Björn Salomon

Characterization of a family of tandemly repeated DNA sequences in Triticeae.

The recombinant plasmid dpTa1 has an insert of relic wheat DNA that represents a family of tandemly organized DNA sequences with a monomeric length of approximately 340 bp. This insert was used to investigate the structural organization of this element in the genomes of 58 species within the tribe Triticeae and in 7 species representing other tribes of the Poaceae. The main characteristic of the genomic organization of dpTa1 is a classical ladder-type pattern which is typical for tandemly organized sequences. The dpTa1 sequence is present in all of the genomes of the Triticeae species examined and in 1 species from a closely related tribe (Bromus inermis, Bromeae). DNA from Hordelymus europaeus (Triticeae) did not hybridize under the standard conditions used in this study. Prolonged exposure was necessary to obtain a weak signal. Our data suggest that the dpTa1 family is quite old in evolutionary terms, probably more ancient than the tribe Triticeae. The dpTa1 sequence is more abundant in the D-genome of wheat than in other genomes in Triticeae. DNA from several species also have bands in addition to the tandem repeats. The dpTa1 sequence contains short direct and inverted subrepeats and is homologous to a tandemly repeated DNA sequence from Hordeum chilense.

Characterization and analysis of microsatellite loci in Elymus caninus (Triticeae: Poaceae)

Abstract Microsatellites are highly variable DNA sequences that can be used as markers for the genetic analysis of plants. The potential of microsatellite markers for use in a genetic diversity study in Elymus species was evaluated. Genomic libraries of Elymus caninus were constructed. The libraries were screened with two dinucleotide, (GA)n and (GT)n, and two trinucleotide repeats, (TCT)n and (CAC)n. A total of 19 positive clones were found for the two dinucleotide repeats; no positive clone was found for the trinucleotide repeats. Positive clones were sequenced to confirm the presence of microsatellites and to generate polymerase chain reaction (PCR) primers based on the sequences flanking the microsatellite. All sequenced (GA)n clones have repeats of n>10; over half of the (GT)n microsatellites have n<10 repeats. Primer pairs were designed and evaluated for 8 selected microsatellites. PCR products were amplified from 15 Elymus caninus accessions. The number of alleles found for the eight loci varied from 1 for ECGA89 and ECGT35 to 13 for ECGA22, as determined by non-denaturing polyacrylamide electrophoresis. Six microsatellite loci were found to be polymorphic in E. caninus. The eight primer pairs were tested on three other species; seven were successful in amplifying DNA from Elymus alaskanus and E. mutabilis, and four amplified DNA from E. caucasicus. Based on these results, microsatellites appear to be useful markers in detecting variation in E. caninus.

Genomic groups, morphology, and sectional delimitation in EurasianElymus (Poaceae, Triticeae)

Seven tetraploid species ofElymus, viz.E. sibiricus, E. caninus, E. gmelinii, E. semicostatus, E. caucasicus, E. parviglume, andE. longearistatus subsp.canaliculatus, representing five sections were studied morphologically and used in interspecific hybridizations. The aim was to investigate whether the present sectional delimitation of the genus was in agreement with genomic data and if there was a correlation between genome constitution and morphology. The study revealed: (i) further information on the genomic affinities between the different species, (ii) that there is no congruence between genome constitution of the species and current sectional delimitation, and (iii) that there is a correlation between genome constitution and morphology in the palea apex shape and in the size of cilia of the palea.

Genetic diversity and structure in a natural Elymus caninus population from Denmark based on microsatellite and isozyme analyses

Abstract. Genetic diversity in a natural Elymus caninus population from Denmark was assessed using isozyme and microsatellite markers. A total of 119 individuals from 46 maternal plants were assayed. Microsatellite loci are shown to display higher levels of variation than isozyme loci. The mean number of alleles per locus was 1.04 for isozymes and 1.38 for microsatellites. The percentage of polymorphic loci for isozymes and microsatellites was 4.7% and 23.6% across the maternal plant, respectively. The genetic diversity at population level was 0.1 for isozymes, and 0.63 for microsatellites. The mean genetic diversity at maternal plant level was 0.027 for isozyme loci and 0.117 for microsatellite loci. The average of total allozyme diversity (HT) was 0.22. The average of total microsatellite diversity was 0.56. Isozyme and microsatellite variation showed the same pattern of differentiation between maternal plants. More than 75% total genetic diversity was found among maternal plants. About 25% total genetic diversity was detected within maternal plants. Ten (22.7%) maternal plants produced heterozygous offspring at allozyme loci, and 30 (68.2%) maternal plants gave heterozygous offspring at microsatellite loci. Both types of markers revealed a relatively high genetic diversity in this population.

Genetic variation and differentiation in Nordic populations of Elymus alaskanus (Scrib. ex Merr.) Löve (Poaceae)

Abstract To gain information on the extent and nature of genetic variation in Elymus alaskanus, levels and distribution of genetic variation were assessed within and among 13 populations originating from Iceland, Norway, Sweden and Russia using allozymes. The results showed that four (30.7%) of the 13 loci were polymorphic within the species, while the mean percentage of polymorphic loci within the populations was 1.9%. The mean number of alleles per locus for the species was 1.8 and 1.02 across the populations. Genetic diversity at the species level was low (Hes=0.135), and mean population diversity was notably lower (Hep=0.005). A high degree of genetic differentiation was observed among populations. The salient points emerging from this study are: (1) statistically significant differences were found in allele frequencies among populations for every polymorphic locus (P<0.001), (2) the high mean coefficient of gene differentiation (GST) showed that 95% of the total allozyme variation was attributable to differences among populations, and (3) relatively high genetic distances between the populations were obtained (mean D=0.16). The Norwegian populations had the highest genetic diversity as compared with the other populations. Geographical comparisons revealed three different groups of populations clearly differentiated, i.e. Scandinavia (Norway and Sweden), Iceland and Russia. Cluster and principal coordinates analyses revealed the same genetic patterns of relationships among populations. Generally, this study indicates that E. alaskanus contains low allozymic variation in its populations. The implications of these results for the conservation of the species are discussed.

Levels and distribution of allozyme and RAPD variation in populations of Elymus fibrosus (Schrenk) Tzvel. (Poaceae).

To study the magnitude and nature of genetic variation in E. fibrosus, the levels and distribution of allozyme and RAPD variations were investigated in populations collected from Finland and Russia. The results obtained from the allozyme and RAPD studies were compared to each other in 10 of the populations. The allozyme analysis showed that 6 of 12 presumed loci (50%) were polymorphic within the species, while the mean number of polymorphic loci within populations was 4.8%. The mean number of allele per locus for the species was 1.5 and 1.05 across the populations. Genetic diversity at the species level was low (Hes = 0.025), and the mean population genetic diversity was even lower (Hep = 0.007). Both these values were much lower than the average for other Elymus and self-fertilising species. The largest proportion of the total allozyme diversity was found among, rather than within the populations (GST = 0.70). The allozyme genetic distances between the populations did not reflect geographic distances. Cluster and principal coordinates analyses revealed the same allozyme relationship patterns among the populations. A comparison of allozyme and RAPD variation in 10 of the populations showed differences in the amount of genetic variation. The RAPD analysis revealed higher levels of variation (Ap = 1.19, Pp = 20.3 and Hep = 0.09) than the allozyme one) Ap = 1.06, Pp = 5.8 and Hep = 0.008). For both markers, the largest proportion of the total gene diversity was found among the populations studied (Gst = 0.63 for RAPDs and Gst = 0.65 for allozyme). In contrast to the allozyme analysis, the RAPD based genetic distances did reflect geographic distances. The cluster and principal coordinates analyses showed different grouping of populations for each data set. There was a positive, but not significant, correlation (r = 0.41) between the genetic distance matrices resulting from these markers. Regional comparison revealed that the Finnish populations had a higher diversity than the Russian ones. Generally, this study indicates that E. fibrosus contains low genetic variation in its populations. The results are discussed in the context of conservation of the species.

Distribution of allozymic alleles and genetic diversity in the American Barley Core Collection

Abstract A survey of allozymic alleles and genetic diversity was made for 151 accessions of the American Barley Core Collection. A total of 25 alleles at ten loci were observed. Two loci were monomorphic. The average diversity index for individual loci ranged between 0.026 and 0.649. Most significant differences in allelic frequency and genetic diversity value were found between spring and winter barley. Spring barley showed a greatly higher average diversity than winter barley (t=2.124, P=0.071). The smallest differences in allelic frequencies and diversity values were observed between the two geographical regions, North and South America. Rare alleles were detected only in a few accessions. Seven rare alleles were associated with spring barley. The genetic similarities among the 151 accessions ranged from 0.20 to 1.00, which showed that a high level of genetic variability exists in this set of core accessions. Cluster analysis and principal coordinate analysis did not give clear-cut separation of different types of barley, but most of the winter barley accessions were closely associated.

Microsatellite polymorphism and genetic differentiation in three Norwegian populations of Elymus alaskanus (Poaceae)

Abstract. Variation at seven microsatellite loci was investigated in three local E. alaskanus populations from Norway and microsatellite variation was compared with allozyme variation. The percentage of polymorphic loci was 81%, the mean number of alleles per polymorphic locus was 5.7 and expected heterozygosity was 0.37. An F-statistic analysis revealed an overall 48% deficit of heterozygotes over Hardy-Weinberg expectations. Gene diversity is mainly explained by the within population component. The averaged between population differentiation coefficient, Fst, over 7 loci is only 0.13, which accounts for only 13% of the whole diversity and was contrary to allozyme analysis. The mean genetic distance between populations was 0.12. However, a χ2 -test showed that allele frequencies were different (p < 0.05) among the populations at 5 of the 7 loci. In comparison with the genetic variation detected by allozymes, microsatellite loci showed higher levels of genetic variation. Microsatellite analysis revealed that population H10576 possesses the lowest genetic variation among the tested three populations, which concur with allozyme analysis. The dendrogram generated by microsatellites agreed very well with allozymic data. Our results suggest that natural selection may be an important factor in shaping the genetic diversity in these three local E. alaskanus populations. Possible explanations for deficit heterozygosity and incongruence between microsatellites and allozymes are discussed.

Genetic diversity among East Asian accessions of the barley core collection as revealed by six isozyme loci

Abstract Studies of allelic variations at six isozyme loci revealed genetic diversity of 380 East Asian accessions of the Barley Core Collection. Genetic variation was found in both cultivars and landraces in different regions. Allelic variations at the Aco-1 and Aco-2 loci were detected for East Asian barley for the first time. Moreover, the Aco-1 locus displayed the highest genetic diversity among the six loci assayed. Indian cultivars showed the highest diversity, followed by Korean and Chinese cultivars. Landraces from Bhutan and Nepal showed the lowest diversity. Cultivars had generally higher diversity than landraces within as well as among regions. The cluster analysis of genetic identity showed that all landraces from different countries can be placed in one group; the cultivars from Japan, India and Korea each form independent groups. Gpi-1 Gu, Pgd-1 Tj, Aco-1 Si, Ndh-2 D and Aco-2 A were rare alleles found in only a few accessions of 6-rowed barley. The Pgd-2 Tn allele was very rare in East Asian accessions.

Cytogenetics and Morphology of Elymus panormitanus var. Heterophyllus and Its Relationship to Elymus panormitanus var. Panormitanus (Poaceae: Triticeae)

Elymus panormitanus var. heterophyllus, PI-235086, was collected in Israel and became part of the National Plant Germplasm System as Elymus caninus L. in 1956. Bivalent pairing at metaphase I (MI) in E. panormitanus var. heterophyllus (2n = 42) was typical of other allohexaploids within the Triticeae. However, chromosome pairing analysis at MI of the tetraploid hybrids with Pseudoroegneria spicata (2n = 14, SS) and the pentaploid hybrids with Pseudoroegneria stipifolia (2n = 28, SSSS), Elymus lanceolatus (2n = 28, SSHH), E. panormitanus (2n = 28, SSYY), and Elymus nevski (2n = 28, SSYY) indicated that two of the three genomes of E. panormitanus var. heterophyllus were at least partially homologous to the S genome and confirmed the presence of a Y genome. Cluster analysis of 18 key characters separated E. panormitanus var. heterophyllus from E. panormitanus However, the continuous variation between the two taxa made taxonomic separation difficult unless the samples represented the two extremes. In this unique case, two taxa-E. panormitanus var. heterophyllus and E. panormitanus-were very close morphologically but different genomically. Elymus panormitanus var. heterophyllus is a hexaploid (SSSSYY; 2n = 42) and E. panormitanus is an allotetraploid (SSYY; 2n = 28).