[Report] Genetic Crop Portection Engineering Market Research, Trends, Analysis TOC

1. Executive Summary

2. Overview of Crop Protection Technologies

1. Conventional Crop Protection Technology
- 1. Herbicides for Crop Protection
- 2. Insecticides for Crop Protection
2. Genetic Engineering Technology
- 1. Genetic Engineering
- 2. Genetic Engineering Methodology
- 3. Herbicide Tolerant Crops

3. Herbicides and Herbicide Tolerant Crops

1. Aquatic Herbicides
- 1. Introduction
- 2. Glyphosate and Fluridone
- 3. Endothall and Triclopyr
- 4. Imazapyr and Diquat
2. Herbicide Tolerance By Selection
- 1. Sulfonylurea Tolerance
- 2. Aminotriazole Tolerance
- 3. Paraquat Tolerance
- 4. Imidazolinone Tolerance
3. Herbicide Tolerance by Molecular Breeding
- 1. Bromoxynil Tolerance
- 2. Glufosinate Tolerance
- 3. Protoporphyrinogen Tolerance
- 4. Paraquat Tolerance
4. Research and Development In Herbicide Tolerant Crops
- 1. Genetically Controlled Herbicide Resistance in Cotton Crop: USA
- 2. Herbicidal Compositions for Tolerant Cereal Crops: Denmark
- 3. Structure-Based; Herbicide-Resistant Products: USA
- 4. Gene Modification for Encoding Mutated EPSPS: France
- 5. Obtain Transgenic Plants with a Silent Marker: USA
- 6. Herbicides for Tolerant Sugar Beet Cultures: Denmark
- 7. Inducible Herbicide Resistance in Crops: UK
5. Drivers and Challenges
- 1. Drivers
  - a. Herbicide tolerant crops simplify weed management
  - b. Less residual activity of herbicides in case of herbicide tolerant crops.
- 2. Challenges
  - a. Crop quality and yield issues in herbicide tolerant crops.
  - b. Herbicide tolerant crops yield products with lower nutritional level.
  - c. Environmental concerns regarding the chemical dependence of herbicide tolerant crops

4. Insecticides and Insecticide Tolerant Crops

1. Bacillus Thuringiensis (Bt) Derived Products
- 1. Bollgard and Ingard Cotton
- 2. Insect-Resistant Rice
2. Insect Control by Nematode Resistant Genes
- 1. Nematode Antibody Genes
- 2. Protease Inhibitors
3. Insect Control by Other Insect-Active Protein Genes
- 1. Lectin Genes
- 2. Gene Stacking
- 3. Other Toxic Genes
- 4. Protease Inhibitor Genes
4. Research and Development In Insecticides Tolerant Crops
- 1. Insect Control Via Genetically Engineered Bioinsecticides: USA
- 2. Insecticide Resistant Seeds: USA
- 3. Insecticide Resistant Corn : USA
5. Drivers and Challenges
- 1. Drivers
  - a. Existing technology paves way for newer technology developments.
  - b. Insecticide tolerant crops reduce soil erosion.
- 2. Challenges
  - a. Environmental legislation limit the use of crop protection chemicals.
  - b. Acceptance of genetically engineered crops threaten to choke crop protection chemical technologies.

5. Tissue Culture

1. Genetic Engineering in Crop Protection
- 1. Genetic Engineering for Crop Protection
- 2. Impact of Genetically Engineered Crops
2. Tissue Culture
- 1. Introduction
- 2. Tissue Culture and Crop Protection
- 3. Somatic Hybridization
3. Research and Development
- 1. Terminator Technology: USA
- 2. Trait Specific Genetic Use Restriction Technology: USA
- 3. Degrading and Detoxifying Fumonisin: USA
- 4. Genetically Modified Cotton: Australia
- 5. Genetic Engineered Plant Chloroplast: USA
- 6. Improve Crop Stress Tolerance by Expressing Choline Monooxygenase: USA
- 7. Increasing Plant Sulfur Content: Germany
- 8. Metal Binding Compounds for Cell Culture Media: USA
- 9. Somatic Embryogenesis for Plant Reproduction: USA
- 10. Control Plant Cell Death and Disease-Resistance Capacity: USA
- 11. Pest-Resistant Transgenic Plants: USA
- 12. Manipulate Ectophosphate Genes for Herbicidal Resistance: USA
4. Drivers and Restraints
- 1. Drivers
  - a. Nonfood applications fueling growth of genetic engineering
  - b. Patent expiry leads to further research
  - c. Comparative advantage of biotechnology
- 2. Restraints
  - a. Genetically engineered plants create biological pollution.
  - b. Wide use of Bacillus Thuringiensis (Bt) crops lead to Bt-resistant insects.
  - c. Financial rewards from intellectual property to influence investment decisions in private sector.
  - d. Cost of the technology limits its use.
  - e. Low consumer demand affect adoption of genetically modified crops

6. Transgenic Crops

1. Introduction
- 1. What are Transgenic Crops?
- 2. Production Methodology and Applications
2. Key Transgenic Products
- 1. Tomatoes and Golden Rice
- 2. Canola and Sunflower
- 3. Plant-Based Vaccines and Improved Turfgrass
- 4. Grapes and Wine
- 5. Coffee; Tea and Tobacco
3. Research and Development
- 1. Transgenic Method of Controlling Worms in Cotton: USA
- 2. Transgenic Plants with Oxidative Stress Resistance Gene: UK
- 3. Deploying a Transgenic Refuge: USA
- 4. Transgenic Plants Metabolize Foreign Compounds: Japan
- 5. Produce Corn Hybrid Transgene P741: USA
- 6. Transgenic Plants Resistant to a Broad Pathogenic Spectrum: Canada
- 7. Transgenic Tetraploids: Korea
- 8. Cicer and Abutilon as Refuges in Transgenic Crops: USA
- 9. Transgenic Crops for Detoxifying Fumonisin Compounds: USA
4. Drivers and Restraints
- 1. Drivers
  - a. Comparative advantage of biotechnology
  - b. Politics influences biotechnology development
- 2. Restraints
  - a. Public perception vital for technological success.
  - b. Creation of transgenes for select crops
  - c. Lack of wide-scale approval of transgenic crops affect technology innovations.

7. Regulations and Patent Laws

8. Patents and Company Profiles

1. Patents
- 1. US Patents
- 2. European Patents
- 3. Asia-Pacific Patents
2. Company Profiles
- 1. North America
- 2. Europe; Middle East and Africa
- 3. Asia-Pacific

9. Frost & Sullivan Science and Technology Awards

10. Decision Support Databases

Genetic Engineering for Crop Protection