We examined the diversity, evolution, and genomic organization of retroelements in a wide range of gymnosperms. In total, 165 fragments of the reverse transcriptase (RT) gene domain were sequenced from PCR products using newly designed primers for gypsy-like retrotransposons and well-known primers for copia-like retrotransposons; representatives of long interspersed nuclear element (LINE) retroposons were also found. Gypsy and copia-like retroelements are a major component of the gymnosperm genome, and in situ hybridization showed that individual element families were widespread across the chromosomes, consistent with dispersion and amplification via an RNA intermediate. Most of the retroelement families were widely distributed among the gymnosperms, including species with wide taxonomic separation from the Northern and Southern Hemispheres. When the gymnosperm sequences were analyzed together with retroelements from other species, the monophyletic origin of plant copia, gypsy, and LINE groups was well supported, with an additional clade including badnaviral and other, probably virus-related, plant sequences as well as animal and fungal gypsy elements. Plant retroelements showed high diversity within the phylogenetic trees of both copia and gypsy RT domains, with, for example, retroelement sequences from Arabidopsis thaliana being present in many supported groupings. No primary branches divided major taxonomic clades such as angiosperms, monocotyledons, gymnosperms, or conifers or (based on smaller samples) ferns, Gnetales, or Sphenopsida (Equisetum), suggesting that much of the existing diversity was present early in plant evolution, or perhaps that horizontal transfer of sequences has occurred. Within the phylogenetic trees for both gypsy and copia, two clearly monophyletic gymnosperm/conifer clades were revealed, providing evidence against recent horizontal transfer. The results put the evolution of the large and relatively conserved genome structure of gymnosperms into the context of the diversity of other groups of plants.
It is shown that chromosome painting is as yet not possible for plants with very complex genomes, neither intra- nor interspecific. The reasons are inefficient blocking of dispersed repetitive sequences and insufficient signal intensity of short unique sequences. Future perspective are indicated.
The genomic organization of two different types of satellite DNA sequences was analysed by means of fluorescence in situ hybridization (FISH) and pulsed-field gel electrophoresis (PFGE) in barley. Satellite HvT01 was detected at all chromosome ends except the long arms of chromosomes 2 and 7. The unrelated satellite pAS1 was found at all chromosome ends except the long arm of chromosome 7 and at two interstitial sites, both located on the long arm of chromosome 4 on the standard karyotype. Southern and in situ hybridization further indicate that pAS1 also occurs interspersed in the barley genome. For most chromosome ends, the linear order of HvT01 and pAS1 could not be determined by in situ hybridization except at the short arms of chromosomes 2 and 6, where HvT01 is more distal than pAS1. This is confirmed by PFGE analysis, HvT01 being frequently associated with the telomeric repeat but not pAS1. Furthermore, we found that HvT01 occurred in clusters up to 1000 kb in size, whereas the pAS1 cluster had a maximum size of 500 kb. Sequence comparison revealed that both satellites are completely unrelated and differ considerably in their G + C contents.
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