitoring the population of B. subtilis 101 in the rhizosphere of tomato, grown under two different soil conditions, i.e. nonsterile peat-based substrate and sandy-loam agricultural soil, respectively. The data of rhizosphere colonization indicated that the soil conditions significantly affected the rhizosphere establishment of strain 101.