Pocket K No. 17: Genetic Engineering and GM Crops


Over the last 50 years, the field of genetic engineering has developed rapidly due to the greater understanding of deoxyribonucleic acid (DNA) as the chemical double helix code from which genes are made. The term genetic engineering is used to describe the process by which the genetic makeup of an organism can be altered using “recombinant DNA technology.” This involves the use of laboratory tools to insert, alter, or cut out pieces of DNA that contain one or more genes of interest.

Developing plant varieties expressing good agronomic characteristics is the ultimate goal of plant breeders. With conventional plant breeding, however, there is little or no guarantee of obtaining any particular gene combination from the millions of crosses generated. Undesirable genes can be transferred along with desirable genes; or, while one desirable gene is gained, another is lost because the genes of both parents are mixed together and re-assorted more or less randomly in the offspring. These problems limit the improvements that plant breeders can achieve.

In contrast, genetic engineering allows the direct transfer of one or just a few genes of interest, between either closely or distantly related organisms to obtain the desired agronomic trait (Figure 1). Not all genetic engineering techniques involve inserting DNA from other organisms. Plants may also be modified by removing or switching off their own particular genes.

Figure 1. Comparing conventional breeding and genetic engineering.
Source: Agricultural Biotechnology (A Lot More than Just GM Crops). https://www.isaaa.org/resources/publications/agricultural_biotechnology/download/

 

Conventional Breeding Genetic Engineering
  • Limited to exchanges between the same or very closely related species
  • Little or no guarantee of any particular gene combination from the million of crosses generated
  • Undesirable genes can be transferred along with desirable genes
  • Takes a long time to achieve desired results
  • Allows the direct transfer of one or just a few genes, between either closely or distantly related organisms
  • Crop improvement can be achieved in a shorter time compared to conventional breeding
  • Allows plants to be modified by removing or switching off particular genes

Source: Agricultural Biotechnology (A Lot More than Just GM Crops). https://www.isaaa.org/resources/publications/agricultural_biotechnology/download/.

Genes are molecules of DNA that code for distinct traits or characteristics.  For instance, a particular gene sequence is responsible for the color of a flower or a plant’s ability to fight a disease or thrive in extreme environment.

Nature’s own genetic engineer

The “sharing” of DNA among living forms is well documented as a natural phenomenon. For thousands of years, genes have moved from one organism to another. For example, Agrobacterium tumefaciens, a soil bacterium known as ‘nature’s own genetic engineer’, has the natural ability to genetically engineer plants. It causes crown gall disease in a wide range of broad-leaved plants, such as apple, pear, peach, cherry, almond, raspberry, and roses. The disease gains its name from the large tumor-like swellings (galls) that typically occur at the crown of the plant, just above soil level. Basically, the bacterium transfers part of its DNA to the plant, and this DNA integrates into the plant’s genome, causing the production of tumors and associated changes in plant metabolism.

Application of genetic engineering in crop production

Genetic engineering techniques are used only when all other techniques have been exhausted, i.e. when the trait to be introduced is not present in the germplasm of the crop; the trait is very difficult to improve by conventional breeding methods; and when it will take a very long time to introduce and/or improve such trait in the crop by conventional breeding methods (see Figure 2). Crops developed through genetic engineering are commonly known as transgenic crops or genetically modified (GM) crops.

Modern plant breeding is a multi-disciplinary and coordinated process where a large number of tools and elements of conventional breeding techniques, bioinformatics, molecular genetics, molecular biology, and genetic engineering are utilized and integrated.

Figure 2:  Modern Plant Breeding

Source: DANIDA, 2002.

 

Development of transgenic crops

Although there are many diverse and complex techniques involved in genetic engineering, its basic principles are reasonably simple. There are five major steps in the development of a genetically engineered crop. But for every step, it is very important to know the biochemical and physiological mechanisms of action, regulation of gene expression, and safety of the gene and the gene product to be utilized. Even before a genetically engineered crop is made available for commercial use, it has to pass through rigorous safety and risk assessment procedures.

The first step is the extraction of DNA from the organism known to have the trait of interest. The second step is gene cloning, which will isolate the gene of interest from the entire extracted DNA, followed by mass-production of the cloned gene in a host cell. Once it is cloned, the gene of interest is designed and packaged so that it can be controlled and properly expressed once inside the host plant. The modified gene will then be mass-produced in a host cell in order to make thousands of copies. When the gene package is ready, it can then be introduced into the cells of the plant being modified through a process called transformation.  The most common methods used to introduce the gene package into plant cells include biolistic transformation (using a gene gun) or Agrobacterium-mediated transformation. Once the inserted gene is stable, inherited, and expressed in subsequent generations, then the plant is considered a transgenic. Backcross breeding is the final step in the genetic engineering process, where the transgenic crop is crossed with a variety that possesses important agronomic traits, and selected in order to obtain high quality plants that express the inserted gene in a desired manner.

The length of time in developing transgenic plant depends upon the gene, crop species, available resources, and regulatory approval. It may take 6-15 years before a new transgenic hybrid is ready for commercial release.

Commercially available crops improved through genetic engineering

Transgenic crops have been planted in different countries for twenty years, starting from 1996. About 191.7  million hectares was planted in 2018 to transgenic crops with high market value, such as herbicide tolerant soybean, maize, cotton, and canola; insect resistant maize, cotton, potato, and rice; and virus resistant squash and papaya. With genetic engineering, more than one trait can be incorporated or stacked into a plant. Transgenic crops with combined traits are also available commercially. These include herbicide tolerant and insect resistant maize, soybean and cotton.

New and future initiatives in crop genetic engineering

To date, commercial GM crops have delivered benefits in crop production, but there are also a number of products in the pipeline which will make more direct contributions to food quality, environmental benefits, pharmaceutical production, and non-food crops. Examples of these products include: triple stack trait biotech rice with better yield amidst abiotic stresses, biotech chestnut tree with resistance to chestnut blight, biotech citrus greening resistant citrus, potato enriched with beta carotene, biofortified sorghum, bacterial (Xanthomonas) wilt resistant banana, Bunchytop virus resistant banana, insect resistant wheat, among others.


References:

  • Agricultural Biotechnology in Europe. 2003. Future Developments in Crop Biotechnology. Issue Paper 6. http://cms.daegu.ac.kr/sgpark/life&chemistry/future.pdf.
  • DANIDA. 2002. Assessment of Potentials and Constraints for Development and Use of Plant Biotechnology in Relation to Plant Breeding and Crop Production in Developing Countries. Ministry of Foreign Affairs, Denmark.
  • Desmond, S. and T. Nicholl. 1994. An Introduction to Genetic Engineering. Cambridge University Press.
  • Giddings, G., G. Allison, D. Brooks, and A. Carter. 2000. Transgenic Plant as Factories for Biopharmaceuticals. Nature Biotechnology 18: 1151-1155.
  • Goto, F., R. Yoshihara, N. Shigemoto, S. Toki, and F. Takaiwa. 1999. Iron Fortification of Rice Seed by the Soybean Ferritin Gene. Nature Biotechnology 17: 282-286.
  • ISAAA. 2018. Global Status of Commercialized Biotech/GM Crops: 2018. ISAAA Brief No. 54. ISAAA: Ithaca, NY.
  • Lopez-Bucio, J., O. M. de la Vega, A. Guevara-Garcia, and L. Herera-Estrella. 2000. Enhanced Phosphorous Uptake in Transgenic Tobacco Plants that Overproduce Citrate. Nature Biotechnology 18: 450-453.
  • Robinson, C. 2001. Genetic Modification Technology and Food: Consumer Health and Safety. ILSI Europe Concise Monograph Series. http://www.ilsi.org/Europe/Publications/C2002Gen_Mod.pdf.
  • University of Nebraska – Lincoln. 2015. Overview of Crops Genetic Engineering. http://passel.unl.edu/pages/informationmodule.php?
    idinformationmodule=957879329&topicorder=8&maxto=9.
  • Ye, X., S. Al-Babili, A. Kloti, J. Zhang, P. Lucca, and I. Potrykus. 2000. Engineering the Provitamin A (b-carotene) Biosynthetic Pathway into (Carotinoid-Free) Rice Endosperm.  Science 287(5451): 303-305..

*Updated March 2020

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