TY - JOUR
T1 - Comparison of direct and indirect embryogenesis protocols, biolistic gene transfer and selection parameters for efficient genetic transformation of sugarcane
AU - Taparia, Yogesh
AU - Gallo, Maria
AU - Altpeter, Fredy
N1 - Funding Information:
Acknowledgments The authors would like to thank USDA-NIFA for financial support of this work; Dr. Robert Gilbert, Everglades Research and Educational Center, Belle-Glade, University of Florida (UF), Belle Glade FL for providing access to donor plants of sugar-cane cultivar CP 88-1762; Jeff Seib for training Yogesh Taparia in safe handling of radio isotopes; the Conrad Fafard Inc., Apopka, FL for donation of plant growth media.
PY - 2012/10/1
Y1 - 2012/10/1
N2 - The comparison of direct and indirect somatic embryogenesis (DSE and ISE) for biolistic transformation of sugarcane by minimal expression cassettes indicated the highest transformation efficiency with ISE (2.2 independent transgenic plants per shot) and the most rapid production of transgenic plants with DSE (12 weeks from explant to plants in soil). Microprojectiles of 0. 3 μm diameter produced 5 times more transgenic lines than 1 μm microprojectiles when used at the same weight basis per shot. A significant reduction of the number of hybridization signals in the Southern blot was also observed with 0. 3 μm microprojectiles when compared to 1.0 μm microprojectiles. This suggests that the lower DNA carrying capacity and greater number of the smaller microprojectiles contributes to more transgenic lines with less complex transgene integration. When geneticin sulfate, was used for selection following DSE, significantly more (4.8 times) transgenic plants were produced than with paromomycin sulfate and an equal number of non-expressing plants were produced with both selection agents. In conclusion, optimization of two alternative morphogenic routes for regeneration (DSE and ISE), biolistic and selection parameters generated rooted, transgenic plants of a commercially important sugarcane cultivar with simple transgene integration and within 12 or 19 weeks of culture initiation, respectively. Reducing the complexity of the transgene integration and minimizing the time in tissue culture will likely enhance the performance of the transgenic events.
AB - The comparison of direct and indirect somatic embryogenesis (DSE and ISE) for biolistic transformation of sugarcane by minimal expression cassettes indicated the highest transformation efficiency with ISE (2.2 independent transgenic plants per shot) and the most rapid production of transgenic plants with DSE (12 weeks from explant to plants in soil). Microprojectiles of 0. 3 μm diameter produced 5 times more transgenic lines than 1 μm microprojectiles when used at the same weight basis per shot. A significant reduction of the number of hybridization signals in the Southern blot was also observed with 0. 3 μm microprojectiles when compared to 1.0 μm microprojectiles. This suggests that the lower DNA carrying capacity and greater number of the smaller microprojectiles contributes to more transgenic lines with less complex transgene integration. When geneticin sulfate, was used for selection following DSE, significantly more (4.8 times) transgenic plants were produced than with paromomycin sulfate and an equal number of non-expressing plants were produced with both selection agents. In conclusion, optimization of two alternative morphogenic routes for regeneration (DSE and ISE), biolistic and selection parameters generated rooted, transgenic plants of a commercially important sugarcane cultivar with simple transgene integration and within 12 or 19 weeks of culture initiation, respectively. Reducing the complexity of the transgene integration and minimizing the time in tissue culture will likely enhance the performance of the transgenic events.
KW - Biolistic transformation
KW - Direct somatic embryogenesis
KW - Geneticin sulfate
KW - Indirect somatic embryogenesis
KW - Microprojectile size
KW - Paromomycin sulfate
UR - http://www.scopus.com/inward/record.url?scp=84867101578&partnerID=8YFLogxK
U2 - 10.1007/s11240-012-0177-y
DO - 10.1007/s11240-012-0177-y
M3 - Article
AN - SCOPUS:84867101578
SN - 0167-6857
VL - 111
SP - 131
EP - 141
JO - Plant Cell, Tissue and Organ Culture
JF - Plant Cell, Tissue and Organ Culture
IS - 2
ER -