Amount and organization of the heterochromatin in Olea europaea and related species

Bitonti, Maria Beatrice; Cozza, Radiana; Chiappetta, Adriana; Contento, A.; Minelli, S.; Ceccarelli, Marilena; Gelati, M. T.; Maggini, F.; Baldoni, Luciana; Cionini, P. G.

doi:10.1046/j.1365-2540.1999.00564.x

Cited by 28 publications

(13 citation statements)

References 27 publications

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“…5). The first three families (Oe80, Oe178, and Oe86) correspond to the OeTaq80, OeTaq178, and OeGEM86 families described by Bitonti et al (1999) and Minelli et al (2000) and account for ∼72% of tandem repeats. The fourth family (Oe179) was for the first time identified in this survey: it represents 12.6% of the tandem repeats and the most common repeat unit is 179-bp long; within this family, a number of repeats resulted truncated, with a variable length.…”

Section: Resultsmentioning

confidence: 99%

“…Olive ( Olea europaea L.) has a medium-sized haploid genome of 1.4–1.5 Gb (Loureiro et al 2007). Concerning repeated sequences, the best characterized are four tandem repeats isolated from genomic libraries and, in some instances, localized by cytological hybridization on olive chromosomes (Katsiotis et al 1998; Bitonti et al 1999; Minelli et al 2000; Lorite et al 2001; Contento et al 2002). Also putative retrotransposon fragments have been isolated and sequenced (Stergiou et al 2002; Natali et al 2007), but a comprehensive picture of repeat elements landscape in the olive genome is still lacking.…”

Section: Introductionmentioning

confidence: 99%

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The Peculiar Landscape of Repetitive Sequences in the Olive (Olea europaea L.) Genome

Barghini

Natali

Cossu

et al. 2014

Genome Biology and Evolution

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Analyzing genome structure in different species allows to gain an insight into the evolution of plant genome size. Olive (Olea europaea L.) has a medium-sized haploid genome of 1.4 Gb, whose structure is largely uncharacterized, despite the growing importance of this tree as oil crop. Next-generation sequencing technologies and different computational procedures have been used to study the composition of the olive genome and its repetitive fraction. A total of 2.03 and 2.3 genome equivalents of Illumina and 454 reads from genomic DNA, respectively, were assembled following different procedures, which produced more than 200,000 differently redundant contigs, with mean length higher than 1,000 nt. Mapping Illumina reads onto the assembled sequences was used to estimate their redundancy. The genome data set was subdivided into highly and medium redundant and nonredundant contigs. By combining identification and mapping of repeated sequences, it was established that tandem repeats represent a very large portion of the olive genome (∼31% of the whole genome), consisting of six main families of different length, two of which were first discovered in these experiments. The other large redundant class in the olive genome is represented by transposable elements (especially long terminal repeat-retrotransposons). On the whole, the results of our analyses show the peculiar landscape of the olive genome, related to the massive amplification of tandem repeats, more than that reported for any other sequenced plant genome.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The Peculiar Landscape of Repetitive Sequences in the Olive (Olea europaea L.) Genome

Barghini

Natali

Cossu

et al. 2014

Genome Biology and Evolution

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“…As a result, a great number of varieties are present in all the countries where this species is cultivated, raising several problems for germplasm management and preservation. Evaluation and characterization of olive genetic resources is therefore crucial.In general very little work is available about olive cytogenetics (Bitonti et al 1999, Minelli et al 2000 and as a result of shortage of knowledge on the olive genome, there is controversy about olive phylogeny and its relationship to its related wild forms (Zohary 1994, Bitonti et al 1999.Olive cultivars are grown in different parts of Iran and cultivation of the same cultivars for long period of time may lead to the genetic erosion confining the subsequent breeding programs. Therefore it is necessary to study the available diversity and introduce new variability as well.…”

mentioning

confidence: 99%

“…In general very little work is available about olive cytogenetics (Bitonti et al 1999, Minelli et al 2000 and as a result of shortage of knowledge on the olive genome, there is controversy about olive phylogeny and its relationship to its related wild forms (Zohary 1994, Bitonti et al 1999.…”

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confidence: 99%

Chromosome Pairing and Chiasma Formation in Some Olive (Olea europaea L.) Cultivars of Iran

et al. 2008

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Summary Cytogenetic characteristics of 11 olive cultivars were studied considering their chromosome pairing and segregation. The cultivars studied possessed 2nϭ4xϭ46 chromosome number and formed only bivalents in metaphase of meiosis-I. The cultivars differed significantly in their chiasma frequency and distribution as well as chromosome pairing indicating partly their genetic distinctness. Meiotic abnormalities including laggard chromosomes and chromosome stickiness occurred in the cultivars studied. B-chromosomes, cytomixis and unreduced pollen grains were observed in some of the cultivars. Clustering and ordination of the olive cultivars based on cytogenetic characteristics showed distinctness of these cultivars. B-chromosomes and unreduced pollen grain formation are new in olive cytogenetics.Key words B-chromosome, Cytogenetics, Cytomixis, Olive.The olive-tree (Olea europaea L.) is one of the most characteristic species of the Mediterranean area and nowadays is the only cultivated representative of the genus Olea. Since its chromosome complement is 46, it is considered-although not demonstrated-a tetraploid species by Brousse (1987), while according to Green and Wickens (1989) olive is a diploid species, comprising the cultivated type (var. sativa) and the wild type sylvestris (syn. Olea oleaster Hoffm. et Link). Cultivated olives are propagated vegetatively while wild olives only reproduced by sexual mean. These two olive types are interfertile (Zohary and Spiegel-Roy 1975).Olea europaea is the only cultivated representative of the genus Olea, having about 2600 different cultivars cultivated in different regions of the world. Since the beginning of its domestication, olive has been propagated vegetatively to exploit the best combination of genes which arose by random crosses or mutations (Carriero et al. 2002). As a result, a great number of varieties are present in all the countries where this species is cultivated, raising several problems for germplasm management and preservation. Evaluation and characterization of olive genetic resources is therefore crucial.In general very little work is available about olive cytogenetics (Bitonti et al. 1999, Minelli et al. 2000 and as a result of shortage of knowledge on the olive genome, there is controversy about olive phylogeny and its relationship to its related wild forms (Zohary 1994, Bitonti et al. 1999.Olive cultivars are grown in different parts of Iran and cultivation of the same cultivars for long period of time may lead to the genetic erosion confining the subsequent breeding programs. Therefore it is necessary to study the available diversity and introduce new variability as well. For this reason, the present study considers cytogenetic study of 11 olive cultivars available in Iran, considering the chromosome pairing and segregation, the occurrence of B-chromosomes and cytogenetic abnormalities for the first time.

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“…Varieties are predominantly diploid (2n = 2x = 46) (Minelli et al, 2000). The DNA content is 2.2 pg per 1C nucleus (Bitonti et al, 1999), correspondent to a genome size of 2.2 Gbp (De la Rosa et al, 2003).…”

Section: Olive Germplasm Characterizationmentioning

confidence: 99%

Fruit Germplasm Characterization: Genomics Approaches for the Valorisation of Genetic Diversity

Muzzalupo¹,

Perri²,

Chiappetta³

2012

Genetic Diversity in Plants

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Amount and organization of the heterochromatin in Olea europaea and related species

Cited by 28 publications

References 27 publications

The Peculiar Landscape of Repetitive Sequences in the Olive (Olea europaea L.) Genome

The Peculiar Landscape of Repetitive Sequences in the Olive (Olea europaea L.) Genome

Chromosome Pairing and Chiasma Formation in Some Olive (Olea europaea L.) Cultivars of Iran

Fruit Germplasm Characterization: Genomics Approaches for the Valorisation of Genetic Diversity

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