Marilena Ceccarelli

Diversity of Olea genotypes and the origin of cultivated olives

Abstract.Tandem repeats belonging to three DNA sequence families (OeTaq80, OeTaq178, and OeGEM86) were isolated from the nuclear DNA of Olea europaea cv. Carolea and dot-hybridized to the genomic DNA of 14 hypothetically different Olea species, 78 olive cultivars, and 14 wild olives. The copy number per unreplicated haploid genome of OeTaq80- and OeTaq178-related sequences was in the 107–106 range and that of OeGEM86-related sequences was in the 105 range in cultivars, wild olives and some Olea species. A large variation in the frequency of repeats belonging to each sequence family was observed within each group of plants. Positive correlations existed in each genome between the frequencies of repeats belonging to each family, and their overall frequency was positively correlated to the genome size. Duncan grouping showed that the frequency variation of tandem repeats within each group of plants was not continuous. Two main groups and several subgroups of genotypes could be separated within both the olive cultivars and the wild olives. Discrete areas in the Mediterranean Basin could be delimited by the geographic distribution of cultivated olives with different genotypes and the wild plants were associated with the cultivars in these areas according to genotypic similarity. The Olea species could be divided into four genotypic groups. Three of these, comprising accessions from Asia and North Africa, showed similarity with the genotypes of cultivars and wild olives. These results suggest a polyphyletic origin of cultivated olives from different wild Olea forms distributed throughout the Mediterranean Basin.

Genome size variations within Dasypyrum villosum: correlations with chromosomal traits, environmental factors and plant phenotypic characteristics and behaviour in reproduction

Abstract Feulgen/DNA cytophotometric determinations carried out in the root meristem of seedlings showed that substantial quantitative alterations in the nuclear genome are present between and within 15 natural populations of Dasypyrum villosum in Italy. When the most variant values are considered, there is a 17.6% difference between the mean genome size of the populations, and a 66.2% difference between the genome size of individual plants within a population. A highly significant, positive correlation was found to exist between the genome size of D. villosum plants and the altitude of their stations, and differences in DNA contents between individual plants were greater in populations from mountain sites. Karyological analyses showed all chromosome pairs to differ largely in size between plants with differing DNA contents. A highly significant, positive correlation was found to exist between genome size and both the length of the chromosome complement at metaphase and the length and arm ratio of pair VII. Significant correlations were also found between DNA content and certain phenotypic characteristics of the plants. The mean genome size of the populations was negatively correlated with the mean leaf length and width. In contrast, the genome size of individual plants was positively correlated with the weight of the seed from which they originated and their flowering interval. A large range of genome sizes was found in the half-sib progeny of a plant having a relatively large genome. In contrast, in the half-sib progeny of a plant having a small genome, the genome sizes of the individual plants were less divergent and similar to that of the mother plant. All siblings from crosses between plants with differing genome sizes had similar DNA contents, which were intermediate between those of the parental plants, even if closer to the DNA content of the parent plant having the smaller genome size. Size polymorphism within pairs was never observed in plants obtained from these crosses or in half-sibs whose genome size differed from that of the mother plant. The intraspecific alterations observed in the nuclear genome and their effects on plant development and phenotype are briefly discussed as evolutionary factors which allow D. villosum populations to withstand different environmental conditions as well as the variability of conditions in a given environment.

Cytogenetics of Triticum × Dasypyrum hybrids and derived lines

Genomic in situ hybridization was used to study Triticum × Dasypyrum wide hybrids and derived lines. A cytogenetic investigation was carried out in progenies of (i) amphiploids derived from T. turgidum var. durum (T. durum; 2n = 14; genomes AABB) × D. villosum (2n = 14; genome VV), (ii) three-parental hybrids (T. durum × D. villosum) × T. aestivum (2n = 42, genomes A′A′B′B′D′D′), and (iii) T. aestivum aneuploid lines carrying D. villosum chromosomes or chromatin. The amphiploids derived from T. durum × D. villosum showed a stable chromosomal constitution, made up of 14 V chromosomes, 14 chromosomes carrying the wheat A genome and 14 chromosomes carrying the B genome. High karyological instability was observed in the progenies of three-parental hybrids ([T. durum × D. villosum] × T. aestivum). Plants having the expected 14 A chromosomes, 14 B chromosomes, 7 D chromosomes, and 7 V chromosomes were rather rare (4.5%). Many progeny plants (45.5%) had the hexaploid wheat genome with 42 chromosomes and lacked any detectable D. villosum chromatin. Other plants (50%) had 14 A chromosomes and 14 B chromosomes, plus variable numbers of D and V chromosomes, the former being better retained than the latter in most cases. Some T. aestivum lines carrying D. villosum chromosomes or chromatin, as the result of addition, substitution, or recombination events or even a combination of these karyological events, were found to be stable. Other lines were unstable, and these lines carried 1V, 3V, or 5V chromosomes or their portions. Substitution or recombination events where 1V chromosomes were involved could concern the homeologous counterparts in both the A and B and D genomes of wheat. No line could be recovered where the shorter arm of 3V chromosomes was present. Changes in the morphology and banding pattern of V chromosomes were observed in hybrids that did not carry the entire D. villosum complement. By comparing the results of our cytogenetic analyses with certain phenotypic characteristics of the lines studied, genes for discrete traits could be assigned to specific V chromosomes or V chromosome arms. From the frequency of V chromosomes that were involved in chromatin exchanges with or substituted for one of their homeologous counterparts in the A, B, and D wheat genomes, it was inferred that D. villosum belongs to the same phyletic lineage as T. urartu (donor of the A genome of wheat) and Aegilops speltoides (B genome), and that Ae. squarrosa (D genome) diverged earlier from D. villosum.

Genome plasticity during seed germination in Festuca arundinacea

Abstract Feulgen/DNA cytophotometric determinations were carried out on early prophases in the meristems of seedlings obtained by germinating seeds of different accessions of Festuca arundinacea at 10°C, 20°C, or 30°C. Feulgen/DNA contents increased significantly with the increase in the temperature of seed germination. In each accession, the greater the increase in absorption in seedlings obtained at 30°C, the lower the absorption in seedlings obtained at 10°C. In contrast, Feulgen/DNA contents did not undergo changes when the temperature was altered at developmental stages other than seed germination. The results of molecular hybridizations (slot blots) indicated that the redundancy of repeated DNA sequences belonging to two families having Cot ranges of 0–2×10-1 and 2×10-1 −2×100, respectively, was significantly higher in the genome of seedlings obtained at 30°C than in that of seedlings obtained at 10°C. When centrifuged to equilibrium in CsCl density gradients, the DNA extracted from seedlings obtained at 30°C formed a heavier and a lighter shoulder with buoyant densities of 1.707 g/ml and 1.692 g/ml, respectively, in addition to the main band (1.701 g/ml). Only a less apparent shoulder banding at 1.706 g/ml was formed by the DNA extracted from seedlings obtained at 10°C. After seed germination in the presence of [3H]-thymidine for 24 h at 30°C, most of radioactivity was found in the guanine + cytosine- or adenine+thymine-enriched DNA fractions, which formed the two shoulders in the density profile. In contrast, only guanine+cytosine-enriched fractions, which formed the heavier shoulder, were preferentially labelled in the DNA from seedlings obtained at 10°C. These results prove that fluid domains do exist in the nuclear DNA of F. arundinacea. These DNA domains are capable of rapid, quantitative alterations, which represent the direct responses of the genome to developmental and environmental stimuli. Seed germination appears to be a limited, specific period in development within which the adaptive response to temperature variations can be put into effect.

Obtainment of inter-subspecific hybrids in olive (Olea europaea L.)

To enrich the source of germplasm of cultivated olive (Olea europaea subsp. europaea L.), inter-subspecific hybrid plants have been produced by experimental crosses between several varieties of cultivated olive and Asian and African accessions of the wild related subspecies cuspidata. Germination of putative hybrid seeds was enhanced by using in vitro embryo culture. The genetic make-up of germinated seedlings was assayed with the aid of both AFLP and SSR molecular markers and their hybrid nature was proved by the presence of male-specific alleles in their molecular patterns. Most of the parent specific alleles showed segregation among F1 progenies indicating high heterozygosity content of the parental lines. The majority of the hybrids derived from crosses in which an African accession of cuspidata was used as female parent. The overall morphological aspect of hybrids resembled that of the female parent. The production of inter-subspecific hybrid plants in Olea is discussed in relation to the genetic improvement of cultivated olive.

Characterization of the chromosome complement of Helianthus annuus by in situ hybridization of a tandemly repeated DNA sequence

A tandemly repeated sequence isolated from a clone (HAG004N15) of a nebulized genomic DNA library of sunflower (Helianthus annuus L., 2n = 34) was characterized and used to study the chromosome complement of sunflower. HAG004N15 repeat units (368 bp in length) were found to be highly methylated, and their copy number per haploid (1C) genome was estimated to be 7800. After in situ hybridization of HAG004N15 repeats onto chromosome spreads, signals were observed at the end of both chromosome arms in 4 pairs and at the end of only one arm in 8 other pairs. Signals were also observed at the intercalary (mostly subtelomeric) regions in all pairs, in both arms in 8 pairs, and in only one arm in the other 9 pairs. The short arm of 1 pair was labelled entirely. The chromosomal location of ribosomal DNA was also studied by hybridizing the wheat ribosomal probe pTa71. Four chromosome pairs contained ribosomal cistrons at the end of their shorter arm, but a satellite was seen in only 3 pairs. These hybridization patterns were the same in the 3 sunflower lines studied (HA89, RA20031, and HOR). The chromosomal localization of HAG004N15-related sequences allowed all of the chromosome pairs to be distinguished from each other, in spite of small size and similar morphology.

Cryptic Introgression of Dasypyrum villosum Parental DNA in Wheat Lines Derived from Intergeneric Hybridization

Cytogenetic and DNA molecular analyses have been carried out in 3 wheat introgression lines (ILs; CS×V58, CS×V59, and CS×V60) derived from Triticum aestivum cv. ‘Chinese Spring’ (CS) × Dasypyrum villosum(Dv) intergeneric hybridization. All lines, which showed several phenotypic differences compared to CS, had the same chromosome number (2n = 42) and structure as CS, and neither chromosomes nor chromatin from Dv were apparently added to their complement. However, Feulgen/DNA cytophotometry showed that there was more nuclear DNA in the lines than in the parental wheat (by 1.85%, 2.76%, and 1.26% in CS×V58, CS×V59, and CS×V60, respectively). Molecular investigation indicated the presence of Dv DNA in the ILs. AFLP analysis of genomic DNA from the ILs, CS, and Dv detected a total of 120 polymorphic bands, of which 7 (5.8%) were present in some or all the ILs and Dv but were absent in CS. PCR amplification, sequence analysis of amplicons, and Southern blot hybridization confirmed the presence of Dv-specific sequences in each of the ILs. These results indicate cryptic introgression of Dv DNA sequences into the genome of the ILs. Some implications of this finding are discussed.

Characterization, evolution and chromosomal distribution of two satellite DNA sequence families in Lathyrus species.

DNA clones containing highly repetitive DNA sequences were selected from partial libraries of Lathyrus sativus and L. sylvestris. Two satellite DNA sequence families were isolated from the genome of the former species. A first family was made up of repeats that varied in length from 54–56 bp, and shared 51.7–94.8% nucleotide sequence similarity. The repeats of the second sequence family were 52–62 bp in length, and shared a 58.5–78.5% nucleotide sequence similarity. All the repeat units contained in a clone from L. sylvestris were 41 bp in length and showed an almost perfect structural conservation (95.1–100% nucleotide sequence similarity). The evolution of the first sequence family from L. sativus and of that isolated from L. sylvestris was studied by dot-blot hybridization to the genomic DNA of these species and 3 other Lathyrus species, L. clymenum, L. latifolius and L. odoratus. The former repeats were found to be species-specific and their redundancy was calculated to be 2.9 × 107. The satellite DNA sequence isolated from L. sylvestris was present also in L.latifolius, with a redundancy of 1.4 × 107 and 1.1 × 107, respectively. Fluorescent in situ hybridization (FISH) was used to investigate the chromosomal distribution of the two sequence families and of 45S and 5S ribosomal genes. The species-specific sequences of L. sativus were located around the centromere of chromosome pair IV, where they occupied a very broad region, and, in a much smaller amount, close to the centromere in the short arm of pair II. Sequences related to the repeat units isolated from L. sylvestris were found, both in this species and L. latifolius, in all of the chromosome pairs at terminal and interstitial regions, where they co-localize with the vast majority of DAPI bands. The pattern of distribution of the satellite DNA sequences investigated, together with that of DAPI bands and ribosomal DNA, allowed each chromosome pair of the 3 complements studied to be identified unambiguously.

Phylogenetic relationships between annual and perennial species of Helianthus: evolution of a tandem repeated DNA sequence and cytological hybridization experiments.

The amplification and chromosomal localization of tandem repeated DNA sequences from Helianthus annuus (clone HAG004N15) and the physical organization of ribosomal DNA were studied in annual and perennial species of Helianthus. HAG004N15-related sequences, which did not show amplification in other Asteraceae except for Viguiera multiflora, were redundant in all the Helianthus species tested, but their frequency was significantly higher in perennials than in annuals. These sequences were located at the ends and intercalary regions of all chromosome pairs of annual species. A similar pattern was found in the perennials, but a metacentric pair in their complement was not labelled. Ribosomal cistrons were carried on two chromosome pairs in perennials and on three pairs in annuals except for H. annuus, where rDNA loci were on four pairs. No difference was observed between cultivated H. annuus and its wild accessions in the hybridization pattern of the HAG004N15 and ribosomal probes. These findings support the hypothesis that the separation between annual and perennial Helianthus species occurred through interspecific hybridization involving at least one different parent. However, GISH in H. annuus using genomic DNA from the perennial Helianthus giganteus as blocking DNA failed to reveal different genomic assets in annual and perennial species.

Genome-wide analysis of LTR-retrotransposon diversity and its impact on the evolution of the genus Helianthus (L.)

BackgroundGenome divergence by mobile elements activity and recombination is a continuous process that plays a key role in the evolution of species. Nevertheless, knowledge on retrotransposon-related variability among species belonging to the same genus is still limited. Considering the importance of the genus Helianthus, a model system for studying the ecological genetics of speciation and adaptation, we performed a comparative analysis of the repetitive genome fraction across ten species and one subspecies of sunflower, focusing on long terminal repeat retrotransposons at superfamily, lineage and sublineage levels.ResultsAfter determining the relative genome size of each species, genomic DNA was isolated and subjected to Illumina sequencing. Then, different assembling and clustering approaches allowed exploring the repetitive component of all genomes. On average, repetitive DNA in Helianthus species represented more than 75% of the genome, being composed mostly by long terminal repeat retrotransposons. Also, the prevalence of Gypsy over Copia superfamily was observed and, among lineages, Chromovirus was by far the most represented. Although nearly all the same sublineages are present in all species, we found considerable variability in the abundance of diverse retrotransposon lineages and sublineages, especially between annual and perennial species.ConclusionsThis large variability should indicate that different events of amplification or loss related to these elements occurred following species separation and should have been involved in species differentiation. Our data allowed us inferring on the extent of interspecific repetitive DNA variation related to LTR-RE abundance, investigating the relationship between changes of LTR-RE abundance and the evolution of the genus, and determining the degree of coevolution of different LTR-RE lineages or sublineages between and within species. Moreover, the data suggested that LTR-RE abundance in a species was affected by the annual or perennial habit of that species.