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THÔNG TIN TÀI LIỆU
Cấu trúc
Jacket
Cover
TRANSGENIC PLANTS
Contents
Preface
Chapter 1. The Concept: Integration and Expression of Alien Genes in Transgenic Plants
1.1. Definitions of Gene Transfer
1.2. Horizontal Gene Transfer in Cellular Evolution
1.3. Early Attempts to Establish Transgenic Plants
1.4. Summary
Chapter 2. Transformation Approaches
2.1. Agrobacterium-Mediated Genetic Transformation of Plants
2.1.1. The first 70 years of crown gall research
2.1.2. The “molecular” era of Agrobacterium and crown gall research
2.1.3. The emergence of agrobacteria as mediators of genetic transformation in plants
2.1.4. Molecular mechanisms of T-DNA transfer into the plant’s genome
2.1.5. Protocols for Agrobacterium-mediated genetic transformation of plants
2.2. Direct Genetic Transformation
2.2.1. Direct transoformation of DNA into protoplasts
2.2.2. Genetic transformation by the biolistic process
2.3. Approaches to Genetic Transformation of Plants — Concluding Remarks
Chapter 3. Tools for Genetic Transformation
3.1. The Main Components of Plant Genes
3.2. Transformation Vectors
3.2.1. Fundamental considerations
3.2.2. Binary vectors
3.2.3. Helper plasmids
3.2.4. DNA constructs for “direct" transformation
3.3. Promoters, Terminators, Selectable Genes and Reporter Genes
3.3.1. Promoters
General purpose and specific promoters
Promoters for “monocots”
Some general remarks on promoters
3.3.2. Terminators
3.3.3. Selectable genes
Neomycin phosphotransferase
Hygromycin phosphotransferase
Phosphinothricin acetyltransferase
General remarks on selectable genes
3.3.4. Reporter genes
Chloramphenicol acetyl transferase–CAT
b-Glucuronidase–GUS
Luciferase
Green fluorescent protein
Sweet is transgenic
3.3.5. Killer genes
Chapter 4 Regulation of Heterologous Gene Expression
4.1. Functional Analysis of the CaMV 35S Promoter
4.2. Detailed Analysis of a Minimal Promoter: In Vitro Studies
4.3. External Factors Affecting Promoter Activity
Light responsive elements
4.4. Endogenous Factors Affecting Gene Expression
Abscisic-acid-induced Cis acting elements
4.5. Combination of Various Responsive Elements
4.6. Tissue and Cell Specificity
4.6.1. Tuber specificity and sucrose induction of patatin expression
4.6.2. Pollen-specific elements
4.6.3. Regulation of expression by the 5' and 3' flanking sequences and the leader intron
4.7. Introns
4.8. Targeting Sequences to Cellular Organelles
4.8.1. Unique features of plant endoplasmic reticulum (ER) and its relationship to the Golgi complex
4.8.2. Signal-mediated sorting of proteins to the plant vacuole and retention in ER-derived protein bodies
4.8.3. Targeting proteins to the nucleus
4.8.4. Protein targeting to peroxisomes and glyoxysomes
4.8.5. Protein targeting into the chloroplast
4.8.6. Protein targeting into and within the mitochondria
4.9. mRNA 5' and 3' Untranslated Regions Affect Gene Expression
4.10. The SAR/MAR Effect on Gene Expression
4.11. Plant Transcription Factors
4.12. Gene Silencing
4.13. Antisense RNA
Chapter 5. Crop Improvement
5.1. Crop Protection
5.1.1. Protection against biotic stresses
5.1.1.1. Viruses
5.1.1.2. Fungal pathogens
5.1.1.3. Bacteria
5.1.1.4. Nematodes
5.1.1.5. Insects
5.1.1.6. Weeds
5.1.1.7. Parasitic angiosperms
5.1.2. Protection against abiotic stresses
5.1.2.1. Protection against oxidative stress and against salinity, drought and cold stresses
5.1.2.2. Tolerance against metal toxicity
5.2. Improvement of Crop Quality
5.2.1. Improvement of nutritional quality
5.2.2. Improvement of post-harvest qualities
5.3. Ornamentals
5.3.1. Extension of flower-life
5.3.2. Pigmentation
5.3.3. Fragrances
5.4. Male-sterility for hybrid seed production
Chapter 6. Manufacture of Valuable Products
6.1. Transient Expression
6.2. Stable Expression
6.2.1. Production of antigens
6.2.2. Production of antibodies
6.2.2.1. Background
6.2.2.2. Examples
6.2.3. Other products
6.2.3.1. Oligopeptides and proteins
6.2.3.2. Sugar oligomers and polymers
6.2.3.3. Alkaloids and phenolics
6.2.3.4. Volatile (essential) oils
6.2.3.5. Degradable polymers
6.2.3.6. Enzymes for man and other animals
Chapter 7. Benefits and Risks of Producing Transgenic Plants
Appendix. Intellectual Property and Regulatory Requirements Affecting the Commercialisation of Transgenic Plants
A.1. The International Intellectual Property System
A.2. Plant Variety Protection
A.3. The Regular Patent System
A.3.1. Patent system concepts
A.3.2. Important differences among national systems
A.3.3. Typical coverage of actual patents
A.3.4. Implications for commercial firms
A.4. Trade Secrecy and Material Transfer Agreements
A.5. Biosafety and Product Labeling Considerations
A.6. Summary
References
References
Index
Nội dung
[...]... 6 TransKenic Plants 1.3 Early Attempts to Establish TransgenicPlants Before providing a short historical review on early attempts to establish transgenic plants, let us contemplate the problems involved in the stable integration and regulated expression of DNA in host plants This could be viewed as unfair to the pioneer-investigators, who attempted such integration of alien DNA into plants, because... plants 2.1.4 Molecular mechanisms of T-DNA transfer into the plant’s genome 2.1.5 Protocolsfor Agrobacterium-mediated genetic transformation of plants 2.2 Direct Genetic Transformation 2.2.1 Direct transoformation of DNA into protoplasts 2.2.2 Genetic transformation by the biolistic process ix 1 1 4 6 12 13 13 13 17 24 28 32 34 36 38 X TransgenicPlants 2.3 Approaches to Genetic Transformation of Plants. .. Preface V Chapter 1 The Concept: Integration and Expression of Alien Genes in TransgenicPlants 1.1 Definitions of Gene Transfer 1.2 Horizontal Gene Transfer in Cellular Evolution 1.3 Early Attempts to Establish TransgenicPlants 1.4 Summary Chapter 2 Transformation Approaches 2.1 Agrobacterium-Mediated Genetic Transformation of Plants 2.1.1 T h e first 70 years of crown gall research 2.1.2 T h e “molecular”... “corrected” plants did not segregate upon selfing Moreover, using “corrected” plants as pollinators in crosses to mutant plants resulted in a “corrected” progeny O n the other hand in the Fz of the “corrected” progeny a low frequency of thiamine-less The Concept: Integration and Expression of Alien Genes in TransgenicPlants 9 plants was observed The authors claimed that the ability to synthesise the... 191 196 197 198 207 207 212 214 217 221 223 2 23 226 234 236 238 239 241 242 244 Contents Chapter xiii 7 Benefits and Risks of Producing TransgenicPlants 249 Appendix Intellectual Property and Regulatory Requirements Affecting the Commercialisation of TransgenicPlants A 1 The International Intellectual Property System A.2 Plant Variety Protection A.3 The Regular Patent System A.3.1 Patent system... galls of cultivated Paris daisy and for the first time established that this “plant tumour” is of bacterial 13 14 TransgenicPlants origin They followed the Koch criterium and first isolated pure lines of ineffective bacteria These bacteria were used to inoculate healthy plants T h e infected plants developed the same type of tuinourous galls from which the bacteria were initially isolated Moreover, the... families Then methods The Concept: Zntegration and Expression of Alien Genes in TransgenicPlants 3 were devised to fuse protoplasts from different species and to regenerate from these heterofused protoplasts somatic hybrids and cybrids (see Evans and Bravo, 1983; Gleba and Sitnik, 1984; Galun, 1993 for reviews) Cybrids are plants, or cells, that have the nuclear genome of one (recipient) species and... in TransgenicPlants 1.1 Definitions of Gene Transfer The title of this chapter as well as those of the subsequent chapters outline the scope of this book The limited number of pages indicate that the book will focus on essential issues and will not provide full coverage of this emerging and fast-developing subject We shall first relate our meaning for several terms in the title of this chapter By plants. .. very useful They should provide the basis for future research and also explain why many of the early attempts did not result in the expected transgenicplants First we shall recall that DNA that is not integrated in the chromosorncs or in one of the genomes of the plants organelles is prone to be lost during cell divisions, especially during meiosis Thus, integration is required and it summons spccial... insertion of alien DNA into the plant’s genomes; i.e into the chromosomes or into either one of the two organelle genomes (mitochondrion, plastid) 2 Transgenic Plants Intra-specific transfer of genes is easily performed by cross hybridisation in all plants that can be propagated sexually Transfer of genes by cross hybridisation becomes more difficult or impossible with increasing phylogenetic distance . x0 y0 w1 h2" alt=""
TRANSGENIC
PLANTS
WITH
AN
APPENDIX
ON
INTELLECTUAL
PROPERTIES
&
COMMERCIALISATION
OF
TRANSGENIC
PLANTS
BY
JOHN
BARTON. y0 w5 h10" alt=""
TRANSGENIC
PLANTS
WITH
AN
APPENDIX
ON
INTELLECTUAL
PROPERTIES
&
COMMERCIALISATION
OF
TRANSGENIC
PLANTS
BY
JOHN
BARTON