Abstract
Mechanisms are needed to prevent gene flow from transgenic crops, and the later establishment of these transgenes in populations of other varieties, weeds, or wild relatives. Such prevention can be achieved by containing the transgene within a crop, and then mitigating the effects of the inherent leakage and unidirectionality of containment systems. Mitigation lowers the fitness of recipients below that of the wild-type so that transgenes cannot spread. Transplastomic and male-sterility systems suppress transgene outflow, but not the influx of pollen from relatives, requiring mitigation. The Arabidopsis thaliana Δgai (gibberellic acid–insensitive) gene, driven by its own promoter, induced male sterility in transgenic tobacco (Nicotiana tabacum), which is chemically reversible by kinetin applications. Female reproduction was not affected. Kinetin-treated sterile hemizygous and homozygous dwarf tobacco produced viable pollen, becoming self-fertile with copious viable seed, restoring the small amount of seed production needed for such a crop. Thus, Δgai, under its endogenous promoter, can be used as a containment mechanism to prevent transgene outflow. This application is in addition to the previously described highly effective role of Δgai as a dwarfing mitigator gene, which renders the rare transgenic tobacco hybrids unfit and unable to compete with the wild-type in the mixed cultures. Δgai is unique in that it can be used both to prevent transgene outflow and to mitigate the flow should containment fail or should gene influx occur, a dual role for the gene, not previously reported.
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References
Ahokas H. 1982. Cytoplasmic male sterility in barley: evidence for the involvement of cytokinins in fertility restoration. Proc Natl Acad Sci USA 79:7605–7608
Al-Ahmad H, Galili S, Gressel J. 2004. Tandem constructs to mitigate transgene persistence: tobacco as a model. Mol Ecol 13:697–710
Al-Ahmad H, Galili S, Gressel J. 2005a. Poor competitive fitness of transgenically mitigated tobacco in competition with the wild type in a replacement series. Planta DOI: 10.1007/s00425-005-1540-6
Al-Ahmad H, Dwyer J, Moloney M, Gressel J. 2005b. Migration of establishment of Bracssica napus transgenes in volunteers using a tandem construct containing a selectively unfit gene. Plant Biotech J (in press)
Blazquez MA, Weigel D. 2000. Integration of floral inductive signals in Arabidopsis. Nature 404:889–892
Cheng H, Qin LJ, Lee SC, Fu XD, Richards DE. 2004. Gibberellin regulates Arabidopsis floral development via suppression of DELLA protein function. Development 131:1055–1064
Daniell H. 2002. Molecular strategies for gene containment in transgenic crops. Nat Biotechnol 20:581–586
Galun E, Galun E. 2001. The manufacture of medical and health products by transgenic plants. London, UK, Imperial College Press, 332 p
Gressel J. 1999. Tandem constructs: preventing the rise of superweeds. Trends Biotechnol 17:361–366
Gressel J. 2002. Molecular biology of weed control. London, Taylor and Francis, 520 p
Gressel J, Al-Ahmad H. 2005. Molecular containment and mitigation of genes within crops: prevention of gene establishment in volunteer offspring and feral strains. In: Gressel J (ed.), Crop ferality and volunteerism. Boca-Raton, FL, USA, CRC Press, pp. 371–388
Hajdukiewicz P, Svab Z, Maliga P. 1994. The small, versatile pPZP family of Agrobacterium binary vectors for plant transformation. Plant Mol Biol 25:989–994
Horsch RB, Fry JE, Hoffmann NL, Eichholtz D, Rogers SG. 1985. A simple and general method for transferring genes into plants. Science 227:1229–1231
Huang S, Cerny RE, Qi YL, Bhat D, Aydt CM. 2003. Transgenic studies on the involvement of cytokinin and gibberellin in male development. Plant Physiol 131:1270–1282
Hynes LW, Peng JR, Richards DE, Harberd NP. 2003. Transgenic expression of the Arabidopsis DELLA proteins GAI and gai confers altered gibberellin response in tobacco. Transgenic Res 12:707–714
Izhaki A, Borochov A, Zamski E, Weiss D. 2002. Gibberellin regulates post-microsporogenesis processes in petunia anthers. Physiol Plant 115:442–447
Jacobsen SE, Olszewski NE. 1991. Characterization of the arrest in anther development associated with gibberellin deficiency of the gib-1 mutant of tomato. Plant Physiol 97:409–414
Jepson I. 2002. Inducible herbicide resistance. US Patent 6,380,463
Keenan RJ, Stemmer WPC. 2002. Nontransgenic crops from transgenic plants. Nat Biotechnol 20:215–216
Koornneef M, Elgersma A, CJ Hanhart C, van Loenen-Martinet E, van Rijn L. 1985. A gibberellin insensitive mutant of Arabidopsis thaliana. Physiol Plantarum 65:33–39
Kuvshinov V, Anissimov A, Yahya BM. 2004.Barnase gene inserted in the intron of GUS-a model for controlling transgene flow in host plants. Plant Sci 167:173–182
Maliga P. 2004. Plastid transformation in higher plants. Annu Rev Plant Biol 55:289–313
Mallory-Smith C, Thill DC, Dial MJ, Zemetra R. 1990. Inheritance of sulfonylurea herbicide resistance in Lactuca spp. Weed Tech 4:787–790
Mariani C, Gossele V, Debeuckeleer M, Deblock M, Goldberg RB. 1992. A chimeric ribonuclease-inhibitor gene restores fertility to male sterile plants. Nature 357:384–387
Nester JE, Zeevaart JAD. 1988. Flowering development in normal tomato and a gibberellin-deficient (ga-2) mutant. Am J Bot 75:45–55
O1iver MJ, Lou H, Kausch A, Collins H. 2004. Seed-based strategies for transgene containment. In: Proceedings 8th International Symposium on the Biosafety of Genetically Modified Organisms. Montpellier, France: International Society for Biosafety Research, p 154–161 (available online at: http://www.isbr.info/document/proceedings_montpellier2004.pdf)
Peng JR, Harberd NP. 1993. Derivative alleles of the Arabidopsis gibberellin-insensitive (gai) mutation confer a wild-type phenotype. Plant Cell 5:351–360
Phillips RL. 1981. Pollen and pollen tubes, In: Clark G (ed.) Staining procedures. Baltimore, USA, Williams and Wilkins, pp. 361–366
Sawhney VK, Shukla A. 1994. Male sterility in flowering plants: are plant growth substances involved? Am J Bot 81:1640–1647
Schernthaner JP, Fabijanski SF, Arnison PG, Racicot M, Robert LS. 2003. Control of seed germination in transgenic plants based on the segregation of a two-component genetic system. Proc Natl Acad Sci USA 100:6855–6859
Schmulling T, Rohrig H, Pilz S, Walden R, Schell J. 1993. Restoration of fertility by antisense RNA in genetically engineered male sterile tobacco plants. Mol Gen Genet 237:385–394
Stewart CN, Halfhill MD, Warwick SI. 2003. Transgene introgression from genetically modified crops to their wild relatives. Nat Rev Genet 4:806–817
Tomiuk J, Hauser TP, Bagger-Jørgensen R. 2000. A- or C-chromosomes, does it matter for the transfer of transgenes from Brassica napus. Theor Appl Genet 100:750–754
Wang T, Li Y, Shi Y, Reboud X, Darmency H, Gressel J. 2004. Low frequency transmission of a plastid-encoded trait in Setaria italica. Theor Appl Genet 108:315–320
Wilson RN, Heckman JW, Somerville CR. 1992. Gibberellin is required for flowering in Arabidopsis thaliana under short days. Plant Physiol 100:403–408
Acknowledgments
The authors are grateful to Judith Karmi and Alexandra Savitsky for their excellent technical assistance; to Drs. Donald Richards and Nick Harberd, Department of Molecular Genetics, John Innes Centre, UK, for providing the Δgai gene; to Dr. Shihshieh Huang, Monsanto Company, USA for his advice and experience in kinetin application to tobacco; and to Dr. Dvora Aviv for advice on tissue culture and breeding. This research was supported by the Levin Foundation, by INCO-DC contract no. ERB 1C18 CT 98 0391, and a bequest from Israel and Diana Safer. We thank Chaim Barak for his assistance in the photography of the plants.
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Al-Ahmad, H., Gressel, J. Transgene Containment Using Cytokinin-Reversible Male Sterility in Constitutive, Gibberellic Acid–Insensitive (Δgai) Transgenic Tobacco. J Plant Growth Regul 24, 19–27 (2005). https://doi.org/10.1007/s00344-004-0003-9
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DOI: https://doi.org/10.1007/s00344-004-0003-9