[Allelic variants of the gene bamyl barley in Eastern European and central Asian areas].

The collections of varieties of spring barley cultivars from the Eastern European and Central Asian areas were analyzed by exonpecific PCR (EPIC) for beta-amylase genes. The endosperm beta-amylase gene (bamyl) was differentiated by the presence of 126 bp MITE insertion into intron 3 that is associated with low activity beta-amylase. The findings suggest that a low level of genetic variation for bamylgene within climatic zones is associated with individual breeding program for each climatic zone.

Genetic diversity of cultivated flax (Linum usitatissimum L.) germplasm assessed by retrotransposon-based markers.

Retrotransposon segments were characterized and inter-retrotransposon amplified polymorphism (IRAP) markers developed for cultivated flax (Linum usitatissimum L.) and the Linum genus. Over 75 distinct long terminal repeat retrotransposon segments were cloned, the first set for Linum, and specific primers designed for them. IRAP was then used to evaluate genetic diversity among 708 accessions of cultivated flax comprising 143 landraces, 387 varieties, and 178 breeding lines. These included both traditional and modern, oil (86), fiber (351), and combined-use (271) accessions, originating from 36 countries, and 10 wild Linum species. The set of 10 most polymorphic primers yielded 141 reproducible informative data points per accession, with 52% polymorphism and a 0.34 Shannon diversity index. The maximal genetic diversity was detected among wild Linum species (100% IRAP polymorphism and 0.57 Jaccard similarity), while diversity within cultivated germplasm decreased from landraces (58%, 0.63) to breeding lines (48%, 0.85) and cultivars (50%, 0.81). Application of Bayesian methods for clustering resulted in the robust identification of 20 clusters of accessions, which were unstratified according to origin or user type. This indicates an overlap in genetic diversity despite disruptive selection for fiber versus oil types. Nevertheless, eight clusters contained high proportions (70-100%) of commercial cultivars, whereas two clusters were rich (60%) in landraces. These findings provide a basis for better flax germplasm management, core collection establishment, and exploration of diversity in breeding, as well as for exploration of the role of retrotransposons in flax genome dynamics.

Analysis of plant diversity with retrotransposon-based molecular markers.

Retrotransposons are both major generators of genetic diversity and tools for detecting the genomic changes associated with their activity because they create large and stable insertions in the genome. After the demonstration that retrotransposons are ubiquitous, active and abundant in plant genomes, various marker systems were developed to exploit polymorphisms in retrotransposon insertion patterns. These have found applications ranging from the mapping of genes responsible for particular traits and the management of backcrossing programs to analysis of population structure and diversity of wild species. This review provides an insight into the spectrum of retrotransposon-based marker systems developed for plant species and evaluates the contributions of retrotransposon markers to the analysis of population diversity in plants.

[Using IRAP markers for analysis of genetic variability in populations of resource and rare species of plants].

Species-specific LTR retrotransposons were first cloned in five rare relic species of drug plants located in the Perm' region. Sequences of LTR retrotransposons were used for PCR analysis based on amplification of repeated sequences from LTR or other sites of retrotransposons (IRAP). Genetic diversity was studied in six populations of rare relic species of plants Adonis vernalis L. by means of the IRAP method; 125 polymorphic IRAP-markers were analyzed. Parameters for DNA polymorphism and genetic diversity of A. vernalis populations were determined.

Genetic variability in sunflower (Helianthus annuus L.) and in the Helianthus genus as assessed by retrotransposon-based molecular markers.

The inter-retrotransposon amplified polymorphism (IRAP) protocol was applied for the first time within the genus Helianthus to assess intraspecific variability based on retrotransposon sequences among 36 wild accessions and 26 cultivars of Helianthus annuus L., and interspecific variability among 39 species of Helianthus. Two groups of LTRs, one belonging to a Copia-like retroelement and the other to a putative retrotransposon of unknown nature (SURE) have been isolated, sequenced and primers were designed to obtain IRAP fingerprints. The number of polymorphic bands in H. annuus wild accessions is as high as in Helianthus species. If we assume that a polymorphic band can be related to a retrotransposon insertion, this result suggests that retrotransposon activity continued after Helianthus speciation. Calculation of similarity indices from binary matrices (Shannon's and Jaccard's indices) show that variability is reduced among domesticated H. annuus. On the contrary, similarity indices among Helianthus species were as large as those observed among wild H. annuus accessions, probably related to their scattered geographic distribution. Principal component analysis of IRAP fingerprints allows the distinction between perennial and annual Helianthus species especially when the SURE element is concerned.

Evolutionary conserved lineage of Angela-family retrotransposons as a genome-wide microsatellite repeat dispersal agent.

A detailed examination of 45 pea (Pisum sativum L.) simple sequence repeat (SSR) loci revealed that 21 of them included homologous sequences corresponding to the long terminal repeat (LTR) of a novel retrotransposon. Further investigation, including full-length sequencing, led to its classification as an RLC-Angela-family-FJ434420 element. The LTR contained a variable region ranging from a simple TC repeat (TC)(11) to more complex repeats of TC/CA, (TC)(12-30), (CA)(18-22) and was up to 146 bp in length. These elements are the most abundant Ty1/copia retrotransposons identified in the pea genome and also occur in other legume species. It is interesting that analysis of 63 LTR-derived sequences originating from 30 legume species showed high phylogenetic conservation in their sequence, including the position of the variable SSR region. This extraordinary conservancy led us to the proposition of a new lineage, named MARTIANS, within the Angela family. Similar LTR structures and partial sequence similarities were detected in more distant members of this Angela family, the barley BARE-1 and rice RIRE-1 elements. Comparison of the LTR sequences from pea and Medicago truncatula elements indicated that microsatellites arise through the expansion of a pre-existing repeat motif. Thus, the presence of an SSR region within the LTR seems to be a typical feature of this MARTIANS lineage, and the evidence gathered from a wide range of species suggests that these elements may facilitate amplification and genome-wide dispersal of associated SSR sequences. The implications of this finding regarding the evolution of SSRs within the genome, as well as their utilization as molecular markers, are discussed.

[IRAP-and REMAP-analyses of barley varieties of Odessa breeding].

Application of polylocus biallelic systems of PCR along with monolocus SSR-analysis is very promising approach for detailed characterization, differentiation and identification of crop varieties. Microsatellite sequences and LTR retratransposon fragments are known to be the most variable in plant genome. They can be used in PCR analysis as IRAP and REMAP. Conditions of IRAP and REMAP analyses of intra- and intervariety polymorphism of the barley varieties of Odessa breeding have been elaborated. The detailed genotype formulas are represented which reflect the intravariety polimorphism and make it possible to detect the changes in variety structure in the course of seed production process.

Mapping of major spot-type and net-type net-blotch resistance genes in the Ethiopian barley line CI 9819.

Net blotch of barley (Hordeum vulgare L.), caused by the fungal phytopathogen Pyrenophora teres Drechs. f. teres Smedeg., constitutes one of the most serious constraints to barley production worldwide. Two forms of the disease, the net form, caused by P. teres f. teres, and the spot form, caused by P. teres f. maculata, are differentiated by the type of symptoms on leaves. Several barley lines with major gene resistance to net blotch have been identified. Earlier, one of these was mapped in the Rolfi x CI 9819 cross to barley chromosome 6H, using a mixture of 4 Finnish isolates of P. teres f. teres. In this study, we used the same barley progeny to map resistance to 4 spot-type isolates and 4 net-type isolates of P. teres. With all net-type isolates, a major resistance gene was located on chromosome 6H, in the same position as described previously, explaining up to 88% of the phenotypic variation in infection response in the progeny. We designate this gene Rpt5. Several minor resistance genes were located on chromosomes 1H, 2H, 3H, 5H, and 7H. These minor genes were not genuinely isolate-specific, but their effect varied among isolates and experiments. When the spot-type isolates were used for infection, a major isolate-specific resistance gene was located on chromosome 5H, close to microsatellite marker HVLEU, explaining up to 84% of the phenotypic variation in infection response in the progeny. We designate this gene Rpt6. No minor gene effects were detected in spot-type isolates. The Ethiopian 2-rowed barley line CI 9819 thus carries at least 2 independent major genes for net-blotch resistance: Rpt5, active against net-type isolates; and Rpt6, active against specific spot-type isolates.

A movable feast: diverse retrotransposons and their contribution to barley genome dynamics.

Cellular genes comprise at most 5% of the barley genome; the rest is occupied primarily by retrotransposons. Retrotransposons move intracellularly by a replicative mechanism similar to that of retroviruses. We describe the major classes of retrotransposons in barley, including the two nonautonomous groups that were recently identified, and detail the evidence supporting our current understanding of their life cycle. Data from analyses of long contiguous segments of the barley genome, as well as surveys of the prevalence of full-length retrotransposons and their solo LTR derivatives in the genus Hordeum, indicate that integration and recombinational loss of retrotransposons are major factors shaping the genome. The sequence conservation and integrative capacity of barley retrotransposons have made them excellent sources for development of molecular marker systems.

Comparison of the utility of barley retrotransposon families for genetic analysis by molecular marker techniques.

The Sequence-Specific Amplification Polymorphism (S-SAP) method, and the related molecular marker techniques IRAP (inter-retrotransposon amplified polymorphism) and REMAP (retrotransposon-microsatellite amplified polymorphism), are based on retrotransposon activity, and are increasingly widely used. However, there have been no systematic analyses of the parameters of these methods or of the utility of different retrotransposon families in producing polymorphic, scorable fingerprints. We have generated S-SAP, IRAP, and REMAP data for three barley (Hordeum vulgare L.) varieties using primers based on sequences from six retrotransposon families (BARE-1, BAGY-1, BAGY-2, Sabrina, Nikita and Sukkula). The effect of the number of selective bases on the S-SAP profiles has been examined and the profiles obtained with eight MseI+3 selective primers compared for all the elements. Polymorphisms detected in the insertion pattern of all the families show that each can be used for S-SAP. The uniqueness of each transposition event and differences in the historic activity of each family suggest that the use of multiple retrotransposon families for genetic analysis will find applications in mapping, fingerprinting, and marker-assisted selection and evolutionary studies, not only in barley and other Hordeum species and related taxa, but also more generally.

Envelope-class retrovirus-like elements are widespread, transcribed and spliced, and insertionally polymorphic in plants.

Retrotransposons and retroviruses share similar intracellular life cycles and major encoded proteins, but retrotransposons lack the envelope (env) critical for infectivity. Retrotransposons are ubiquitous and abundant in plants and active retroviruses are known in animals. Although a few env-containing retroelements, gypsy-like Athila, Cyclops, and Calypso and copia-like SIRE-1, have been identified in plants, the general presence and functionality of the domain remains unclear. We show here that env-class elements are present throughout the flowering plants and are widely transcribed. Within the grasses, we show the transcription of the env domain itself for Bagy-2 and related retrotransposons, all members of the Athila group. Furthermore, Bagy-2 transcripts undergo splicing to generate a subgenomic env product as do those of retroviruses. Transcription and the polymorphism of their insertion sites in closely related barley cultivars suggests that at least some are propagationally active. The putative ENV polypeptides of Bagy-2 and rice Rigy-2 contain predicted leucine zipper and transmembrane domains typical of retroviral ENVs. These findings raise the prospect of active retroviral agents among the plants.

Active retrotransposons are a common feature of grass genomes.

A large fraction of the genomes of grasses, members of the family Graminae, is composed of retrotransposons. These elements resemble animal retroviruses in their structure and possess a life cycle similar to theirs that includes transcription, translation, and integration of daughter copies. We have investigated if retrotransposons are generally transcribed in the grasses and other plants, and whether the various families of elements are translationally and integrationally active in multiple grass species. A systematic search of 7.8 x 10(5) publicly available expressed sequence tags from plants revealed widespread retrotransposon transcripts at a frequency of one in 1,000. Monocot retrotransposons found relatively more expressed sequence tags from non-source species than did those of dicots. Antibodies were raised to the capsid protein, GAG, of BARE-1, a transcribed and translated copia-like retrotransposon of barley (Hordeum vulgare). These detected immunoreactive proteins of sizes identical to those of the BARE-1 GAG and polyprotein, respectively, in other species of the tribe Triticeae as well as in oats (Avena sativa) and rice (Oryza sativa). Retrotransposon-based markers showed integrational polymorphisms for BARE-1 in different subfamilies of the Graminae. The results suggest that grasses share families of transcriptionally, translationally, and integrationally active retrotransposons, enabling a comparative and integrative approach to understanding the life cycle of retrotransposons and their impact on the genome.

Application of BARE-1 retrotransposon markers to the mapping of a major resistance gene for net blotch in barley.

Net blotch, which is caused by the fungus Pyrenophoral teres Drechs. f. teres Smedeg., presents a serious problem for barley production worldwide, and the identification and deployment of sources of resistance to it are key objectives for many breeders. Here, we report the identification of a major resistance gene, accounting for 65% of the response variation, in a cross between the resistant line C19819 and the susceptible cv. Rolfi. The resistance gene was mapped to chromosome 6H with the aid of two recently developed systems of retrotransposon-based molecular markers, REMAP and IRAP. A total of 239 BARE-1 and Sukkula retrotransposon markers were mapped in the cross, and the 30-cM segment containing the locus with significant resistance effect contained 26 of the markers. The type and local density of the markers should facilitate future map-based cloning of the resistance gene as well as manipulation of the resistance through backcross breeding.

[The mapping of the barley genome by RAPD analysis using double haploid strains]. / Kartirovanie genoma iachmenia RAPD-analizom s ispol'zovaniem digaploidnykh linii.

A map of the barley genome consisting of 107 loci was constructed using double haploid lines. 33 RAPD loci marks all barley chromosomes. The total length of the obtained map is 1047 centiMorgans (cM) with a 9.8 cM average distance between markers. 7 linkage groups was identified as certain chromosomes. The distribution of the markers was analyzed, comparison with other published maps was made. Some statistical considerations are presented. Alternative strategies of gene mapping are considered.

Genome evolution of wild barley (Hordeum spontaneum) by BARE-1 retrotransposon dynamics in response to sharp microclimatic divergence.

The replicative spread of retrotransposons in the genome creates new insertional polymorphisms, increasing retrotransposon numbers and potentially both their share of the genome and genome size. The BARE-1 retrotransposon constitutes a major, dispersed, active component of Hordeum genomes, and BARE-1 number is positively correlated with genome size. We have examined genome size and BARE-1 insertion patterns and number in wild barley, Hordeum spontaneum, in Evolution Canyon, Lower Nahal Oren, Mount Carmel, Israel, along a transect presenting sharply differing microclimates. BARE-1 has been sufficiently active for its insertional pattern to resolve individuals in a way consonant with their ecogeographical distribution in the canyon and to distinguish them from provenances outside the canyon. On both slopes, but especially on the drier south-facing slope, a simultaneous increase in the BARE-1 copy number and a decrease in the relative number lost through recombination, as measured by the abundance of solo long terminal repeats, appear to have driven the BARE-1 share of the genome upward with the height and dryness of the slope. The lower recombinational loss would favor maintenance of more full-length copies, enhancing the ability of the BARE-1 family to contribute to genome size growth. These local data are consistent with regional trends for BARE-1 in H. spontaneum across Israel and therefore may reflect adaptive selection for increasing genome size through retrotransposon activity.

Retrotransposon BARE-1: expression of encoded proteins and formation of virus-like particles in barley cells

Retrotransposons are ubiquitous and major components of plant genomes, and are characteristically retroviral-like in their genomic structure and in the major proteins encoded. Nevertheless, few have been directly demonstrated to be transcribed or reverse transcribed. The BARE-1 retrotransposon family of barley (Hordeum vulgare) is highly prevalent, actively transcribed, and contains well conserved functional regions. Insertion sites for BARE-1 are highly polymorphic in the barley genome. Here we show that BARE-1 is translated and the capsid protein (GAG) and integrase (IN) components of the predicted polyprotein are processed into polypeptides of expected size. Some of the GAG sediments as virus-like particles together with IN and with BARE-1 cDNA. Reverse transcriptase activity is also present in gradient fractions containing BARE-1 translation products. Virus-like particles have also been visualized in fractions containing BARE-1 components. Thus BARE-1 components necessary for carrying out the life cycle of an active retrotransposon appear to be present in vivo, and to assemble. This would suggest that post-translational mechanisms may be at work to prevent rapid genome inflation through unrestricted integration.

Phylogeny and transpositional activity of Ty1-copia group retrotransposons in cereal genomes.

The Ty1-copia group retrotransposon populations of barley (Hordeum vulgare) and bread wheat (Triticum aestivum) have been characterised by degenerate PCR and sequence analysis of fragments of the reverse transcriptase genes. The barley population is comprised of a highly heterogeneous set of retrotransposons, together with a collection of sequences that are closely related to the BARE-1 element. Wheat also contains a highly diverse Ty1-copia retrotransposon population, together with a less prominent BARE-1 subgroup. These data have been combined with previously published Gramineae sequences to construct a composite phylogenetic tree for this class of retrotransposons in cereal grasses. The analysis indicates that the ancestral Gramineae genome contained a heterogeneous population of Ty1-copia group retrotransposons, the descendants of which have proliferated to differing degrees in present-day species. Lastly, the level of recent transpositional activity of two Ty1-copia elements has been estimated by measuring their insertional polymorphism within species. Both transposons are highly polymorphic within all species tested. These data suggest that transposition proficiency may be a common and evolutionarily stable feature of the Ty1-copia group retrotransposons of cereal grasses.

Structure, functionality, and evolution of the BARE-1 retrotransposon of barley.

The BARE-1 retrotransposon is a major, active component of the genome of barley (Hordeum vulgare L.) and other Hordeum species. Copia-like in its organization, it consists of 1.8-kb long terminal repeats bounding an internal domain of 5275 bp which encodes a predicted polyprotein of 1301 residues. The polyprotein contains the key residues, structural motifs, and conserved regions associated with retroviral and retrotransposon GAG, aspartic proteinase, integrase, reverse transcriptase, and RNaseH polypeptides. BARE-1 is actively transcribed and translated. As part of our effort to understand the evolution and function of BARE-1, we have examined its copy number and localization. Full-length members of the BARE-1 family constitute 2.8% of the barley genome. Globally, they are dispersed throughout the genome, excepting the centromeric, telomeric, and NOR regions. Locally, BARE-1 occurs more commonly in repetitive DNA than in coding regions, forming clusters of nested insertions. Both barley and other Hordeum genomes contain a high proportion of BARE-1 solo LTRs. New techniques have been developed which exploit the insertion site polymorphism generated by BARE-1 integration to produce molecular markers for breeding, biodiversity, and mapping applications.

[Genetic polymorphism in barley detected by arbitrary primers]. / Geneticheskii polimorfizm iachmenia, vyiavlennyi PTsR s proizvol'nymi praimerami.

Genetics and breeding studies require effective methods for polymorphism analysis that allow one to classify varieties and to determine phylogenetic interactions between plant species. A variant of the polymerase chain reaction for DNA amplification with arbitrary primers (RAPD) was used to determine genetic distances between Hordeum vulgare varieties and to integrate of the varieties into groups. The dendrogram of relations between species from the genus Hordeum and species of some cultivated cereals was constructed on the basis of RAPD analysis.

[The genetic polymorphism of cereals demonstrated by PCR with random primers]. / Geneticheskii polimorfizm zlakovykh rastenii pri pomoshchi PTsR s proizvol'nymi praimerami.

Polymerase chain reaction of DNA amplification with the use of random primers is a new approach in investigations of genome specificity. Nucleotide sequences that showed polymorphism in RFLP analysis were used as primers. Optimal temperature conditions and Mg2+ concentrations were determined for studying inter- and intraspecific DNA polymorphism in the most important cereals.