High Levels of Variation Within Gene Sequences of Olea europaea L.

Gene sequence variation in cultivated olive (Olea europaea L. subsp. europaea var. europaea), the most important oil tree crop of the Mediterranean basin, has been poorly evaluated up to now. A deep sequence analysis of fragments of four genes, OeACP1, OeACP2, OeLUS and OeSUT1, in 90 cultivars, revealed a wide range of polymorphisms along all recognized allele forms and unexpected allele frequencies and genotype combinations. High linkage values among most polymorphisms were recorded within each gene fragment. The great sequence variability corresponded to a low number of alleles and, surprisingly, to a small fraction of genotype combinations. The distribution, frequency, and combination of the different alleles at each locus is possibly due to natural and human pressures, such as selection, ancestrality, or fitness. Phylogenetic analyses of allele sequences showed distant and complex patterns of relationships among cultivated olives, intermixed with other related forms, highlighting an evolutionary connection between olive cultivars and the O. europaea subspecies cuspidata and cerasiformis. This study demonstrates how a detailed and complete sequence analysis of a few gene portions and a thorough genotyping on a representative set of cultivars can clarify important issues related to sequence polymorphisms, reconstructing the phylogeny of alleles, as well as the genotype combinations. The identification of regions representing blocks of recombination could reveal polymorphisms that represent putatively functional markers. Indeed, specific mutations found on the analyzed OeACP1 and OeACP2 fragments seem to be correlated to the fruit weight.

Analysis of transposons and repeat composition of the sunflower (Helianthus annuus L.) genome.

A sample-sequencing strategy combined with slot-blot hybridization and FISH was used to study the composition of the repetitive component of the sunflower genome. One thousand six hundred thirty-eight sequences for a total of 954,517 bp were analyzed. The fraction of sequences that can be classified as repetitive using computational and hybridization approaches amounts to 62% in total. Almost two thirds remain as yet uncharacterized in nature. Of those characterized, most belong to the gypsy superfamily of LTR-retrotransposons. Unlike in other species, where single families can account for large fractions of the genome, it appears that no transposon family has been amplified to very high levels in sunflower. All other known classes of transposable elements were also found. One family of unknown nature (contig 61) was the most repeated in the sunflower genome. The evolution of the repetitive component in the Helianthus genus and in other Asteraceae was studied by comparative analysis of the hybridization of total genomic DNAs from these species to the sunflower small-insert library and compared to gene-based phylogeny. Very little similarity is observed between Helianthus species and two related Asteraceae species outside of the genus. Most repetitive elements are similar in annual and perennial Helianthus species indicating that sequence amplification largely predates such divergence. Gypsy-like elements are more represented in the annuals than in the perennials, while copia-like elements are similarly represented, attesting a different amplification history of the two superfamilies of LTR-retrotransposons in the Helianthus genus.

Characterization of two families of tandem repeated DNA sequences in Potamogeton pectinatus L.

DNA sequences belonging to two families of tandem repeats, PpeRsa1 (362-364 bp in length, 62% A+T residues) and PpeRsa2 (355-359 bp in length, 59% A+T residues), have been isolated from the Potamogeton pectinatus L. genome. The two sequence families do not share significant nucleotide sequence similarity, even if an evolutionary relationship between them could be assumed. The comparison of the cleaving activity of isoschizomeres that are either sensitive or insensitive to methylation of cytosine residues in the target sequence revealed high methylation in both sequence families. The copy number per 1C DNA of PpeRsa1- and PpeRsa2-related sequences is estimated to be 4.92 x 10(4) and 7.96 x 10(4), respectively. Taken together, these sequences account for about 7.5% of the entire genome of P. pectinatus. The chromosomal organization of these sequences was investigated by fluorescent in situ hybridization. PpeRsa1 and PpeRsa2 repeats found related sequences in 52 chromosomes of the P. pectinatus complement (2n = 78). The related sequences were localized around the centromeres and at the chromosome ends in three pairs of chromosomes, while they were found only at the chromosome ends in the remaining pairs. Twenty-six chromosomes did not show any hybridization signal. The hypothesis that the species is a hybrid between a diploid parent and an allotetraploid parent is put forward.