Maize

Forty chapters deal with various aspects of tissue culture, in vitro manipulation, and other biotechnological approaches to the improvement of maize. They are arranged in eight sections: - In Vitro Technology, Callus Cultures and Regeneration of Plants, Somatic Embryogenesis. - Wide Hybridization, Embryo, Ovule, and Inflorescence Culture, in Vitro Fertilization. - Production of Haploids and Double Haploids, Anther and Pollen Culture. - Protoplast Culture, Genetic Transformation. - Somaclonal Variation and Mutations. - Molecular Biology and Physiological Studies. - Proteins and Nutritional Improvement. Pollen Storage, Cryopreservation of Germplasm.

I.1 Biotechnology in Maize Improvement.- I.2 Establishment of Callus Cultures and Regeneration of Maize Plants.- I.3 Maize Propagation and Breeding Through the Culture of Reproductive Organs.- I.4 Ultrastructural Studies on Callus Development and Somati Embryogenesis in Zea mays L..- II. 1 Maize x Tripsacum Hybridization and the Potential for Apomixis Transfer for Maize Improvement.- II.2 Maize x Teosinte Hybridization.- II.3 Wheat x Maize Crosses for the Production of Wheat Haploids.- II.4Interaction of Callus of Pure Lines and Hybrids of Maize in Co-Culture.- II.5 In Vitro Culture of Maize Inflorescences.- II.6 In Vitro Fertilization in Maize.- III. 1 Anther Culture and Haploid Breeding of Maize in China.- III.2 Embryogenesis in Haploid Cell Culture of Maize.- III.3 Isolated Microspore Culture of Maize.- III.4 Advantages and Disadvantages of the Use of in Vitro/ in Situ Produced DH Maize Plants.- IV. 1 Transformation of Maize Protoplasts.- IV.2 Transformation of Maize Through Particle Bombardment.- IV.3 Transformation in Maize Using Low Voltage electric Current.- V.1 Somaclonal variation in the Progeny of CHI-31 Maize Inbred Line derived from Tissue Culture.- V.2 Insecticide-Resistant Maize Plants Regenerated in Vitro.- V.3 In Vitro Selection for Herbicide Tolerance in Maize.- V.4 In Vitro Selection for Salt Tolerance in Maize.- V.5 Approaches for the Development of Cold Tolerance in Maize Through Regenerable Callus Cultures.- V.6 Cold Tolerance in in Vitro-Grown Seedlings, Callus Tissue, and Somaclones of Maize.- V.7 Genetic variability Induced Through Mutations in Maize.- V.8 C-Banding in Zea mays.- VI. 1 Transposon Tagging Technologies in Maize.- VI.2 Molecular Aspects of Cytoplasmic Male Sterility in Maize.- VI.3 Mitochondrial Genome Organization in cmsT-Regenerated Maize Plants.- VI.4 Maize Chloroplast Gene Transfer to Nucleus.- VI.5 Alcohol Dehydrogenases in Maize Cell Cultures.- VI.6 Isozymes as Markers for Embryogenic Maize Callus.- VI.7 Chilling Sensitivity of Photosynthesis in Maize.- VII. 1 Biotechnology in Nutritional Improvement of Maize.- VII.2 Corn Germ Protein: Functional Properties in a Model System and in Food Products.- VII.3 Albumins and Globulins in Maize Grains.- VII.4 Proteins and Amino Acids in Maize Kernels.- VII.5 Synthetic Peptides and Antipeptide Antibodies in Studying Zein Structure and Fingerprinting Maize Genotypes.- VII.6 Alterations in the Biosynthesis of Lysine, Threonine, and Methionine by Tissue Culture Approaches in Maize.- VIII. 1 Preservation of Maize Pollen.- VIII.2 Cryopreservation of Germplasm of Maize.