Genome- and species-specific markers and genome relationships of diploid perennial species in Triticeae based on RAPD analyses.

Eight different genomes (E, H, I, P, R, St, W, and Ns) represented by 22 diploid species of the tribe Triticeae were analyzed using the random amplified polymorphic DNA (RAPD) technique. The genome relationships were obtained based on 371 RAPD fragments produced with 30 primers. The four species of the genus Psathyrostachys (having various Ns genomes) were closely related. The genomes Ee and Eb had a similarly close relationship and were distinct from all other genomes analyzed. Genomes P, R, and St were grouped in one cluster and genomes H and I in another. Genome W had a distant relationship with all other genomes. These results agree with the conclusions from studies of chromosome pairing and isozyme and DNA sequence analyses. Twenty-nine and 11 RAPD fragments are considered to be genome- and species-specific markers, respectively. One to six genome-specific markers were identified for each genome. These RAPD markers are useful in studies of genome evolution, analysis of genome composition, and genome identification.     

Morphological variation and genome constitution in some perennial Triticeae

JARVIE, J. K. & BARKWORTH, M. E., 1992. Morphological variation and genome constitution in some perennial Triticeae. A numerical analysis of species of five genomically defined genera of the Triticeae was undertaken, based on 42 morphological characters and 142 operational taxonomic units (OTUs). The primary goal was to determine the degree of congruence between morphological variation and genomic constitution. The second goal was to determine which existing supraspecific classification, if any, best reflected the morphological variation encountered. The five genera investigated were Thinopyrum (J genome), Lophopyrum (E genome), Pseudoroegneria (S genome), Trichopyrum (EES genome) and Elytrigia (SJE/SSX genome). Both principal co-ordinate and cluster analysis of the data placed the OTUs in supraspecific groups that reflected their genomic constitution. Monogenomic taxa were clearly separated. Allotetraploids between the E and S genomes were situated between E and S monogenomic taxa. Allotetraploids between the J and E genomes were situated closest to J genome taxa. The EES taxa of Trichopyrum were placed closest to Lophopyrum. OTUs of Elytrigia overlapped those of Pseudoroegneria , but not those of Lophopyrum or Thinopyrum.     

Genome size and genome evolution in diploid Triticeae species.

One of the intriguing issues concerning the dynamics of plant genomes is the occurrence of intraspecific variation in nuclear DNA amount. The aim of this work was to assess the ranges of intraspecific, interspecific, and intergeneric variation in nuclear DNA content of diploid species of the tribe Triticeae (Poaceae) and to examine the relation between life form or habitat and genome size. Altogether, 438 plants representing 272 lines that belong to 22 species were analyzed. Nuclear DNA content was estimated by flow cytometry. Very small intraspecific variation in DNA amount was found between lines of Triticeae diploid species collected from different habitats or between different morphs. In contrast to the constancy in nuclear DNA amount at the intraspecific level, there are significant differences in genome size between the various diploid species. Within the genus Aegilops, the 1C DNA amount ranged from 4.84 pg in A. caudata to 7.52 pg in A. sharonensis; among genera, the 1C DNA amount ranged from 4.18 pg in Heteranthelium piliferum to 9.45 pg in Secale montanum. No evidence was found for a smaller genome size in annual, self-pollinating species relative to perennial, cross-pollinating ones. Diploids that grow in the southern part of the group's distribution have larger genomes than those growing in other parts of the distribution. The contrast between the low variation at the intraspecific level and the high variation at the interspecific one suggests that changes in genome size originated in close temporal proximity to the speciation event, i.e., before, during, or immediately after it. The possible effects of sudden changes in genome size on speciation processes are discussed.     

Quantitative intra-short interspersed element PCR for species-specific DNA identification

We have designed and evaluated four assays based upon PCR amplification of short interspersed elements (SINEs) for species-specific detection and quantitation of bovine, porcine, chicken, and ruminant DNA. The need for these types of approaches has increased drastically in response to the bovine spongiform encephalopathy epidemic. Using SYBR Green-based detection, the minimum effective quantitation levels were 0.1, 0.01, 5, and 1 pg of starting DNA template using our bovine, porcine, chicken, and ruminant species-specific SINE-based PCR assays, respectively. Background cross-amplification with DNA templates derived from 14 other species was negligible. Species specificity of the PCR amplicons was further demonstrated by the ability of the assays to accurately detect trace quantities of species-specific DNA from mixed (complex) sources. Bovine DNA was detected at 0.005% (0.5 pg), porcine DNA was detected at 0.0005% (0.05 pg), and chicken DNA was detected at 0.05% (5 pg) in a 10-ng mixture of bovine, porcine, and chicken DNA templates. We also tested six commercially purchased meat products using these assays. The SINE-based PCR methods we report here are species-specific, are highly sensitive, and will improve the detection limits for DNA sequences derived from these species.     

Studies on host-virus genome relationship in Epstein-Barr virus immortalized lymphoblastoid cell lines

Five human lymphoblastoid cell lines immortalized in vitro with the B95-8 EBV strain, chosen to have a low number of copies of EBV genome, were examined to detect variations in electrophoretic mobility of viral restriction fragments and in the karyotype. Patterns of mobility detected with different viral probes are always the same as those obtained with fragments from purified virus-plasmidic DNA, with one exception. This "non-plasmidic" pattern occurs with a probe containing the termini of the linear virion DNA and consists in an increase of the molecular weight and in the appearance of more than one band. Cytogenetic studies carried on the same cell populations used as source of DNA, early after immortalization, showed a diploid modal chromosome number and no G banding rearrangements.     

Development of a species-specific sequence-characterized amplified region marker for roses

DNA fingerprints of four rose species, Rosa centifolia, R. Gruss-an-Teplitz, R. bourboniana, and R. damascena, were developed using RAPD-PCR. We identified a unique polymorphic band in R. centifolia. This 762-bp fragment was produced by the random primer GLI-2. The fragment was eluted and directly cloned in a TA cloning vector, pTZ57R/T. Digestion of the plasmid with EcoRI confirmed the cloning of GLI-2(762) in pTZ57R/T. A second enzyme, PstI, used in combination with EcoRI, gave complete digestion of the plasmid, and the 762-bp fragment was confirmed on the gel. Subsequently, the polymorphic amplicon was sequenced with an AB1 373 DNA sequencer system using the PRISM(TM) Ready Reaction DyeDeoxy(TM) Terminator Cycle Sequencing kit. After sequencing, specific primers (23 bp long) were designed based on the sequence of the flanking regions of the original RAPD fragment. These primers will effectively allow fingerprinting for the identification of R. centifolia species. In essence, we developed an SCAR marker to authenticate the identity of R. centifolia species and to distinguish it from its substitutes. Such techniques are required not only to complement conventional parameters in creating the passport data of commercial and medicinal products of rose, but also for routine quality control in commercial and government rosaries and rose nurseries.     

Genus- and species-specific PCR primers for the detection and identification of bifidobacteria

16SrDNA-targeted genus- and species-specific PCR primers have been developed and used for the identification and detection of bifidobacteria. These primers cover all of the described species that inhabit the human gut, or occur in dairy products. Identification of cultured bifidobacteria using PCR primer pairs is rapid and accurate, being based on nucleic acid sequences. Detection of bifidobacteria can be achieved using DNA extracted from human faeces as template in PCR reactions. We have found that, in adult faeces, the Bifidobacterium catenulatum group was the most commonly detected species, followed by Bifidobacterium longum, Bifidobacterium adolescentis, and Bifidobacterium bifidum. In breastfed infants, Bifidobacterium breve was the most frequently detected species, followed by Bifidobacterium infantis, B. longum and B. bifidum. It was notable that the B. catenulatum group was detected with the highest frequency in adults, although it has often been reported that B. adolescentis is the most common species. Real-time, quantitative PCR using primers targeting 16S rDNA shows promise in the enumeration of bifidobacteria in faecal samples. The approach to detect the target bacteria with quantitative PCR described in this review will contribute to future studies of the composition and dynamics of the intestinal microflora.     

Development of a species-specific recA-based PCR test for Burkholderia fungorum

The genus Burkholderia comprises over 28 species and species-specific, recA-based polymerase chain reaction (PCR) tests are available for several species, but not for some soil-inhabiting species including B. fungorum. Previous analysis of several novel rhizospheric, environmental isolates belonging to the B. cepacia complex suggested they may be closely related to B. fungorum. To discover any relationship between these isolates and B. fungorum we set out to clone and sequence a portion of the B. fungorum recA gene in order to design species-specific primer pairs for use in a recA-based PCR assay. Using a similar procedure we extended the recA-based PCR assay to identify B. sacchari and B. caledonica, two additional soil-inhabiting Burkholderia spp.     

Sequence-tagged-site-facilitated PCR for barley genome mapping

Summary Speed, efficiency, and safety considerations have led many genome mapping projects to evaluate polymerase chain reaction (PCR) sequence amplification as an alternative to Southern blot analysis. However, the availability of informative primer sequences can be a limiting factor in PCR-based mapping. An alternative to random amplified polymorphism detection (RAPD) is the sequence-tagged-site (STS) approach. If informative primer sequences could be derived from known sequences, then current maps, which are based on both known function and anonymous clones, might be easily converted to maps utilizing PCR technology. In this paper, four pairs of primer sequences were obtained from published sequences, and four pairs were obtained by sequencing portions of DNA clones from genomic clones derived from a random genomic library used in the North American Barley Genome Mapping Project (NABGMP). These primers were used to screen for polymorphisms in the progeny of a winter x spring and a spring x spring barley cross. Two types of polymorphisms were distinguished using these primer sets: (1) insertion/deletion events that could be read directly from agarose gels, and (2) point mutation events. The latter were identified using polyacrylamide-gel electrophoresis of PCR products following digestion with restriction endonucleases (four-base cutters). To determine whether the PCR-based polymorphisms were allelic to polymorphisms identified by the clones from which the primer sequences derived, chromosomal assignments and (when possible) co-segregation analysis was performed.     

Template-blocking PCR: An advanced PCR technique for genome walking

This article describes the development of an improved method for the isolation of genomic fragments adjacent to a known DNA sequence based on a cassette ligation-mediated polymerase chain reaction (PCR) technique. To reduce the nonspecific amplification of PCR-based genome walking, the 3′ ends of the restriction enzyme-digested genomic DNA fragments were blocked with dideoxynucleoside triphosphate (ddNTP) and ligated with properly designed cassettes. The modified genomic DNA fragments flanked with cassettes were used as a template for the amplification of a target gene with a gene-specific primer (GSP) and a cassette primer (CP). The ddNTP blocking of the genomic DNA ends significantly reduced the nonspecific amplification and resulted in a simple and rapid walking along the genome. The efficiency of the template-blocking PCR method was confirmed by a carefully designed control experiment. The method was successfully applied for the cloning of the PGK1 promoter from Pichia ciferrii and two novel cellulase genes from Penicillium sp.     

Ubiquity of the St chloroplast genome in St-containing Triticeae polyploids.

Interspecific hybridization occurs between Tritceae species in the grass family (Poaceae) giving rise to allopolyploid species. To examine bias in cytoplasmic DNA inheritance in these hybridizations, the sequence of the 3' end of the chloroplast ndhF gene was compared among 29 allopolyploid Triticeae species containing the St nuclear genome in combination with the H, I, Ns, P, W, Y, and Xm nuclear genomes. These ndhF sequences were also compared with those from diploid or allotetraploid Triticeae species having the H, I, Ns, P, W, St, and Xm genomes. The cpDNA sequences were highly similar among diploid, allotetraploid, allohexaploid, and allooctoploid Triticeae accessions containing the St nuclear genome, with 0-6-nucleotide (nt) substitutions (0-0.8%) occurring between pairs of species. Neighbor-joining analysis of the sequences showed that the ndhF DNA sequences from species containing the St nuclear genome formed a strongly supported clade. The data indicated a strong preference for cpDNA inheritance from the St nuclear genome-containing parent in hybridizations between Triticeae species. This preference was independent of the presence of the H, I, Ns, P, W, and Xm nuclear genomes, the geographic distribution of the species, and the mode of reproduction. The data suggests that hybridizations having the St-containing parent as the female may be more successful.     

High-definition genome profiling for genetic marker discovery

Genetic mapping is a key step towards isolating genes and genetic markers associated with phenotypic traits by elucidating their genetic positions. The success of this approach depends on precision in pinpointing genetic positions and the effectiveness of the discovery process. Recent advances in microarray technology and the increasing availability of genomic information have provided an opportunity to use microarrays to scan effectively for genetic variations at the whole-genome scale, enabling the production of high-definition gene-based genetic maps, in combination with functional analyses and identification of trait-associated genetic marker candidates with high precision. In this review, we discuss the concept, process, tools and applications of microarray-based high-definition genetic analysis. This post-genomics approach should help to identify causative genetic variation by uniting genetic and functional information.     

Development of species-specific PCR primer sets for the detection of Leptospira

Spirochetes of the genus Leptospira infect animals and humans and are the causative agents for the emerging infectious disease leptospirosis. Rapid and simple assays for the identification of individual Leptospira species are currently not available. For identification of individual Leptospira species, PCR primers that detect the ompL1 gene sequence for the majority of pathogenic leptospires were developed in this study. The primer pairs detect Leptospira interrogans, Leptospira borgpetersenii, Leptospira kirschneri, Leptospira santarosai, Leptospira weilii and Leptospira noguchii, without cross-reacting with other Leptospira species. The development of the primers revealed a divergence of the ompL1 gene within L. interrogans, splitting this species into two separate groups. The species-specific primers will be especially useful in epidemiological studies and disease outbreak investigations for the detection of Leptospira species in human, animal and environmental samples.     

Sequence composition, organization, and evolution of the core Triticeae genome

We investigated the composition and the basis of genome expansion in the core Triticeae genome using Aegilops tauschii, the D-genome donor of bread wheat. We sequenced an unfiltered genomic shotgun (trs) and a methylation-filtration (tmf) library of A. tauschii, and analyzed wheat expressed sequence tags (ESTs) to estimate the expression of genes and transposable elements (TEs). The sampled D-genome sequences consisted of 91.6% repetitive elements, 2.5% known genes, and 5.9% low-copy sequences of unknown function. TEs constituted 68.2% of the D-genome compared with 50% in maize and 14% in rice. The DNA transposons constituted 13% of the D-genome compared with 2% in maize. TEs were methylated unevenly within and among elements and families, and most were transcribed which contributed to genome expansion in the core Triticeae genome. The copy number of a majority of repeat families increased gradually following polyploidization. Certain TE families occupied discrete chromosome territories. Nested insertions and illegitimate recombination occurred extensively between the TE families, and a majority of the TEs contained internal deletions. The GC content varied significantly among the three sequence sets examined ranging from 42% in tmf to 46% in trs and 52% in the EST. Based on enrichment of genic sequences, methylation-filtration offers one option, although not as efficient as in maize, for isolating gene-rich regions from the large genome of wheat.     

An RFLP species-specific DNA sequence for the A genome of rice.

A DNA sequence, pOs6.20, was cloned from the nuclear genome of cultivated rice (Oryza sativa L.) by hybridization with a human minisatellite sequence. At high hybridization stringency, a subfragment of the rice sequence, pOs6.20.3, detected low-copy restriction fragment length polymorphisms (RFLPs), which behaved as Mendelian genetic markers. This subfragment detected multicopy RFLPs between an indica and a javanica cultivar at medium hybridization stringency. The sequences detected by pOs6.20.3 at high hybridization stringency did not occur in rice species possessing the B, C, D, E, and F genomes. These results suggest that the RFLPs detected by this sequence can be placed on a genetic map of rice and that this sequence can be used as a species-specific probe for the A genome of rice.     

Studies on Morphological Evolution,Classification and Distribution of the Triticeae in China

_{The classification and the relationships among the genera of Chinese Triticeae were studied based on morphological characters with reference to geographical distribution and habitat conditions. The spike of Triticeae might have been derived from a panicled inflorescence like that in the Bromeae through a racemose inflorescence like the one in the Brachypodieae. There might be three evolutionary lines in the tribe. 1. Pedicels of the panicled inflorescence have become short and bracts decreased in size, which has resulted in a panicled spike with indefinite spikelets or false solitary spikelets at each node of rachis. The middle ribes of both glumes and lemmas and rachilla are not in a single plane. 2. A simple spike with usual solitary spikelets at each node of rachis has been derived from the raceme. The middle ribe of both glumes and lemmas and rachilla are in a single plane. 3. A cymose spike with 3-spikelets at each node of rachis has evolved from the cymose panicle. The glume on the central spikelet is behind the lemma, while those on the lateral spikelets are on lateral sides of the lemmas. From what we have described above Triticeae may be divided into three subtribes: Elyminae, Triticinae and Hordeinae. Then according to the morphological characters of glume, lemma and other organs as well as the habitats and distribution, the native and introduced triticeous plants are classified into 13 genera (Leymus, Elymus, Roegneria, Elytrigia, Aegilops, Triticum, Agropyron, Eremopyrum, Secale, Haynaldia, Psathyrostachys, Hordeum and Hystrix) and their relationships are also discussed meanwhile.}     

Evaluation of different species-specific PCR protocols for the detection of Vibrio tapetis

In this study the specificity and sensitivity of three primer pairs, Jvt1–Jvt2, VtF–VtR and VtKF–VtKR, for the detection of Vibrio tapetis were evaluated in parallel using 23 V. tapetis strains isolated from different mollusc and fish species and with different geographical origin, as well as 29 representatives of related Vibrio species. The three primer pairs amplified all the V. tapetis strains, regardless of their host or geographical origin. However, with primer sets VtF–VtR and VtKF–VtKR amplification products of the expected size were obtained from chromosomal DNA of some of the non-V. tapetis bacteria tested. The sensitivity of the three PCR detection methods was also different. The detection limit obtained with primer pairs Jvt1–Jvt2 and VtF–VtR was between 1 and 10 pg DNA/PCR tube (2–20 bacterial cells per reaction). The primer set VtKF–VtKR showed a reduction of sensitivity in at least one order of magnitude. The results were highly reproducible with all primer sets when using the same thermal cycler, although some differences were observed in the results obtained in different PCR machines. Based on the findings reported here, we propose the Jvt1–Jvt2 PCR protocol as the most adequate for an accurate detection of V. tapetis in diagnostic pathology as well as in epidemiological studies of this clam pathogen.