Abstract
Genetically-modified coffee clones (GMCs) were presented in a previous work. They were created from a single commercial clone of Coffea canephora Pierre (clone 126). Therefore they all have the same genotype, except for the localization of the transgenic insertions. They synthesize the Bacillus thuringiensis endotoxin Cry1Ac against Leucoptera coffeella Guérin-Méneville, a secondary pest of C. canephora and one of the main pest of C. arabica in South America. The synthetic Cry1Ac gene is regulated by the EF1α-A1 promoter of Arabidopsis thaliana (L.) Heynh. They were tested in an experimental field for their resistance against the pest insect in a previous work. In the present work, levels of Cry1Ac were measured in the leaves. The insecticidal protein was evenly distributed in all the leaves. Cry1Ac levels were measured once in the coffee plants of a sensitive GMC and of 14 resistant ones grown in the experimental field and in plants grown in a greenhouse. Some resistant GMCs contained higher levels but it is not possible to confirm that it would be enough for a sustainable resistance to the pest. Growth speed was variable in the plot. The correlation with plant height and other indicators of plant growth was examined. Cry1Ac levels in the GMCs were negatively correlated with growth speed. The latter was not statistically influenced neither by Cry1Ac synthesis nor by the genetic modification in itself as seen by comparing the GMCs and the unmodified control clone 126. Hence the conclusion is that the growth conferred to field-grown plants by environmental factors and especially the soil was probably the underlying cause of the negative correlation. Other field experiments would be necessary in order to confirm this result. It would be important that the genetic construct inserted in these GMCs and mainly the EF1α-A1 promoter of the Cry1Ac gene be reconsidered since Cry1Ac levels might be too low to provide efficient and sustainable protection against L. coffeella in a highly favourable environment for coffee plants. Alternatives are discussed.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
Abbreviations
- GMC (s):
-
Genetically-modified clone(s)
- GM:
-
Genetically-modified
- fw:
-
Fresh weight
- Bt:
-
Bacillus thuringiensis
References
Adamczyk JJ, Hardee DD, Adams LC et al (2001) Correlating differences in larval survival and development of bollworm (Lepidoptera: noctuidae) and fall armyworm (Lepidoptera: Noctuidae) to differential expression of Cry1A (c) delta-endotoxin in various plant parts among commercial cultivars of transgenic Bacillus thuringiensis cotton. J Econ Entomol 94(1):284–290
Aida R, Nagaya S, Yoshida K et al (2005) Efficient transgene expression in chrysanthemum, Chrysanthemum morifolium ramat., with the promoter of a gene for tobacco elongation factor 1 alpha protein. Jpn Agric Res Q 39(4):269–274
Brandle JE, Miki BL (1993) Agronomic performance of sulfonylurea-resistant transgenic flue-cured tobacco grown under field condition. Crop Sci 33(4):847–852
Bruns HA, Abel CA (2007) Effects of nitrogen fertility on Bt endotoxin levels in maize. J Entomol Sci 42(1):35–43
Callis J, Raasch JA, Vierstra RD et al (1990) Ubiquitin extension proteins of Arabidopsis thaliana. Structure, localization, and expression of their promoters in transgenic tobacco. J Biol Chem 265:12486–12493
Curie C, Liboz T, Bardet C et al (1991) Cis and trans-acting elements involved in the activation of Arabidopsis thaliana A1 gene encoding the translation elongation factor EF-1α. Nucleic Acids Res 19(6):1305–1310
De Guglielmo-Cróquer Z, Altosaar I, Zaidi M et al (2010) Transformation of coffee (Coffea Arabica L. cv. Catimor) with the cry1ac gene by biolistic, without the use of markers. Braz J Biol 70(2):387–393
Ducos JP, Alenton R, Reano JF et al (2003) Agronomic performance of Coffea canephora P. trees derived from large-scale somatic embryo production in liquid medium. Euphytica 131(2):215–223
Fragoso DB, Guedes RNC, Picanço MC et al (2002a) Insecticide use and organophosphate resistance in the coffee leaf miner Leucoptera coffeella (Lepidoptera: Lyonetiidae). Bull Entomol Res 92(3):203–212
Fragoso DB, Jusselino Filho P, Pallini Filho A et al (2002b) Action of organophosphorate insecticides used to control Leucoptera coffeella (Guérin-Mèneville) (Lepidoptera: Lyonetiidae) on the predator mite Iphiseiodes zuluagai. Neotrop Entomol 31(3):463–467
Gould F (1998) Sustainability of transgenic insecticidal cultivars: integrating pest genetics and ecology. Annu Rev Entomol 43:701–726
Greenplate JT (1999) Quantification of Bacillus thuringiensis insect control protein Cry1Ac over time in Bollgard cotton fruit and terminals. J Econ Entomol 92(6):1377–1383
Guerreiro O, Denolf P, Peferoen M, Decazy B, Eskes AB, Frutos F (1998) Susceptibility of the coffee leaf miner (Perileucoptera spp.) to Bacillus thuringiensis δ-endotoxins: a model for transgenic perennial crops resistant to endocarpic insects. Curr Microbiol 36:175–179
Halpin C (2005) Gene stacking in transgenic plants-the challenge for 21st century plant technology. Plant Biotechnol J 3:141–155
Kay R, Chan A, Daly M et al (1987) Duplication of CaMV35S promoter sequences creates a strong enhancer for plant genes. Science 236:1299–1302
Leroy T, Henry AM, Royer M et al (2000) Genetically modified coffee plants expressing the Bacillus thuringiensis cry1Ac gene for resistance to leaf miner. Plant Cell Rep 19(4):382–389
Martins CM, Beyene G, Hofs JL et al (2008) Effect of water-deficit stress on cotton plants expressing the Bacillus thuringiensis toxin. Annals of Applied Biology 152(2):255–262
Nantes JFD, Parra JRP (1977) Biologia de Perileucoptera coffeella (Guérin-Mèneville, 1842) (Lepidoptera-Lyonetiidae), em três variedades de café (Coffea spp). Anais do Sociedade Entomológica do Brasil 6:156–163
Perthuis B, Pradon JL, Montagnon C et al (2005) Stable resistance against the leaf miner Leucoptera coffeella expressed by genetically transformed Coffea canephora in a pluriannual field experiment in French Guiana. Euphytica 144(3):321–329
Pettigrew WT, Adamczyk JJ (2006) Nitrogen fertility and planting date effects on lint yield and Cry1Ac (Bt) endotoxin production. Agron J 98(3):691–697
Pinto FO, Maluf MP, Guerreiro-Filho O (2007) Study of simple sequence repeat markers from coffee expressed sequences associated to leaf miner resistance. Pesqui Agropecu Brasileira 42(3):377–384
Pouteau S, Huttner E, Grandbastien M et al (1991) Specific expression of the tobacco Tnt1 retrotransposon in protoplasts. EMBO J 10:1911–1918
Purrington CB, Bergelson J (1997) Fitness consequences of genetically engineered herbicide and antibiotic resistance in Arabidopsis. Genetics 145(3):807–814
Purrington CB, Bergelson J (1999) Exploring the physiological basis of costs of herbicide resistance in Arabidopsis thaliana. Am Nat 154(S1):S82–S91
Rochester IJ (2006) Effect of genotype, edaphic, environmental conditions, and agronomic practices on Cry1Ac protein expression in transgenic cotton. J Cotton Sci 10:252–262
Smirnova OG, Ibragimova SS, Kochetov AV (2012) Simple database to select promoters for plant transgenesis. Transgenic Res 21:429–437
Van Boxtel J, Berthouly M, Carasco C, Dufour M, Eskes AB (1995) Transient expression of β-glucuronidase following biolistic delivery of foreign DNA into coffee tissues. Plant Cell Rep 14(12):748–752
Wei W, Schuler TH, Clark S et al (2005) Age-related increase in levels of insecticidal protein in the progenies of transgenic oilseed rape and its efficacy against a susceptible strain of diamondback moth. Ann Appl Biol 147(3):227–234
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Perthuis, B., Vassal, JM., Fenouillet, C. et al. Cry1Ac insecticidal protein levels in genetically modified Coffea canephora Pierre coffee plants were negatively correlated with the growth speed in a field experiment. Euphytica 202, 373–383 (2015). https://doi.org/10.1007/s10681-014-1258-2
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s10681-014-1258-2