Tina Lopes scite author profile

Flow cytometry analyses were used to verify the ploidy stability of Quercus suber L. somatic embryogenesis process. Leaf explants of two adult cork oak trees (QsG0 and QsG5) of the North of Portugal were inoculated on MS medium with 2,4-D and zeatin. After 3 months, calluses with embryogenic structures were isolated and transferred to fresh MS medium without growth regulators and somatic embryo evolution was followed. Morphologically normal somatic embryos (with two cotyledons) and abnormal somatic embryos (with one or three cotyledons) were used in this assay. Flow cytometry combined with propidium iodide staining was employed to estimate DNA ploidy levels and nuclear DNA content of somatic embryos and leaves from mother plants. No significant differences (P< or =0.05) were detected among embryos, and between the embryos and the mother plants. Also, after conversion of these embryos, no significant morphological differences were observed among the somatic embryo-derived plants. These results and further studies using converted plantlet leaves and embryogenic callus tissue indicate that embryo cultures and converted plantlets were stable with regard to ploidy level. As no major somaclonal variation was detected our primary goal of "true-to-type" propagation of cork oak using somatic embryogenesis was assured at this level. The estimation of the 2C nuclear DNA content for this species is similar to the previously obtained value.

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Analysis of the genetic stability of Eucalyptus globulus Labill. somatic embryos by flow cytometry

Pinto

Loureiro

Lopes

et al. 2004

Theor Appl Genet

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Flow cytometry was used to measure the nuclear DNA content of Eucalyptus globulus Labill. somatic and zygotic embryos and leaves in order to determine if somatic embryogenesis induces DNA content and ploidy changes in this species. Mature zygotic embryos derived from open-pollination orchard families were collected from a location in the centre of Portugal. One group was kept for nuclear DNA content and ploidy analysis, and the other group was used for establishing embryogenic cultures. Mature zygotic embryos were grown on Murashige and Skoog (MS) medium supplemented with 3% (w/v) sucrose and 3 mg l(-1) alpha-naphthaleneacetic acid (NAA) for 3 weeks and then transferred to MS medium without growth regulators. Globular somatic embryos from approximately 8-month-old embryogenic cultures were used in the assay. DNA ploidy levels and the nuclear DNA content of mature zygotic embryos, somatic embryos and leaves from the mother field tree were determined using flow cytometry combined with propidium iodide staining. Zygotic embryos had a nuclear DNA content of 1.32 pg/2C, somatic embryos had a nuclear DNA content of 1.39 pg/2C and leaves from the field tree had a nuclear DNA content of 1.40 pg/2C. The values estimated for the somatic embryos and mother plant did not differ statistically from each other (P < or = 0.05), but both differed from those of the zygotic embryos (P < or = 0.05). These results clearly indicate that no changes were induced during the embryogenic process. However, the differences found between the field plants and zygotic embryos did suggest that some aspects must be evaluated carefully, as propidium iodide fluorescence may potentially be influenced by the presence of secondary compounds (e.g. anthocyanins, tannins) in E. globulus somatic embryos and mature leaves. Therefore we believe that the somatic embryogenesis methodology used did not induce major genetic changes in the somatic embryos and that our primary goal of "true-to-type" propagation was assured.

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Determination of genetic stability in long-term somatic embryogenic cultures and derived plantlets of cork oak using microsatellite markers

et al. 2006

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Microsatellites were used to test genetic stability in somatic embryos (SE) of Quercus suber L. The SE were obtained by a simple somatic embryogenesis protocol: leaf explants from two adult plants (QsG0, QsG5) and from two juvenile plants (QsGM1, QsGM2) were inoculated on Murashige and Skoog (MS) medium with 2,4-dichlorophenoxyacetic acid and zeatin. Calluses with primary embryogenic structures were transferred to MSWH (MS medium without growth regulators) and SE proliferated by secondary somatic embryogenesis. High morphological heterogeneity was found among cotyledonary SE. However, converted plants looked morphologically normal with well-developed rooting systems and shoots. The genetic stability of the plant material during the somatic embryogenesis process was evaluated by using six to eight nuclear microsatellites transferred from Q. myrsinifolia Blume, Q. petraea (Matts.) Liebl. and Q. robur L. Five of eight microsatellites distinguished among the genotypes analyzed, and for QsG0, QsGM1 and QsGM2, uniform microsatellite patterns were generally observed within and between SE and the respective donor genotypes. For genotype QsG5, the same pattern was observed in all samples analyzed except one, where the mutation percentage was 2.5%. We conclude that microsatellite markers can be used to assess genetic stability of clonal materials and to determine genetic stability throughout the process of somatic embryogenesis. The simple somatic embryogenesis protocol described has potential for the commercial propagation of Q. suber because it results in a low percentage of mutations.

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Assessment of genetic stability of two micropropagated wild olive species using flow cytometry and microsatellite markers

Brito

Lopes

Loureiro

et al. 2010

Trees

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Micropropagated plants from two wild-olive species, Olea maderensis and O. europaea ssp. europaea var. sylvestris were screened for genetic stability. O. maderensis shoots were elongated/multiplied on OMG medium with zeatin (9.12 lM), and rooted on 1/2 OMG with NAA (3.22 lM). O. europaea var. sylvestris shoots were elongated/multiplied on OM medium with zeatin, and rooting was optimal after a hormonal shock (IBA 100 lM) followed by transfer to the same medium without growth regulators. In both species, acclimatization was successful and plants looked normal and morphologically identical to the donor field trees. Genetic variability was assessed at several stages of the micropropagation process using flow cytometry (FCM) and nuclear microsatellites (SSR). No changes in ploidy level were found among micropropagated plants, though small deviations, putatively due to the negative effects of cytosolic compounds on propidium iodide staining, between these and field plants were observed. In SSRs analyses, ten SSR markers were able to distinguish between genotypes. No mutations were found in these tested SSR loci among the donor tree and micropropagated plants, suggesting, for the tested markers, genetic uniformity throughout the process. The FCM and SSR results obtained do not exclude the occurrence of other changes in the nuclear genome but, considering the morphological stability of micropropagated plants, indicate that both protocols are suitable and efficient for large scale, true-to-type micropropagation of these two wild olive species.

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Genetic characterisation of olive trees from Madeira Archipelago using flow cytometry and microsatellite markers

Brito

Loureiro

Lopes

et al. 2007

Genet Resour Crop Evol

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In this study, native olive plants from Olea maderensis (: O. europaea ssp. cerasiformis) and O. cerasiformis (: O. europaea ssp. guanchica), wild olives (O. europaea ssp. europaea var. sylvestris) and cultivated olives (O. europaea ssp.europaea var. europaea) were analysed with respect to genome size and microsatellite markers. The mean nuclear DNA content of O. maderensis was estimated as 5.97 AE 0.191 pg/2C, while the remaining studied taxa presented mean genome sizes ranging from 2.99 to 3.18 pg/2C. These data and the obtained simple sequence repeats (SSR) profiles, i.e., with 2-4 alleles in O. maderensis and a maximum of two alleles in the other taxa, enabled the identification of a new ploidy level, tetraploidy, for a species belonging to the Olea genus. Cluster analysis of the microsatellite data revealed a clear separation of each species in different clusters and a high genetic dissimilarity could be observed among genotypes belonging to different species. This work contributed to a better characterization of olive species and the obtained data can be helpful to support taxonomic studies, and to develop germplasm preservation strategies in endangered populations of O. maderensis from Madeira Archipelago.

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Tina Lopes

Assessment of ploidy stability of the somatic embryogenesis process in Quercus suber L. using flow cytometry

Analysis of the genetic stability of Eucalyptus globulus Labill. somatic embryos by flow cytometry

Determination of genetic stability in long-term somatic embryogenic cultures and derived plantlets of cork oak using microsatellite markers

Assessment of genetic stability of two micropropagated wild olive species using flow cytometry and microsatellite markers

Genetic characterisation of olive trees from Madeira Archipelago using flow cytometry and microsatellite markers

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