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dc.contributor.authorWeber, Ricardo Luís Mayerpt_BR
dc.contributor.authorStrohm, Beatriz Wiebkept_BR
dc.contributor.authorBredemeier, Christianpt_BR
dc.contributor.authorMargis-Pinheiro, Márciapt_BR
dc.contributor.authorBrito, Giovani Greigh dept_BR
dc.contributor.authorRechenmacher, Cilianapt_BR
dc.contributor.authorBertagnolli, Paulo Fernandopt_BR
dc.contributor.authorSá, Maria Eugênia Lisei dept_BR
dc.contributor.authorCampos, Magnólia de Araújopt_BR
dc.contributor.authorAmorim, Regina Maria Santos dept_BR
dc.contributor.authorBeneventi, Magda Aparecidapt_BR
dc.contributor.authorMargis, Rogeriopt_BR
dc.contributor.authorGrossi-de-Sá, Maria Fátimapt_BR
dc.contributor.authorBodanese-Zanettini, Maria Helenapt_BR
dc.date.accessioned2015-04-09T01:58:02Zpt_BR
dc.date.issued2014pt_BR
dc.identifier.issn1471-2229pt_BR
dc.identifier.urihttp://hdl.handle.net/10183/115079pt_BR
dc.description.abstractBackground: Drought is by far the most important environmental factor contributing to yield losses in crops, including soybeans [Glycine max (L.) Merr.]. To address this problem, a gene that encodes an osmotin-like protein isolated from Solanum nigrum var. americanum (SnOLP) driven by the UBQ3 promoter from Arabidopsis thaliana was transferred into the soybean genome by particle bombardment. Results: Two independently transformed soybean lines expressing SnOLP were produced. Segregation analyses indicated single-locus insertions for both lines. qPCR analysis suggested a single insertion of SnOLP in the genomes of both transgenic lines, but one copy of the hpt gene was inserted in the first line and two in the second line. Transgenic plants exhibited no remarkable phenotypic alterations in the seven analyzed generations. When subjected to water deficit, transgenic plants performed better than the control ones. Leaf physiological measurements revealed that transgenic soybean plants maintained higher leaf water potential at predawn, higher net CO2 assimilation rate, higher stomatal conductance and higher transpiration rate than non-transgenic plants. Grain production and 100-grain weight were affected by water supply. Decrease in grain productivity and 100-grain weight were observed for both transgenic and non-transgenic plants under water deficit; however, it was more pronounced for non-transgenic plants. Moreover, transgenic lines showed significantly higher 100-grain weight than non-transgenic plants under water shortage. Conclusions: This is the first report showing that expression of SnOLP in transgenic soybeans improved physiological responses and yield components of plants when subjected to water deficit, highlighting the potential of this gene for biotechnological applications.en
dc.format.mimetypeapplication/pdf
dc.language.isoengpt_BR
dc.relation.ispartofBMC Plant biology. London. Vol. 14, no. 343, (2014), p. 1-9pt_BR
dc.rightsOpen Accessen
dc.subjectAbiotic stressen
dc.subjectSolanum nigrumpt_BR
dc.subjectEstresse abióticopt_BR
dc.subjectBombardmenten
dc.subjectGlycine maxpt_BR
dc.subjectDrought toleranceen
dc.subjectGenetic transformationen
dc.subjectGlycine maxen
dc.subjectOsmotinen
dc.subjectWater deficiten
dc.titleExpression of an osmotin-like protein from Solanum nigrum confers drought tolerance in transgenic soybeanpt_BR
dc.typeArtigo de periódicopt_BR
dc.identifier.nrb000955678pt_BR
dc.type.originEstrangeiropt_BR


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