Simple Sequence Repeats (SSRs) are known to be scattered and present in high number in eukaryotic genomes. We demonstrate that dye-labeled oligodeoxyribonucleotides with repeated mono-, di-, tri, or tetranucleotide motifs (15-20 nucleotides in length) have an unexpected ability to recognize SSR target sequences in non-denatured chromosomes. The results show that all these probes are able to invade chromosomes, independent of the size of the repeat motif, their nucleotide sequence, or their ability to form alternative B-DNA structures such as triplex DNA. This novel and remarkable property of binding SSR oligonucleotides to duplex DNA targets permitted the development of a non-denaturing fluorescence in situ hybridization method that quickly and efficiently detects SSR-enriched chromosome regions in mitotic, meiotic, and polytene chromosome spreads of different model organisms. These results have implications for genome analysis and for investigating the roles of SSRs in chromosome structure and function.
This study provides evidence that nuclear and chromosome remodelling has taken place in sugarcane, a vegetative crop with a complex genome derived from interspecific hybridizations between Saccharum officinarum and S. spontaneum. Detailed knowledge on the chromosomal compositions of the three clones analysed was acquired. (1) All hybrid cultivars were found to be aneuploid, affecting both parental genomes (having chromosomes in addition to full genomes), with chromosome numbers from 2n=102-106 in My5514 and up to 2n=113-117 in C236-51. (2) Comparative in situ hybridization showed that about 16% of these chromosomes are inherited from S. spontaneum and less than 5% are recombinant or translocated chromosomes containing sequences of both S. officinarum and S. spontaneum. (3) Differences between the observed DNA contents (estimated by flow cytometry) and those expected from the number of chromosomes, allowed the introgression of additional S. spontaneum or S. officinarum DNA pieces into the B42231 and C236-51 cultivars to be estimated. (4) Size heterogeneity between S. officinarum homologous chromosomes carrying the 18S-5.8S-25S and 5S ribosomal genes (identified by FISH with pTa71 and pTa794, respectively) confirms remodelling occurred by chromosomal interchange events, at least in these homologous chromosomes. (5) Simultaneous visualization of nucleoli and NORs showed that all 18S-5.8S-25S loci were potentially functional in the three clones, independent of their origin and size.
The presence and distribution of two simple sequence repeats (SSRs), three highly repetitive sequences from rye, and the 5S rDNA have been investigated in 3 rye cultivars and 10 wild-related species of the genus SECALE: The following conclusions can be drawn in addition to detailed knowledge of the sequence content of chromatin in each accession studied: (1) Every species is unique in either or both the complement and chromosomal distribution of the six repeated sequences analyzed. (2) These sequences reveal multiple landmarks along all the rye chromosomes arms. (3) High polymorphism as well as heterozygosity between homologues in the distribution of the (AAG)(5) and (AAC)(5) was revealed in the outbreeding species of the Secale strictum complex. (4) It is possible to deduce trends in the complexity of repetitive DNA during the evolution of the genus. A possible evolutionary pathway that accounts for the present-day Secale species is presented.
The physical distribution of ten simple-sequence repeated DNA motifs (SSRs) was studied on chromosomes of bread wheat, rye and hexaploid triticale. Oligomers with repeated di-, tri- or tetra-nucleotide motifs were used as probes for fluorescence in situ hybridization to root-tip metaphase and anther pachytene chromosomes. All motifs showed dispersed hybridization signals of varying strengths on all chromosomes. In addition, the motifs (AG)12, (CAT)5, (AAG)5, (GCC)5 and, in particular, (GACA)4 hybridized strongly to pericentromeric and multiple intercalary sites on the B genome chromosomes and on chromosome 4A of wheat, giving diagnostic patterns that resembled N-banding. In rye, all chromosomes showed strong hybridization of (GACA)4 at many intercalary sites that did not correspond to any other known banding pattern, but allowed identification of all R genome chromosome arms. Overall, SSR hybridization signals were found in related chromosome positions independently of the motif used and showed remarkably similar distribution patterns in wheat and rye, indicating the special role of SSRs in chromosome organization as a possible ancient genomic component of the tribe Triticeae (Gramineae).
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