Thuanne Pires Ribeiro1,2, Isabela Tristan Lourenço-Tessutti1,3, Bruno Paes de Melo1,3,4, Carolina Vianna Morgante1,3,5, Alvaro Salles Filho1,6,7, Camila Barrozo Jesus Lins1, Gilanna Falcão Ferreira1, Glênia Nunes Mello1, Leonardo Lima Pepino Macedo1,3, Wagner Alexandre Lucena1,3, Maria Cristina Mattar Silva1,3, Osmundo Brilhante Oliveira-Neto1,3,8, Maria Fatima Grossi-de-Sa9,10,11. 1. Embrapa Genetic Resources and Biotechnology, PqEB, Final W5 North, PO Box 02372, Brasília, DF, 70770-901, Brazil. 2. Cellular Biology Department, Brasilia University, Brasília, DF, Brazil. 3. National Institute of Science and Technology, INCT PlantStress Biotech, EMBRAPA, Brasília, DF, Brazil. 4. Federal University of Viçosa, UFV, Viçosa, MG, Brazil. 5. Embrapa Semiarid, Petrolina, PE, Brazil. 6. Catholic University of Brasília, Brasília, DF, Brazil. 7. Federal University of Paraná, Curitiba, PR, Brazil. 8. Biochemistry and Molecular Biology Department, Integrated Faculties of the Educational Union of Planalto Central, Brasília, DF, Brazil. 9. Embrapa Genetic Resources and Biotechnology, PqEB, Final W5 North, PO Box 02372, Brasília, DF, 70770-901, Brazil. fatima.grossi@embrapa.br. 10. National Institute of Science and Technology, INCT PlantStress Biotech, EMBRAPA, Brasília, DF, Brazil. fatima.grossi@embrapa.br. 11. Catholic University of Brasília, Brasília, DF, Brazil. fatima.grossi@embrapa.br.
Abstract
MAIN CONCLUSION: The combined Agrobacterium- and biolistic-mediated methods of cotton transformation provide a straightforward and highly efficient protocol for obtaining transgenic cotton. Cotton (Gossypium spp.) is the most important crop for natural textile fiber production worldwide. Nonetheless, one of the main challenges in cotton production are the losses resulting from insect pests, pathogens, and abiotic stresses. One effective way to solve these issues is to use genetically modified (GM) varieties. Herein, we describe an improved protocol for straightforward and cost-effective genetic transformation of cotton embryo axes, merging biolistics and Agrobacterium. The experimental steps include (1) Agrobacterium preparation, (2) seed sterilization, (3) cotton embryo excision, (4) lesion of shoot-cells by tungsten bombardment, (5) Agrobacterium-mediated transformation, (6) embryo co-culture, (7) regeneration and selection of transgenic plants in vitro, and (8) molecular characterization of plants. Due to the high regenerative power of the embryonic axis and the exceptional ability of the meristem cells for plant regeneration through organogenesis in vitro, this protocol can be performed in approximately 4-10 weeks, with an average plant regeneration of about 5.5% (± 0.53) and final average transformation efficiency of 60% (± 0.55). The transgene was stably inherited, and most transgenic plants hold a single copy of the transgene, as desirable and expected in Agrobacterium-mediated transformation. Additionally, the transgene was stably expressed over generations, and transgenic proteins could be detected at high levels in the T2 generation of GM cotton plants. The T2 progeny showed no phenotypic or productivity disparity compared to wild-type plants. Collectively, the use of cotton embryo axes and the enhanced DNA-delivery system by combining particle bombardment and Agrobacterium infection enabled efficient transgenic plant recovery, overcoming usual limitations associated with the recalcitrance of several cotton genotypes subjected to somatic embryogenesis. The improved approach states this method's success for cotton genetic modification, allowing us to obtain GM cotton plants carrying traits, which are of fundamental relevance for the advancement of global agribusiness.
MAIN CONCLUSION: The combined Agrobacterium- and biolistic-mediated methods of cotton transformation provide a straightforward and highly efficient protocol for obtaining transgenic cotton. Cotton (Gossypium spp.) is the most important crop for natural textile fiber production worldwide. Nonetheless, one of the main challenges in cotton production are the losses resulting from insect pests, pathogens, and abiotic stresses. One effective way to solve these issues is to use genetically modified (GM) varieties. Herein, we describe an improved protocol for straightforward and cost-effective genetic transformation of cotton embryo axes, merging biolistics and Agrobacterium. The experimental steps include (1) Agrobacterium preparation, (2) seed sterilization, (3) cotton embryo excision, (4) lesion of shoot-cells by tungsten bombardment, (5) Agrobacterium-mediated transformation, (6) embryo co-culture, (7) regeneration and selection of transgenic plants in vitro, and (8) molecular characterization of plants. Due to the high regenerative power of the embryonic axis and the exceptional ability of the meristem cells for plant regeneration through organogenesis in vitro, this protocol can be performed in approximately 4-10 weeks, with an average plant regeneration of about 5.5% (± 0.53) and final average transformation efficiency of 60% (± 0.55). The transgene was stably inherited, and most transgenic plants hold a single copy of the transgene, as desirable and expected in Agrobacterium-mediated transformation. Additionally, the transgene was stably expressed over generations, and transgenic proteins could be detected at high levels in the T2 generation of GM cotton plants. The T2 progeny showed no phenotypic or productivity disparity compared to wild-type plants. Collectively, the use of cotton embryo axes and the enhanced DNA-delivery system by combining particle bombardment and Agrobacterium infection enabled efficient transgenic plant recovery, overcoming usual limitations associated with the recalcitrance of several cotton genotypes subjected to somatic embryogenesis. The improved approach states this method's success for cotton genetic modification, allowing us to obtain GM cotton plants carrying traits, which are of fundamental relevance for the advancement of global agribusiness.
Authors: Marcos Fernando Basso; Julia Almeida Costa; Thuanne Pires Ribeiro; Fabricio Barbosa Monteiro Arraes; Isabela Tristan Lourenço-Tessutti; Amanda Ferreira Macedo; Maysa Rosa das Neves; Sarah Muniz Nardeli; Luis Willian Arge; Carlos Eduardo Aucique Perez; Paolo Lucas Rodrigues Silva; Leonardo Lima Pepino de Macedo; Maria Eugênia Lisei-de-Sa; Regina Maria Santos Amorim; Eduardo Romano de Campos Pinto; Maria Cristina Mattar Silva; Carolina Vianna Morgante; Eny Iochevet Segal Floh; Marcio Alves-Ferreira; Maria Fatima Grossi-de-Sa Journal: Plant Physiol Biochem Date: 2021-05-17 Impact factor: 4.270
Authors: E Firoozabady; D L Deboer; D J Merlo; E L Halk; L N Amerson; K E Rashka; E E Murray Journal: Plant Mol Biol Date: 1987-03 Impact factor: 4.076
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Authors: Waseem Akbar; Anilkumar Gowda; Jeffrey E Ahrens; Jason W Stelzer; Robert S Brown; Scott L Bollman; John T Greenplate; Jeffrey Gore; Angus L Catchot; Gus Lorenz; Scott D Stewart; David L Kerns; Jeremy K Greene; Michael D Toews; David A Herbert; Dominic D Reisig; Gregory A Sword; Peter C Ellsworth; Larry D Godfrey; Thomas L Clark Journal: Pest Manag Sci Date: 2018-12-18 Impact factor: 4.845