Temporal and Spatial Regulation of Plant Genes - Brossura

Contenuti

1 Arabidopsis as a Tool for the Identification of Genes Involved in Plant Developmen.- I. Introduction.- II. Phytohormone Mutants.- A. Introduction.- B. Auxin.- C. Ethylene.- D. Gibberellins.- E. Abscisic Acid.- III. Environmental Regulation of Growth and Development.- A. Introduction.- B. Tropic Responses.- C. Phytochrome.- D. Flowering Induction.- IV. Conclusions and Future Directions.- V. References.- 2 Regulation of Gene Expression During Seed Germination and Postgerminative Developmen.- I. Introduction.- II. Differential Gene Expression Underlies Seed Germination.- III. Spatial Regulation of Postgermination-Abundant Genes.- IV. Activation of Postgermination-Abundant Genes.- V. Future Directions.- VI. References.- 3 Genes Involved in the Patterns of Maize Leaf Cell Divisio.- I. Introduction.- II. The Shoot Apical Meristem as a Self-Regulating Unit.- III. Heterochrony.- IV. Maize Leaf Mesophyll and Epidermis Lineage Maps.- V. Leaf Vascularization and Development Compartments.- VI. The Importance of Periclinal Divisions.- VII. Strict Versus Loose Programming of Epidermal Cell Division.- VIII. Alternative Models Involving the Programming of Cell Division.- IX. The Ligule and Mutants that Affect It.- X. Kn 1: Neomorphic Mutants that Induce the Epidermis to Divide.- XI. Conclusions About Leaf and Ligule Development Derived from Mutant Analyses, and the Concept of Cell Age Identity.- XII. Where Are the Molecules.- XIII. References.- 4 Molecular Analysis of Genes Determining Spatial Patterns in Antirrhinum majus.- I. Introduction.- II. Cis-Acting Mutations.- A. Stable cis-Acting Mutations.- B. Unstable cis-Acting Mutations.- III. Trans-Acting Mutations.- IV. Mutations Which Act Both in cis and trans.- V. Conclusions.- VI. References.- 5 Isolation of Differentially Expressed Genes from Tomato Flower.- I. Introduction.- II. Screening for Floral-Specific cDNAs.- III. Organ and Temporal Specificity of Floral Clones.- IV. Tissue Specificity of Floral Clones.- V. Discussion.- VI. References.- 6 Anther- and Pollen-Expressed Gene.- I. Introduction.- A. Anther and Microsporangium Development.- B. Summary of Meiosis, Pollen, and Pollen Tube Development.- II. Gene Expression in the Anther.- A. The Tapetum.- B. Other Anther Tissues.- III. Gene Expression in the Developing Male Gametophyte.- A. Specific Transcription and Translation.- B. Estimates of Numbers of Genes Expressed in Pollen.- C. Cloning of Pollen-Expressed Genes and the Pattern of Transcription of Specific mRNAs.- D. Overlap of Sporophytic and Gametophytic Gene Expression.- E. Sperm Cells.- IV. References.- 7 Self-Incompatibility Genes in Flowering Plant.- I. Introduction.- II. Homomorphic Incompatibility.- A. The General Features of Gametophytic Self-Incompatibility.- B. The General Features of Sporophytic Self-Incompatibility.- III. Heteromorphic Incompatibility.- IV. Nature of the Self-Incompatibility Reaction.- V. Nature of the S-Gene Products.- A. Gametophytic Systems.- 1. Nicotiana alata.- 2. Petunia hybrida.- 3. Lycopersicon peruvianum.- 4. Prunus avium.- 5. Lilium longiflorum.- 6. Trifolium pratense.- B. Sporophytic Systems.- 1. Brassica oleracea.- 2. Brassica campestris.- VI. Studies of the Molecular Basis of Self-Incompatibility.- VII. Concluding Comments.- VIII. References.- 8 Regulatory Circuits of Light-Responsive Gene.- I. Introduction.- II. Multiplicity of Light Effects.- A. Photomorphogenesis.- B. Effects on Gene Expression.- C. Rhythms.- III. Effectors of Photoreception.- A. Phytochrome.- B. Signal Transduction.- C. Cis-Acting DNA Sequences.- D. Trans-Acting Factors.- IV. Conclusions.- V. References.- 9 Regulation of Gene Expression by Ethylen.- I. Introduction.- A. Plant Hormones.- B. Ethylene and the Control of Tomato Fruit Ripening.- C. Induction of the Gene Expression by Exposure to Exogenous Ethylene.- D. A Model System for Studying Hormonal Regulation of Gene Expression During Plant Development.- II. Analysis of Ethylene-Inducible Gene Expression.- A. Isolation of cDNA Clones.- B. Induction of Gene Expression by Exogenous Ethylene in Unripe Tomato Fruit.- C. Activation of Gene Expression and Ethylene Production During Tomato Fruit Development.- D. Repression of Gene Expression by a Competitive Inhibitor of Ethylene Action.- III. Discussion.- IV. References.- 10 Root Nodule Symbiosis: Nodulins and Nodulin Gene.- I. Introduction.- II. An Overview of Legume Nodulation.- III. Induction of Plant Genes Coding for Nodulins.- A. Nodulin Structure and Function.- 1. Leghemoglobins.- 2. Nitrogen-Assimilatory Enzymes.- a) Glutamine Synthetase.- b) Uricase II.- c) Xanthine Dehydrogenase.- d) Purine Nucleosidase.- 3. Enzymes Involved in Carbon Metabolism.- a) Sucrose Synthas.- 4. Nodulins of Unknown Functions.- a) Nodulin-A Family.- b) Peribacteroid Membrane (pbm) Nodulins.- c) Early Nodulins.- d) “Nodulin-25” of Alfalfa.- B. Regulation of Nodulin Gene Expression.- 1. Induction of Early Nodulin Genes Does Not Require Intracellular Bacteria or Infection Threads.- 2. Expression of Late Nodulins Requires Infection Threads or Intracellular Bacteria.- 3. Some Nodulins May Require Nitrogen Fixation for Induction.- 4. Nodulin Gene Regulation at the Molecular Level: cis-Regulatory Sequences.- 5. Physiological Factors Involved in Induction of Nodulin Genes.- IV. Rapid Evolution of Legume-Rhizobium Symbiosis.- V. References.- 11 Structure and Expression of Plant Genes Encoding Pathogenesis-Related Protein.- I. Introduction.- A. Occurrence of PR Proteins.- B. Induction of PR Proteins.- C. PR Proteins and Acquired Resistance.- II. Characteristics of PR mRNAs and Genes.- A. cDNA Cloning of PR mRNAs.- B. Genes Corresponding to Groups A, B, C and G.- C. Genes Corresponding to Groups D, E and F.- III. General Conclusion.- A. Role of PR Proteins.- B. Prospects for Future Research.- IV. References.- 12 Proteinase Inhibitor Gene Families: Tissue Specificity and Regulatio.- I. Introduction.- II. Developmentally Regulated Proteinase Inhibitor Genes in Seeds, Tubers, and Fruit.- III. Wound-Inducible Proteinase Inhibitor Genes in Leaves.- IV. Summary.- V. References.- 13 Cell Wall Extensin Gene.- I. Cell Walls.- II. Extensin Networks.- A. Insoluble Extensins.- B. Soluble Extensins.- C. Extensin Crosslinking.- III. Extensin Genes.- A. Cloning Extensins.- B. Functional Domains.- C. Gene Regulation.- IV. Prospects.- V. References.- 14 The Expression of Heat Shock Genes — A Model for Environmental Stress Respons.- I. Introduction.- A. The Heat Shock Response.- B. Groups of Related Heat Shock Proteins.- C. Heat Shock and Other Environmental Stresses.- II. Molecular Biology of Heat Shock Genes.- A. Sequence Homology Among Small Heat Shock Proteins.- B. Heat Shock Promoter and Upstream Sequences.- C. Heterologous Expression of hs Genes in Transgenic Plants.- III. General Conclusions.- IV. References.- 15 Protein Transport in Plant Cell.- I. Introduction.- II. The Secretory Pathway.- III. Post-Translational Transport.- A. The Nucleus.- B. The Chloroplast.- 1. Import.- 2. Fusion Proteins.- 3. Mutants in Envelope Translocation.- 4. Mutants in Thylakoid Translocation.- 5. Processing.- C. The Mitochondrion.- D. Endosomes.- IV. Conclusions.- V. References.- 16 Genetic Engineering of Herbicide Resistance Gene.- I. Introduction.- II. Identification and Engineering of Herbicide Resistance Genes.- A. Glyphosate Resistance.- B. Phosphinothricin Resistance.- C. Sulfonylurea and Imidazolinone Resistance.- III. Conclusions.- IV. References.- 17 Virus Cross-Protection in Transgenic Plant.- I. Introduction.- A. Classical Cross-Protection: Applications and Limitations.- B. Proposed Mechanisms of Cross-Protection.- II. Genetic Transformation to Produce Virus Resistant Plants.- A. Expression of Viral Coat Protein Coding Sequences in Transgenic Plants.- B. Resistance to Virus Infection in Transgenic Plants.- C. Elucidating the Mechanism(s) of Engineered Protection.- D. Expression of Other Viral Sequences in Transgenic Plants.- III. Field Testing of Virus Protection in Transgenic Plants.- IV. Conclusions.- V. References.