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Rice is the most important cereal crop which feeds more than half the population of the world. It is being grown in more than 144. 641 million ha with a production of over 468. 275 million tons (in 1988). Rice is attacked by a large number of pests and diseases which cause an enormous loss in its yield. Therefore, the major objectives in rice breeding are the development of disease resistance, tolerance to insects, adverse soil water, and drought; and improvement of quality including increased protein content. Tremendous efforts being made at the International Rice Research Institute have…mehr
Rice is the most important cereal crop which feeds more than half the population of the world. It is being grown in more than 144. 641 million ha with a production of over 468. 275 million tons (in 1988). Rice is attacked by a large number of pests and diseases which cause an enormous loss in its yield. Therefore, the major objectives in rice breeding are the development of disease resistance, tolerance to insects, adverse soil water, and drought; and improvement of quality including increased protein content. Tremendous efforts being made at the International Rice Research Institute have resulted in the release of improved varieties. It is estimated that the world's annual rice production must increase from 460 million tons (in 1987) to 560 million tons by the year 2000, and to 760 million tons by 2020 (a 65% increase) in order to keep up with the population growth (IRRI Rice Facts 1988). To achieve this gigantic goal, new strategies have to be evolved. Since the success of any crop improvement program de pends on the extent of genetic variability in the base population, new techniques need to be developed not only to generate the much needed variability but also for its conservation. In this regard the progress made in the biotechnology of rice during the last 5 years has amply demonstrated the immense value of innovative approaches for further improvement of this crop.
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Inhaltsangabe
Section I Establishment of Tissue Cultures, Somatic Embryogenesis, Plant Regeneration, and Ultrastructural Studies.- I.1 Biotechnology in Rice Improvement.- I.2 Rice (Oryza sativa L.): Establishment of Callus Cultures and the Regeneration of Plants.- I.3 Regeneration of Rice Plants from Suspension Cultures.- I.4 Enhancement of Regeneration in Rice Tissue Cultures by Water and Salt Stress.- I.5 Early Events in Zygotic and Somatic Embryogenesis in Rice.- I.6 Endosperm Culture and the Regeneration of Triploid Rice Plants.- I.7 Ultrastructural Aspects of Rice Scutellum as Related to Seminal Root Cultures.- Section II Hybridization, Embryo Culture, Hybrid Rice.- II.1 Embryo Culture for Wide Hybridization in Rice.- II.2 Improvement of Tongil-Type Rice Cultivars from Indica/Japonica Hybridization in Korea.- II.3 Genetics of Hybrid Sterility in Wide Hybridization in Rice (Oryza sativa L.).- II.4 Hybrid Rice in China - Techniques and Production.- Section III Anther Culture, Haploid Production, and Release of Cultivars.- III.1 Anther Culture for Rice Improvement in China.- III.2 In Vitro Production of Haploids in Rice Through Ovary Culture.- III.3 Factors Affecting Androgenesis in Rice (Oryza sativa L.).- III.4 Breeding New Rice Strains Through Anther Culture.- III.5 Huayu 15, a High-Yielding Rice Variety Bred by Anther Culture.- Section IV Protoplast Isolation, Fusion, Culture, and Field Trials of Regenerated Plants.- IV.1 Isolation, Culture and Fusion of Rice Protoplasts.- IV.2 Field Performance of Protoplast-Derived Rice Plants and the Release of a New Variety.- Section V In Vitro Mutation and Somaclonal Variation.- V.1 In Vitro Mutation in Rice.- V.2 Rice Mutants Resistant to Amino Acids and Amino Acid Analogs.- V.3 Hydroxy-L-Proline-Resistant Mutants in Rice.- V.4Utilization of Somaclonal Variation in Rice Breeding.- V.5 Male Sterile Mutants from Rice Somaclones.- V.6 Somaclonal Variation for Salt Tolerance in Rice.- V.7 Somaclonal Selection for Tolerance to Streptomycin and Herbicides Through Rice Cell Culture.- V.8 Rice Somaclones Resistant to Xanthomonas Oryzae.- Section VI Transformation, Molecular Biology, and Nutritional Improvement.- VI.1 Transformation in Rice.- VI.2 Molecular Analysis of Rice Genes and Methods for Gene Transfer.- VI.3 Plasticity of the Rice Genome: DNA Amplification in Cultured Cells.- VI.4 Molecular Structure of Chloroplast DNA from Rice.- VI.5 Molecular Markers in Rice Systematics and the Evaluation of Genetic Resources.- VI.6 Rice Storage Proteins: Genetic Analysis of Accumulation Process.- VI.7 Biotechnology in Nutritional Improvement of Rice.- Section VII Conservation of Genetic Resources and Cryopreservation.- VII.1 Conservation and Potentials of Rice Genetic Resources.- VII.2 Cryopreservation of Germplasm of Rice.- Section VIII Rice Tissue Culture Studies in the USSR, France, and Hungary.- VIII.1 Rice Improvement Through Tissue Culture in the USSR.- VIII.2 Rice Somatic Tissue and Anther Cultures: Current Status in France.- VIII.3 In Vitro Studies on Rice in Hungary.
Section I Establishment of Tissue Cultures, Somatic Embryogenesis, Plant Regeneration, and Ultrastructural Studies.- I.1 Biotechnology in Rice Improvement.- I.2 Rice (Oryza sativa L.): Establishment of Callus Cultures and the Regeneration of Plants.- I.3 Regeneration of Rice Plants from Suspension Cultures.- I.4 Enhancement of Regeneration in Rice Tissue Cultures by Water and Salt Stress.- I.5 Early Events in Zygotic and Somatic Embryogenesis in Rice.- I.6 Endosperm Culture and the Regeneration of Triploid Rice Plants.- I.7 Ultrastructural Aspects of Rice Scutellum as Related to Seminal Root Cultures.- Section II Hybridization, Embryo Culture, Hybrid Rice.- II.1 Embryo Culture for Wide Hybridization in Rice.- II.2 Improvement of Tongil-Type Rice Cultivars from Indica/Japonica Hybridization in Korea.- II.3 Genetics of Hybrid Sterility in Wide Hybridization in Rice (Oryza sativa L.).- II.4 Hybrid Rice in China - Techniques and Production.- Section III Anther Culture, Haploid Production, and Release of Cultivars.- III.1 Anther Culture for Rice Improvement in China.- III.2 In Vitro Production of Haploids in Rice Through Ovary Culture.- III.3 Factors Affecting Androgenesis in Rice (Oryza sativa L.).- III.4 Breeding New Rice Strains Through Anther Culture.- III.5 Huayu 15, a High-Yielding Rice Variety Bred by Anther Culture.- Section IV Protoplast Isolation, Fusion, Culture, and Field Trials of Regenerated Plants.- IV.1 Isolation, Culture and Fusion of Rice Protoplasts.- IV.2 Field Performance of Protoplast-Derived Rice Plants and the Release of a New Variety.- Section V In Vitro Mutation and Somaclonal Variation.- V.1 In Vitro Mutation in Rice.- V.2 Rice Mutants Resistant to Amino Acids and Amino Acid Analogs.- V.3 Hydroxy-L-Proline-Resistant Mutants in Rice.- V.4Utilization of Somaclonal Variation in Rice Breeding.- V.5 Male Sterile Mutants from Rice Somaclones.- V.6 Somaclonal Variation for Salt Tolerance in Rice.- V.7 Somaclonal Selection for Tolerance to Streptomycin and Herbicides Through Rice Cell Culture.- V.8 Rice Somaclones Resistant to Xanthomonas Oryzae.- Section VI Transformation, Molecular Biology, and Nutritional Improvement.- VI.1 Transformation in Rice.- VI.2 Molecular Analysis of Rice Genes and Methods for Gene Transfer.- VI.3 Plasticity of the Rice Genome: DNA Amplification in Cultured Cells.- VI.4 Molecular Structure of Chloroplast DNA from Rice.- VI.5 Molecular Markers in Rice Systematics and the Evaluation of Genetic Resources.- VI.6 Rice Storage Proteins: Genetic Analysis of Accumulation Process.- VI.7 Biotechnology in Nutritional Improvement of Rice.- Section VII Conservation of Genetic Resources and Cryopreservation.- VII.1 Conservation and Potentials of Rice Genetic Resources.- VII.2 Cryopreservation of Germplasm of Rice.- Section VIII Rice Tissue Culture Studies in the USSR, France, and Hungary.- VIII.1 Rice Improvement Through Tissue Culture in the USSR.- VIII.2 Rice Somatic Tissue and Anther Cultures: Current Status in France.- VIII.3 In Vitro Studies on Rice in Hungary.
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