The genus Elatine contains ca 25 species, all of which are small, herbaceous annuals distributed in ephemeral waters on both hemispheres. However, due to a high degree of morphological variability (as a consequence of their amphibious life-style), the taxonomy of this genus remains controversial. Thus, to fill this gap in knowledge, we present a detailed molecular phylogenetic study of this genus based on nuclear (rITS) and plastid (accD-psaI, psbJ-petA, ycf6-psbM-trnD) sequences using 27 samples from 13 species. On the basis of this phylogenetic analysis, we provide a solid phylogenetic background for the modern taxonomy of the European members of the genus. Traditionally accepted sections of this tree (i.e., Crypta and Elatinella) were found to be monophyletic; only E. borchoni—found to be a basal member of the genus—has to be excluded from the latter lineage to achieve monophyly. A number of taxonomic conclusions can also be drawn: E. hexandra, a high-ploid species, is most likely a stabilised hybrid between the main sections; E. campylosperma merits full species status based on both molecular and morphological evidence; E. gussonei is a more widespread and genetically diverse species with two main lineages; and the presence of the Asian E. ambigua in the European flora is questionable. The main lineages recovered in this analysis are also supported by a number of synapomorphic morphological characters as well as uniform chromosome counts. Based on all the evidence presented here, two new subsections within Elatinella are described: subsection Hydropipera consisting of the temperate species of the section, and subsection Macropodae including the Mediterranean species of the section.
Assessment of genetic relationships among Secale taxa by using ISSR and IRAP markers and the chromosomal distribution of the AAC microsatellite sequence
In most cereals, coding sequences account for less than 20% of the genome (Flavell et al., 1977;Barakat et al., 1997); the remaining part is composed mainly of repetitive sequences, among which microsatellites and retrotransposons are of particular importance. Retrotransposons are ubiquitous and abundant components of grass genomes, constituting a major fraction of repetitive sequences (approximately 10%-60% of the genome). In many species there is a positive correlation between the copy number of retrotransposons and genome size (Pearce et al., 1996;Vicient et al., 2001;Schulman et al., 2004). It is thought that even among individuals within one population there are differences in copy numbers of a given retrotransposon. Retrotransposons are excellent tools for detecting genetic diversity as they are major generators of genomic changes. Sequences generated from retrotransposon-based molecular markers are often more polymorphic than sequences generated from random amplified polymorphic DNA (RAPD), amplified fragment length polymorphism (AFLP), or restriction fragment length polymorphism (RFLP). Detection of inter-retrotransposon amplified polymorphisms (IRAPs) became a retrotransposon-based fingerprinting technique. IRAP markers are generated by amplification of sequences, embedded between 2 retrotransposons, using outward-facing primers annealing to long terminal repeat (LTR) target sequences. This marker system was used for the first time in barley, based on the BARE-1 retrotransposon (Kalendar et al., 1999;Vicient et al., 1999). It was also used in genetic studies of the diversity or phylogenetic relationships of Oryza L.
Main conclusion The analysis of early generations of triticale showed numerous rearrangements of the genome. Complexed transformation included loss of chromosomes, t-heterochromatin content changes and the emergence of retrotransposons in new locations.This study investigated certain aspects of genomic transformations in the early generations (F5 and F8) of the primary octoploid triticale derived from the cross of hexaploid wheat with the diploid rye. Most of the plants tested were hypoploid; among eliminated chromosomes were rye chromosomes 4R and 5R and variable number of wheat chromosomes. Wheat chromosomes were eliminated to a higher extent. The lower content of telomeric heterochromatin was also found in rye chromosomes in comparison with parental rye. Studying the location of selected retrotransposons from Ty1-copia and Ty3-gypsy families using fluorescence in situ hybridization revealed additional locations of these retrotransposons that were not present in chromosomes of parental species. ISSR, IRAP and REMAP analyses showed significant changes at the level of specific DNA nucleotide sequences. In most cases, the disappearance of certain types of bands was observed, less frequently new types of bands appeared, not present in parental species. This demonstrates the scale of genome rearrangement and, above all, the elimination of wheat and rye sequences, largely due to the reduction of chromosome number. With regard to the proportion of wheat to rye genome, the rye genome was more affected by the changes, thus this study was focused more on the rye genome. Observations suggest that genome reorganization is not finished in the F5 generation but is still ongoing in the F8 generation.
Polyploidy is an important event and major force in plant speciation. Amongst the polyploids, allopolyploids have attracted special attention to investigate genetic and epigenetic mechanisms. Also, they are the means for the development of new genotypes and genomic combinations to facilitate genetic enhancement and agricultural productivity. Whereas natural allopolyploids are genetically stable and well adapted, the newly synthesized ones are highly unstable. This instability is manifested into alterations at genomic and/or phenotypic level. Here we present the phenomenon of direct chromosome/chromatin elimination from pollen mother cells (PMCs) in wheat-rye hybrids as one aspect of instability leading to irregular meiosis and disturbances in meiotic process. One of the prominent irregularities noticed is peripherally separated uncondensed or pycnotic masses of chromatin in all meiotic stages. We have observed that this chromatin undergoes elimination by budding-like way, whereby a "mini-cell" is created. It was also found that nucleoli are the first to be eliminated along with a small mass of chromatin. By means of GISH we have shown that both rye and wheat chromatin might be eliminated. In the separated groups of chromosomes/ chromatin neither DNaseI nor DNase II activity was detected. Immunolocalization of tubulin allowed for differentiation between chromatin elimination from microspores and elimination from earlier stages of meiosis. It was noticeable, that in microspores special cytoskeleton structure pushing micronuclei out from the cells was created. Elimination occurred before and after meiosis as well as in each stage of meiotic division, but its intensity varied, depending on the PMC. The basis of the elimination mechanism might be the same as in cytomixis, because both phenomena share common symptoms, although cytomixis per se was rare in the analyzed hybrids.
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