High-tech and micropropagation

Presented here is another classic from this series and deals with general aspects of micropropagation of plants for commercial exploitation. It includes chapters on setting up a commercial laboratory, meristem culture, somatic embryogenesis, factors affecting micropropagation, disposable vessels, vitrification, acclimatization, induction of rooting, artificial substrates, cryopreservation and artificial seed. Special emphasis is given on modern approaches and developing technologies such as automation and bioreactors, robots in transplanting, artificial intelligence, information management and computerized greenhouses for en masse commercial production of plants.

Section I General Aspects, Factors Affecting Micropropagation, Meristem Culture, Somatic Embryogenesis, Grafting, Vitrification, Acclimatization, Disposable Culture Vessels.- I.1 Automated Micropropagation for en masse Production of Plants.- 1 General Account.- 2 Problems and Factors Affecting Micropropagation.- 3 Automation - Robots, Microcomputers, and Artificial Intelligence.- 4 Summary and Conclusions.- References.- I.2 Setting Up a Commercial Micropropagation Laboratory (With 8 Figures).- 1 Introduction.- 2 The Planning Phase.- 3 Decision on Laboratory Specification.- 4 The Micropropagation and Ancillary Facilities.- 5 Research and Development and Quality Assurance.- 6 Trends in the Micropropagation Industry.- 7 Conclusions.- References.- I.3 Micropropagation Through Meristem Culture (With 1 Figures).- 1 Introduction.- 2 Shoot Meristem Culture.- 3 Factors Influencing Disease-Elimination.- 4 In Vitro Clonal Propagation of Disease Eliminated Plants.- 5 Long-Term Storage.- 6 Implications in Commercial Propagation.- References.- I.4 Micropropagation Through Somatic Embryogenesis in Conifers (With 7 Figures).- 1 General Account.- 2 Plant Regeneration.- 3 Conclusions.- References.- I.5 Graft Compatibilities in Vitro (With 9 Figures).- 1 Introduction.- 2 In Vitro Studies of Graft Compatibility-Incompatibility.- 3 Models for Graft Compatibility-Incompatibility.- 4 Future Prospects.- References.- I.6 In Vitro Induction of Flowering and Its Relevance to Micropropagation (With 2 Figures).- 1 Introduction.- 2 The Existence of Florigen? Evidence Provided by in Vitro Studies.- 3 Studies Concerned with Flower Inhibitors.- 4 Flowering as a Multi-Component System: Evidence Provided by in Vitro Studies.- 5 Hormones and in Vitro Flowering.- 6 Nonhormonal Substances and in Vitro Flowering.- 7 Conclusions.- References.- I.7 Vitrification in Micropropagation.- 1 Definition.- 2 Morphological, Anatomical, Mechanical and Biochemical Characteristics.- 3 External and Internal Factors Inducing Vitrification.- 4 Remedies.- 5 Disadvantages.- 6 Beneficial Management.- 7 Conclusions and Prospects.- References.- I.8 Acclimatization of Micropropagated Plants (With 7 Figures).- 1 Introduction.- 2 Features of Tissue Culture Environment.- 3 Heterotrophy, Mixotrophy, and Autotrophy.- 4 Increasing Percentage Survival and Growth Rate.- 5 Computer-Controlled Acclimatization Unit.- 6 Concluding Remarks.- References.- I.9 The Effect of the Nature and Origin of Explants on Micropropagation (With 9 Figures).- 1 Introduction.- 2 What Is Meant by the Nature and Origin of Explants?.- 3 Examples of Explant Reaction.- 4 Summary.- References.- I.10 Problems with Explant Exudation in Micropropagation (With 1 Figure).- 1 General Account.- 2 Phenolic Compounds.- 3 Oxidation of Phenolics.- 4 Conclusions.- References.- I.11 Woody Plant Micropropagation with Cytokinins (With 4 Figures).- 1 Introduction.- 2 Comparative Physiology.- 3 Cytokinin Biology.- 4 Discussion.- References.- I.12 The Effect of the Culture Vessel on Micropropagation (With 4 Figures).- 1 Introduction.- 2 Moisture Conductance.- 3 Discussion.- 4 Summary and Conclusion.- References.- I.13 Disposable Film Culture Vessels (With 17 Figures).- 1 Introduction.- 2 Properties of Fluorocarbon Polymer Films.- 3 Box-Shaped Vessel, the "Culture Pack".- 4 Envelope-Shaped Vessel, the "Culture Bag".- 5 Conclusions.- References.- Section II Rooting, Artificial Substrates, Autotrophic Micropropagation, Nursery Planting.- II.1 Rooting of in Vitro Cuttings (With 4 Figures).- 1 Introduction.- 2 Stages of Root Ontogenesis.- 3 Rooting Correlations: Influence of Lateral Organs.- 4 Influence of Juvenility.- 5 Basal Medium and Carbohydrate Nutrition.- 6 Environmental Influences.- 7 Relations Between Rhizogenesis, Auxins, Peroxidases, Phenols, and Ethylene.- 8 Relations Between Ontogenetic States and Rooting Markers.- 9 Conclusion.- References.- II.2 Rooting of in Vitro-Produced Shoots in Nonsterile - an Inexpensive and Efficient Technique for en masse Micropropagation (With 2 Figures).- 1 Introduction.- 2 Method and Observations.- 3 Protocol for Sand Rooting.- 4 Summary and Conclusions.- References.- II.3 Use of Artificial Substrates for in Vitro Propagation (With 6 Figures).- 1 Introduction.- 2 Rhizogenesis and Acclimatization.- 3 Use of Artificial Substrates for in Vitro Micrografting.- 4 Use of Artificial Substrates in a Mixed Culture: Plant and Microorganisms.- 5 Qualities Needed in an Ideal Artificial Substrate.- 6 Summary and Conclusion.- References.- II.4 Rockwool as a Substrate for Greenhouse Crops (With 21 Figures).- 1 Introduction.- 2 Rockwool.- 3 Growing Systems.- 4 Root Zone Temperature.- 5 Water Quality.- 6 Water Supply.- 7 Other Rockwool Systems.- 8 pH.- 9 Electrical Conductivity.- 10 Nutrients.- 11 Handling of Plant Nutrition.- 12 Conclusions.- References.- II.5 Autotrophic Micropropagation (With 20 Figures).- 1 Introduction.- 2 Micropropagation Process and Reasons for High Production Cost in the Conventional Micropropagation Method.- 3 Carbon Sources for Hetero- and Autotrophic Growth.- 4 Fundamental Photosynthetic Characteristics of C3 plants.- 5 Number of Gas Changes of the Vessel per Hour.- 6 Diurnal Changes in CO2 Concentration Inside the Tissue Culture Vessel.- 7 Interpretation of the Results of Low CO2 Concentration in the Culture Vessel During the Photoperiod.- 8 Growth of Plantlets in Vitro Under Different Sugar Concentration, CO2 Concentration, and PPF Conditions.- 9 Other Physical Environmental Factors Affecting the Autoor Mixotrophic Growth of Plantlets in Vitro.- 10 Use of a Gas-Permeable, Clear Plastic Film as a Vessel Closure.- 11 An Autotrophic Micropropagation System.- 12 A Novel Approach to Auto- or Mixotrophic Micropropagation.- 13 Increase of Production Costs for Lighting, Cooling, and CO2 Enrichment.- 14 Concluding Remarks.- References.- II.6 In Vitro Nursery System for Vegetable Crops - Tomato and Melon (With 9 Figures).- 1 Introduction.- 2 Breeding Programs and Their Results.- 3 Tissue Culture Propagation of Selected Plants.- 4 Culture of in Vitro-Propagated Plants.- 5 Conclusions.- References.- Section III Storage/Cryopreservation of Cultures, Quiescent Somatic Embryos, Artificial Seed.- III.1 Storage and Cryopreservation of in Vitro Cultures (With 7 Figures).- 1 General Account.- 2 Nonfrozen Storage.- 3 Cryopreservation (196 C) of Cultures.- 4 Conclusions.- References.- III.2 Quiescence and Dormancy in Somatic Embryos (With 3 Figures).- 1 Introduction.- 2 Background and Terminology.- 3 Quiescence.- 4 Dormancy.- 5 Conclusions.- References.- III.3 Artificial Seeds - Encapsulated Somatic Embryos (With 9 Figures).- 1 Introduction.- 2 Artificial Seed Concepts.- 3 Artificial Seed Coating.- 4 Somatic Embryogeny.- 5 Conclusions.- References.- Section IV Automation, Artificial Intelligence, Robots in Transplanting, Information Management, Bioreactors, Computerized Greenhouses.- IV. 1 Automated Systems.- 1 Introduction.- 2 Automated Systems in Plant Tissue Culture.- 3 Automated Plant Culture System Features.- 4 Remarks on the APCS.- 5 Future of the APCS.- References.- IV.2 Artificial Intelligence Technology to Control Plant Environments (With 15 Figures).- 1 Introduction.- 2 The Concept of Control Logic.- 3 Outline of Control Logic.- 4 Rule Base and Performance of the Inference Engine.- 5 Measuring Systems for Controlling Plant Environment.- 6 Experiments of Controlling Plant Environment by Means of the A1 Technique.- 7 Conclusions.- References.- IV.3 Robots in Transplanting (With 15 Figures).- 1 Introduction.- 2 Simulation of the Transplanting Task.- 3 Simulation Results.- 4 Transplanting Validation Tests.- 5 Machine Vision and Image Processing.- 6 Summary and Conclusion.- References.- IV.4 Computing and Information Management in Micropropagation (With 5 Figures).- 1 Introduction.- 2 Basic Concepts.- 3 The Micropropagation Firm as a System.- 4 The Planning Phase.- 5 Production Monitoring and Control.- 6 Planning-Production Feedback Mechanism.- 7 Technical Aspects of Computing and Information Management.- 8 The Micropropagation Firm as a Whole - Prospects of Information Management.- 9 Summary.- References.- IV.5 Mass Propagation of Plants Through Shakeand Bioreactor-Culture Techniques (With 19 Figures).- 1 Introduction.- 2 Advantages and Disadvantages of the Present in Vitro Propagation Techniques.- 3 Present State of Development of Mass Propagation Techniques.- 4 Schematic Outline of Mass Propagation of Plants Using Shake- and Bioreactor-Culture Techniques.- 5 Characteristics of Cultures in the Bioreactor.- 6 Scale-Up Technique.- 7 Shake- and Bioreactor-Culture Techniques Applied to Various Plants.- 8 Concluding Remarks.- References.- IV.6 Climate Control of Greenhouses and Crop Growth (With 8 Figures).- 1 Introduction.- 2 A Greenhouse as a Production Facility.- 3 Greenhouse Climate Control.- 4 Summary and Conclusions.- References.- IV.7 Computer-Controlled Greenhouses in Japan (With 4 Figures).- 1 Introduction.- 2 Examples of Using a Microcomputer for Greenhouse Control.- 3 Examples of Using a General-Purpose Microcomputer.- 4 Conclusion.- References.

Second in the series, High-Tech and Micropropagation, this work covers the micropropagation of trees and fruit-bearing plants, such as poplar, birches, larch, American sweetgum, black locust, Sorbus, sandalwood, Quercus, cedar, Persian walnut, date palm, cocoa, Citrus, olive, apple, pear, peach, plum, cherry, papaya, pineapple, kiwi, Japanese persimmon, grapevine, strawberry, and raspberry. The importance and distribution of conventional propagation and in vitro studies on individual species are discussed. In particular detail, the transfer of in vitro plants to the greenhouse or the field, and the prospects of commercial exploitation are examined. The book will be of use to advanced students, research workers and teachers in horticulture, forestry and plant biotechnology in general, and also to individuals interested in industrial micropropagation.

Section I Trees.- I.1 Micropropagation of American Sweetgum (Liquidambar styraciflua L.).- 1 Introduction.- 2 Micropropagation.- 3 Conclusions and Prospects.- References.- I.2 Micropropagation of Black Locust (Robinia pseudoacacia L.).- 1 General Information.- 2 Review of Plantlet Regeneration in Robinia pseudoacacia.- 3 Micropropagation: General Considerations.- 4 Summary and Conclusions.- 5 Experimental Protocol: Cotyledonary Node Culture.- I.3 Micropropagation of Birches (Betula spp.).- 1 Introduction.- 2 In Vitro Culture Studies on Betula.- 3 In Vitro Techniques.- 4 Conclusions.- 5 Protocol.- References.- I.4 Micropropagation of Cedar (Thuja spp.).- 1 Introduction.- 2 In Vitro Approaches for Propagation.- 3 Conclusions.- 4 Protocol.- References.- I.5 Micropropagation of Cocoa (Theobroma cacao L.).- 1 Introduction.- 2 In Vitro Culture and Micropropagation.- 3 Conclusions and Prospects.- References.- I.6 Micropropagation of Larches (Larix spp.).- 1 Introduction.- 2 In Vitro Approaches.- 3 Special In Vitro Application.- 4 Conclusions and Prospects.- 5 Protocol.- References.- I.7 Micropropagation of Persian Walnut (Juglans regia L.).- 1 Introduction.- 2 Need for Micropropagation.- 3 Review of in Vitro Studies on J. regia.- 4 Micropropagation Techniques.- 5 Conclusion.- 6 Protocol.- References.- I.8 Micropropagation of Poplars (Populus spp.).- 1 Introduction.- 2 In Vitro Approaches.- 3 Conclusions and Prospects.- References.- I.9 Clonal Propagation of Oak (Quercus acutissima Carruth.).- 1 Introduction.- 2 Micropropagation.- 3 Conclusion.- 4 Protocol.- References.- I.10 Micropropagation of Sandalwood (Santalum album L.).- 1 Introduction.- 2 Micropropagation.- 3 Plants from Endosperm.- 4 Plants from Cell Suspensions.- 5 Plants from Protoplasts: Protocol.- 6 Plants from Synthetic Seeds.- 7 Transfer to Field.- 8 Commercial Aspects and Prospects.- 9 Protocol.- References.- I.11 Micropropagation of European Mountain Ash (Sorbus aucuparia L.) and Wild Service Tree [Sorbus torminalis (L.) Cr.].- 1 Introduction.- 2 In Vitro Approaches.- 3 Summary and Conclusions.- References.- Section II Fruits.- II.1 Micropropagation of Apple (Malus domestica Burkh.).- 1 General Account.- 2 Need for in Vitro Culture of Apple.- 3 Previous Research.- 4 Micropropagation Technique.- 5 Shoot Multiplication.- 6 Rooting.- 7 Acclimatization and Transfer to Greenhouse.- References.- II.2 Micropropagation of Pear (Pyrus communis L.).- 1 Introduction.- 2 In Vitro Culture Studies on Pear.- 3 Conclusions.- 4 Protocol.- References.- II.3 Micropropagation of Peach [Prunus persica (L.) Batsch].- 1 Introduction.- 2 In Vitro Culture of Peach.- 3 Micropropagation of Peach.- 4 Summary and Future Prospects.- 5 Protocol.- References.- II.4 In Vitro Culture and Micropropagation of Plum (Prunus spp.).- 1 General Account.- 2 Review of Tissue Culture Work on Plum.- 3 Examples of Application in the Preparation for Industrial Processing of Plum Species.- 4 Summary and Conclusions.- 5 Protocol.- References.- II.5 Micropropagation of Cherry (Prunus spp.).- 1 General Account.- 2 Review of Organ and Tissue Culture in Cherry.- 3 Micropropagation.- 4 Summary and Conclusion.- 5 Protocol.- References.- II.6 Citrus Shoot-Tip Grafting in Vitro.- 1 Introduction.- 2 The Technique of Shoot Tip Grafting in Vitro.- 3 Applications of Shoot Tip Grafting in Vitro.- 4 Conclusion.- References.- II.7 Micropropagation of Raspberry (Rubus idaeus L.).- 1 General Account.- 2 Review of Tissue Culture Work on Raspberry.- 3 Micropropagation.- 4 Summary and Conclusions.- 5 Protocol.- References.- II.8 Micropropagation of Strawberry (Fragaria spp.).- 1 Introduction.- 2 Micropropagation.- 3 Conclusions and Perspectives.- References.- II.9 Micropropagation of Grapevine (Vitis vinifera).- 1 Introduction.- 2 In Vitro Approaches.- 3 Conclusions and Prospects.- References.- II.10 Micropropagation of Kiwi (Actinidia spp.).- 1 Introduction.- 2 In Vitro Approaches.- References.- II.11 Micropropagation of Japanese Persimmon (Diospyros kaki L.).- 1 Introduction.- 2 Summary of Tissue Culture Work.- 3 Shoot Tip Culture.- 4 Summary and Conclusions.- 5 Protocol.- References.- II.12 Micropropagation of Papaya (Carica spp.).- 1 General Account.- 2 Brief Review of Tissue Culture Work on Papaya.- 3 Micropropagation.- 4 Summary and Conclusions.- 5 Protocol.- References.- II.13 Micropropagation of Pineapple (Ananas comosus L.).- 1 Introduction.- 2 Micropropagation of Pineapple.- 3 Critical Factors in the Micropropagation Process.- 4 Summary and Conclusions.- 5 Protocol.- References.- II.14 Micropropagation of Date Palm (Phoenix dactylifera L.).- 1 General Account.- 2 Review of Work on Date Palm.- 3 Micropropagation.- 4 Summary and Conclusions.- 5 Protocol.- References.- II.15 Micropropagation of Olive (Olea europaea L.).- 1 Introduction.- 2 Micropropagation.- 3 Summary and Conclusions.- 4 Protocol.- References.

Presenting the state of the art of tissue culture and in vitro propagation of vegetable and tuber crops, medicinal and aromatic plants, fibre and oilseed crops, and grasses, this book complements the previous two volumes on High-Tech and Micropropagation, which concentrated on special techniques (Vol.17) and trees and bushes of commercial value (Vol.18). The specific plants covered here include asparagus, lettuce, horse radish, cucumber, potato, cassava, sweet potato, artichoke, yams, cardamom, fennel, celery, thyme, leek, mentha, turmeric, lavender, agave, yucca, cotton, jute, sunflower, ryegrass, zoysiagrass, and various species of Aconitum, Artemisia, Camelia, Centaurium, Digitalis, Dioscorea, Glehnia, Levisticum, Parthenium, and Pinella. The book is of use to advanced students, teachers and research workers in the field of pharmacy, horticulture, plant breeding and plant biotechnology in general, and also to individuals interested in industrial micropropagation.

Section I Vegetables, Tubers, and Root Crops.- I.1 Micropropagation of Hybrid Lines in Vegetable Breeding.- I.2 Micropropagation of Asparagus (Asparagus officinalis L.).- I.3 Micropropagation of Lettuce (Lactuca sativa L.).- I.4 Micropropagation of Horseradish (Cochlearia armoracia L.).- I.5 Micropropagation of Cucumis spp..- I.6 Micropropagation of Potato (Solanum tuberosum L.).- I.7 Micropropagation of Sweet Potato (Ipomoea batatas L.).- I.8 Micropropagation of Artichoke (Cynara scolymus).- I.9 Micropropagation of White Yam (Dioscorea rotundata Poir.).- I.10 Micropropagation of Cubio (Tropaeolum tuberosum R & P).- Section II Medicinal and Aromatic Plants.- II.1 Micropropagation of Cardamom (Elettaria cardamomum Maton).- II.2 Micropropagation of Fennel (Foeniculum vulgare Miller).- II.3 Micropropagation of Celery (Apium graveolens var. dulce).- II.4 Micropropagation of Thyme (Thymus vulgaris L.).- II.5 Micropropagation of Japanese Bunching Onion (Allium fistulosum L.) and Its Hybrid (A. fistulosum x A. cepa) Derivatives.- II.6 Micropropagation of Mentha L..- II.7 Micropropagation of Turmeric (Curcuma domestica Valet) and Other Curcuma Species.- II.8 Micropropagation of Lavandin (Lavandula officinalis Chaix x Lavandula latifolia Villars cv. Grosso).- II.9 Micropropagation of Agave spp..- II.10 Micropropagation of Yucca (Yuccaglauca Nutt.).- II.11 Micropropagation of Monkshood (Aconitum spp.).- II.12 Micropropagation of French Tarragon (Artemisia dracunculus L. var. sativa).- IL13 Micropropagation of Camellia spp..- II.14 Micropropagation of Common Centaury (Centaurium erythraea Rafn.).- II.15 Micropropagation of Woolly Foxglove (Digitalis lanata) by Shoot Tip Culture.- II.16 Micropropagation of Medicinal Dioscorea Species.- II.17 Micropropagation of Glehnia (Glehnia littoralis Fr. Schmidt ex Miq.).- II.18 Micropropagation of Guayule (Parthenium argentatum).- II.19 Micropropagation of Pinellia ternata.- Section III Fibre and Oilseed Crops, and Grasses.- III.1 Micropropagation of Cotton (Gossypium species).- III2 Tissue Culture and Micropropagation of Jute (Corchorus spp.).

In continuation from the previous three volumes 17, 18, and 19 on High-Tech and Micropropagation this volume presents 29 chapters on the propagation of ornamental plants through modern biotechnological methods. The species covered include Alstromeria, Antirrhinum, Begonia, Chrysanthemum, Cornus, Euphorbia, Gardenia, Gladiolus, Hyacinthus, Impatiens, Iris, Lycoris, Nematanthus, Paeonia, Pelargonium, Phalaenopsis, Rhododendron, Ruscus, Saintpaulia, Senecio, Syringa, orchids, cacti, roses, and Boston ferns. In addition, one chapter is devoted to micropropagation of virus-free ornamentals in the CIS. Throughout the book, detailed protocols as well as a comprehensive review of the literature are provided. Advanced students, teachers, and researchers in the fields of floriculture, horticulture, and plant biotechnology in general, and also those interested in industrial or commercial micropropagation will find a wealth of useful information in the book.

Micropropagation of plants is a multibillion dollar industry being prac- ticed in hundreds of small and large nurseries and commercial labora- tories throughout the world. At present, it is the only component of plant biotechnology which has been commercially exploited on such a large scale, especially for the production of ornamentals. Now micro- propagation of trees and medicinal plants has also assumed great im- portance. With recent progress made in the propagation of fruit and forest trees, and the immediate need for afforestation and planting of orchards, propagules and plantlets are required quickly and in large numbers. Taking these points into consideration High-Tech and Micro- propagation I, If, If I, and IV were published in 1991 and 1992. The present two volumes, High-Tech and Micropropagation V and VI, com- prise 51 chapters contributed by international experts from 24 countries. High-Tech and M icropropagation V comprises 24 chapters arranged into the following three sections: I. Vegetables and fruits (garlic, Amaranthus, Brassica oleracea, pepper watermelon, cassava, banana, Myrtus communis, passionfruit, Poly- mnia sonchifolia, pepino, and spinach) II. Grasses (bamboos, Caustis dioica, Dendrocalamus, Miscanthus x giganteus, sugarcane) III. Trees (Aegle marmelos, Eucalyptus, Fraxinus excelsior, Juglans cinerea, Pinus virginiana, Prosopis, and Ulmus species) High-Tech and Micropropagation VI comprises 27 chapters arranged in two sections: I.

I.1 Micropropagation of Allium sativum L. (Garlic).- I.2 Micropropagation of Amaranthus (Amaranth).- I.3 Micropropagation of Brassica oleracea (Cole Crops).- I.4 Micropropagation of Capsicum Species (Pepper).- I.5 Micropropagation of Citrullus lanatus (Thunb.) Matsum. and Nakai (Watermelon).- I.6 Micropropagation of Manihot esculenta Crantz (Cassava).- I.7 Micropropagation of Musa Species (Bananas).- I.8 Micropropagation of Myrtus cominunis L. (Mediterranean myrtle).- I.9 Micropropagation of Passiflora Species (Passionfruit).- I.10 Micropropagation of Polymnia sonchifolia (Yacon).- I.11 Micropropagation of Solanum muricatum Ait. (Pepino).- I.12 Micropropagation of Spinacia oleracea L. (Spinach).- II.1 Micropropagation of Bamboos.- II.2 Micropropagation of Caustis dioica (Chinese Puzzle).- II.3 Micropropagation of Dendrocalamus Species (Bamboo).- II.4 Micropropagation of Miscanthus x giganteus.- II.5 Micropropagation of Sugarcane (Saccharum spp. Hybrid).- III.1 Micropropagation of Aegle marmelos Corr. (Bael).- III.2 Micropropagation of Eucalyptus.- III.3 Micropropagation of Fraxinus excelsior L. (Common Ash).- III.4 Micropropagation of Juglans cinerea L. (Butternut).- III.5 Micropropagation of Pinus virginiana (Virginia Pine).- III.6 Micropropagation of Prosopis Species (Mesquites).- III.7 Micropropagation of Ulmus Species (Elms).

Micropropagation of plants is a multi billion dollar industry being practiced in hundreds of sm all and large nurseries and commerciallabo- ratories throughout the world. At present, it is the only component of plant biotechnology which has been commercially exploited on such a large scale, especially for the production of ornamentals. Now micropropagation of trees and medicinal plants has also assumed great importance. With recent progress made in the propagation of fruit and forest trees, and the immediate need for afforestation and planting of orchards, propagules and plantlets are required quickly and in large numbers. Taking these points into consideration High-Tech and Micropropagation I, II, III, and IV were published in 1991 and 1992. The present two volumes, High-Tech and Micropropagation V and VI, comprise 51 chapters contributed by international experts from 24 countries. High-Tech and Micropropagation V comprises 24 chapters arranged into the following three seetions: 1. Vegetables and fruits (garlic, Amaranthus, Brassica oleracea, pep- per, watermelon, cassava, banana, Myrtus communis, passionfruit, Polymnia sonchifolia, pepino, and spinaeh) H. Grasses (bamboos, Caustis dioica, Dendrocalamus, Miscanthus x giganteus, sugarcane) In. Trees (Aegle marmelos, Eucalyptus, Fraxinus excelsior, luglans cinerea, Pinus virginiana, Prosopis, and Vlmus species) High-Tech and Micropropagation VI comprises 27 chapters arranged in two sections: 1. Ornamental and aromatic plants (Amaryllis, Anthurium, Blandfordia, bromeliads, Campanula, Coleus, Ctenanthe, Cyclamen, Daphne, Dracaena, Gerbera, Helianthemum, Hippeastrum, Leucojum, Mammillaria, Maranta, Mediocactus, Mussaenda, Narcissus, Otacanthus, ponytail palm, Prunus tenella, Spiranthes, and Zinnia) II.

Section I Ornamental, and Aromatic Plants.- I.1 Micropropagation of Amaryllis (Hippeastrum hybridum).- I.2 Micropropagation of Anthurium.- I.3 Micropropagation of Blandfordia Species (Christmas Bells).- I.4 Micropropagation of Ornamental Bromeliads (Bromeliaceae).- I.5 Micropropagation of Campanula.- I.6 Micropropagation of Coleus forskohlii (Willd.) Briq..- I.7 Micropropagation of Ctenanthe lubbersiana Eichl. and Maranta leuconeura Morren var. Tricolor (Marantaceae).- I.8 Micropropagation of Cyclamen persicum Mill..- I.9 Micropropagation of Daphne L..- I.10 Micropropagation of Dracaena Species.- I.11 Micropropagation of Gerbera.- I.12 Micropropagation of Helianthemum almeriense.- I.13 Micropropagation of Leucojum aestivum L. (Summer Snowflake).- I.14 Micropropagation of Mammillaria Species (Cactaceae).- I.15 Micropropagation of Mediocactus coccineus S.D. (Yellow Pitaya).- I.16 Micropropagation of Mussaenda Cultivars.- I.17 Micropropagation of Narcissus (Daffodils).- I.18 Micropropagation of Otacanthus Species.- I.19 Micropropagation of Beaucarnea recurvata Lem. syn. Nolina recurvata (Lem.) Hemsl. (Ponytail Palm).- I.20 Micropropagation of Prunus tenella (Dwarf Russian Almond).- I.21 Micropropagation of Spiranthes sinensis (Pers.) Ames (Orchidaceae).- I.22 Micropropagation of Zinnia.- Section II Medicinal, and Miscellaneous Plants.- II.1 Micropropagation of Duboisia Species.- II.2 Micropropagation of Matricaria chamomilla L. (Camomile).- II.3 Micropropagation of Sideritis Species.- II.4 Micropropagation of Dictamnus albus L. (Gas Plant).- II.5 Micropropagation of Simmondsia chinensis (Jojoba).