Microsatellite megatracts in the maize (Zea mays L.) genome.

Long tracts (megatracts) of (CAG)n, (TAG)n, and (GAA)n microsatellite sequences capable of forming composite DNA segments were found in the maize (Zea mays L.) genome. Some of the (CAG)n and (TAG)n megatracts were organized in clusters of up to 1 Mb on several chromosomes, as detected by fluorescence in situ hybridization (FISH), as well as on extended DNA fibers. Extensive polymorphism was found among different maize inbred lines with respect to the number and size of microsatellite megatract clusters on the A chromosomes. Polymorphism was also common among B chromosomes of different nuclei in the inbred line Zapalote Chico. Different retrotransposable elements were often inserted into the microsatellite tracts. Size variation in some (TAG)n and (GAA)n megatracts was observed in consecutive generations among siblings of the inbred lines, indicating that these loci are highly unstable and predisposed to dynamic mutations similar to those described in mammalian systems.

Complete sequence analysis of transgene loci from plants transformed via microprojectile bombardment.

A substantial literature exists characterizing transgene locus structure from plants transformed via Agrobacterium and direct DNA delivery. However, there is little comprehensive sequence analysis of transgene loci available, especially from plants transformed by direct delivery methods. The goal of this study was to completely sequence transgene loci from two oat lines transformed via microprojectile bombardment that were shown to have simple transgene loci by Southern analysis. In line 3830, transformed with a single plasmid, one major and one of two minor loci were completely sequenced. Both loci exhibited rearranged delivered DNA and flanking genomic sequences. The minor locus contained only 296 bp of two non-contiguous fragments of the delivered DNA flanked by genomic (filler) DNA that did not originate from the integration target site. Predicted recognition sites for topoisomerase II and a MAR region were observed in the transgene integration target site for this non-functional minor locus. Line 11929, co-transformed with two different plasmids, had a single relatively simple transgene locus composed of truncated and rearranged sequences from both delivered DNAs. The transgene loci in both lines exhibited multiple transgene and genomic DNA rearrangements and regions of scrambling characteristic of complex transgene loci. The similar characteristics of recombined fragments and junctions in both transgenic oat lines implicate similar mechanisms of transgene integration and rearrangement regardless of the number of co-transformed plasmids and the level of transgene locus complexity.

Genomic interspersions determine the size and complexity of transgene loci in transgenic plants produced by microprojectile bombardment.

The structure of transgene loci in six transgenic allohexaploid oat (Avena sativa L.) lines produced using microprojectile bombardment was characterized using fluorescence in situ hybridization (FISH) on extended DNA fibers (fiber-FISH). The transgene loci in five lines were composed of multiple copies of delivered DNA interspersed with genomic DNA fragments ranging in size from ca. 3 kb to at least several hundred kilobases, and in greater numbers than detected using Southern blot analysis. Although Southern analysis predicted that the transgene locus in one line consisted of long tandem repeats of the delivered DNA, fiber-FISH revealed that the locus actually contained multiple genomic interspersions. These observations indicated that transgene locus size and structure were determined by the number of transgene copies and, possibly to a greater extent, the number and the length of interspersing genomic DNA sequences within the locus. Large genomic interspersions detected in several lines were most likely the products of chromosomal breakage induced either by tissue culture conditions or, more likely, by DNA delivery into the nucleus using microprojectile bombardment. We propose that copies of transgene along with other extrachromosomal DNA fragments are used as patches to repair double-strand breaks (DSBs) in the plant genome resulting in the formation of transgene loci.

Genome-specific repetitive DNA and RAPD markers for genome identification in Elymus and Hordelymus.

We have developed RFLP and RAPD markers specific for the genomes involved in the evolution of Elymus species, i.e., the St, Y, H, P, and W genomes. Two P genome specific repetitive DNA sequences, pAgc1 (350 bp) and pAgc30 (458 bp), and three W genome specific sequences, pAuv3 (221 bp), pAuv7 (200 bp), and pAuv13 (207 bp), were isolated from the genomes of Agropyron cristatum and Australopyrum velutinum, respectively. Attempts to find Y genome specific sequences were not successful. Primary-structure analysis demonstrated that pAgc1 (P genome) and pAgc30 (P genome) share 81% similarity over a 227-bp stretch. The three W genome specific sequences were also highly homologous. Sequence comparison analysis revealed no homology to sequences in the EMBL-GenBank databases. Three to four genome-specific RAPD markers were found for each of the five genomes. Genome-specific bands were cloned and demonstrated to be mainly low-copy sequences present in various Triticeae species. The RFLP and RAPD markers obtained, together with the previously described H and St genome specific clones pHch2 and pP1Taq2.5 and the Ns genome specific RAPD markers were used to investigate the genomic composition of a few Elymus species and Hordelymus europaeus, whose genome formulas were unknown. Our results demonstrate that only three of eight Elymus species examined (the tetraploid species Elymus grandis and the hexaploid species Elymus caesifolius and Elymus borianus) really belong to Elymus.

A study of 28 Elymus species using repetitive DNA sequences.

Four repetitive DNA sequences cloned from the barley (Hordeum vulgare) genome and common for different Triticeae species were used for a molecular study of phylogenetic relationships among 28 Elymus species. Two wild Hordeum species (H genome), two Pseudoroegneria species (S genome), Agropyron cristatum (P genome), and Australopyrum velutinum (W genome) were included as genomic representatives for the genomes that supposedly were involved in the evolution of the genus Elymus. Our results are essentially congruent with the genomic classification system. This study demonstrates that Elymus is not a monophyletic genus. Based on an analysis of Southern blot hybridization we could discriminate between SY and SH species owing to the strong specific hybridization pattern of the H genome. Hexaploid SYH species gave a hybridization pattern similar to SH species for the same reason. The results support the genomic composition of Elymus batalinii as SYP and also indicated the presence of at least one H genome in Elymus enysii with a hitherto unknown genomic constitution. Elymus erianthus had a hybridization pattern distinctly different from all other species in the investigation. Key words : Elymus, RFLP, phylogeny, repetitive DNA.

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.

Phylogenetic analysis of the genus Hordeum using repetitive DNA sequences.

A set of six cloned barley (Hordeum vulgare) repetitive DNA sequences was used for the analysis of phylogenetic relationships among 31 species (46 taxa) of the genus Hordeum, using molecular hybridization techniques. in situ hybridization experiments showed dispersed organization of the sequences over all chromosomes of H. vulgare and the wild barley species H. bulbosum, H. marinum and H. murinum. Southern blot hybridization revealed different levels of polymorphism among barley species and the RFLP data were used to generate a phylogenetic tree for the genus Hordeum. Our data are in a good agreement with the classification system which suggests the division of the genus into four major groups, containing the genomes I, X, Y, and H. However, our investigation also supports previous molecular studies of barley species where the unique position of H. bulbosum has been pointed out. In our experiments, H. bulbosum generally had hybridization patterns different from those of H. vulgare, although both carry the I genome. Based on our results we present a hypothesis concerning the possible origin and phylogeny of the polyploid barley species H. secalinum, H. depressum and the H. brachyantherum complex.

Is there a connection between genomic changes and wide hybridization?

The structural organization of a set of highly repetitive DNA sequences (HRS) of barley (Hordeum vulgare) was studied by blot-hybridization in the genomes of seven Hordeum L. species and several Hordeum x Secale hybrids. The copy numbers of the sequences, and length and intensity of the hybridization fragments varied among barley species; so, this set appeared to be useful as molecular markers for barley species. Structural rearrangements of some HRS were observed in hybrids. It was noteworthy that the genomic changes in the hybrids partially coincided with those that take place during species divergence; so, chromosomal rearrangements are likely to proceed according to certain rules. The possibility of cryptic mobile elements participating in the genomic rearrangements under stress factors of the remote hybridization, is discussed, the primary structure of a Bam HI fragment (999 bp long) of Hordeum vulgare DNA being the example.

The occurrence of Ds-like sequences in cereal genomes.

The occurrence of DNA sequences similar to the Ds-element of sh-m5933 maize (Ds-like sequences) was studied in other representatives of the Gramineae. The approximate number of copies of such sequences found under gentle and stringent conditions of washing was determined by dot-hybridization. It was shown that in the maize genome the number of copies of Ds-like sequences exceeds about ten-fold the content of such sequences found in wheat, rye and barley genomes. Quantitative differences in Ds-like sequences between wheat species with various genomes and ploidies (when estimated per genome) as well as between different H. vulgare varieties was not determined. The various melting points (Tm) of DNA-duplexes formed when the Ds-element is hybridized with wheat, rye and barley DNA respectively do not show significant differences and are essentially lower than the Tm of the Ds-element (by 8°-9°C). Thus, these duplexes have 9-11% of nucleotide substitutions in comparison to Ds sh-m5933. The data obtained permit one to suppose the presence of a series of Ds-like sequences heterogenous for the length and degree of homology to the Ds-element isolated from the shrunken locus (sh-m5933) of maize DNA.