SBIR-STTR Award

Problem Cypripedium is a genus of temperate terrestrial slipper orchids with very showy flowers that make excellent garden plants, and which have several medicinal properties related to the sedative, hypnotic and spasmolytic activity of rhizome extracts. Several species of Cypripedium were once common across the northern United States. Loss of habitat due to development as well as overcollection for the natural medicines and floriculture trades has made most species uncommon and several endangered. There is a large potential market for these plants which may only be slowly produced from seed. Many species of orchids are readily produced in large numbers of uniform plants using micropropagation from tissue explants. No such methods have been developed for Cypripedium making the plants uncommon and expensive. Purpose It is the purpose of this project to determine what concentrations of ratios or auxin and cytokinine growth factors are necessary to 1) induce the formation of callus tissue and its continued expansion and 2) what changes in growth factor concentrations and ratios result in differentiation of callus into protocorm-like bodies, and then plantlets. It is the goal of this project to identify methods that may be further developed into protocols that reproducibly induce callus formation by tissue explants, cause callus to differentiate, and which induce the differentiation of callus into protocorm-like bodies and then into plantlets with roots and shoots. OBJECTIVES: Cypripedium is a genus of temperate terrestrial slipper orchids with considerable horticultural and naturopathic medicine potential. While many species of orchids with horticultural value may be rapidly and uniformly reproduced using micropropagation techniques, such techniques have not been developed for any slipper orchid, including Cypripedium. Several pilot studies have suggested that micropropagation of Cypripedium is possible, but no reliable methodology has been developed. The objectives of this project are to identify a method by which callus may be reliably produced from Cypripedium explants and to identify a method by which callus may be induced to differentiate into plantlets with roots and shoots. The first step toward successful micropropagation is the development of methods that reliably produce callus tissue that may be expanded in vitro and subcultured at will. Initiation of callus growth from tissue explants of Cypripedium orchids is not straightforward using current techniques whereas once callus has been obtained, it is reasonably straightforward to induce differentiation into protocorm-like bodies and plantlets. Therefore, in order to establish viable commercial methodology for mass micropropagation of Cypripedium, a reliable method of inducing callus growth in a high percentage of explants must be developed. The primary objective of this project is to develop a micropropagation method utilizing explants that do not harm the donor plants. Thus, since Cypripedium have many individual roots considerable effort will be made to develop a method based on the use of root tip explants. As an alternative approach, we will seek to develop a micropropagation method that utilizes explants from another primordial tissue, lateral buds. Use of lateral buds will cause donor plants to abort new growth for at least one season, but should usually not kill the donor. The second objective of this project is to develop methodology by which callus may be divided and explanted into media that induce differentiation into multiple plantlets that may be grown in flask until roots and shoots are present, with the ultimate goal of being able to transfer plantlets into garden culture. APPROACH: To most closely mimic plants that would be used to obtain explants in a commercial operation, we will explant tissue from mature Cypripedium reginae that have bloomed. Explants, either root tip or lateral bud, will be placed into sterile culture on agar to which have been added either an auxin or cytokinin, or both. Concentration-response (induction of callus) will be assessed for each growth factor as well as ratios between auxin and cytokinin when both are present. In some experiments a complex growth additive, potato, will be included. During the course of these experiments it will also be determined what concentrations and ratios of growth factors are required to maintain callus in continuous culture. Once callus is obtained, experiments will be carried out to determine what conditions induce differentiation of callus into protocorm-like bodies and then to plantlets with shoots and roots. These experiments will include treatments in which auxin is absent but cytokinin maintained, treatments in which both auxin and cytokinin are absent, and experiments in which auxin and cytokinin are absent and charcoal present to further reduce growth factor concentration by adsorption. Our preliminary observation that potato may serve as a necessary complex growth additive will also be examined. The expected outcome of this project is a method that reliably results in formation of callus from a tissue explant and the ability to induce differentiation of the callus into plantlets

Cypripedium is a genus of temperate terrestrial ladyslipper orchids of excellent garden size, forming clumps or 12 - 18 inches in diameter or more, with very showy flowers. Many species are easy to grow in northern gardens (USDA zones 2-7) and have excellent horticultural potential. Today, several nurseries grow a few species and hybrids from seed, although a number of garden-worthy species have not yielded to propagation by seed germination. Several exceptionally garden-worthy hybrids have been developed, but as with the hybrids of many orchids and other flowering plants, vigor and flower appearance varies from specimen to specimen. At present no method of vegetative mass production of superior cultivars is available for Cypripedium. The goals of this research are 1) further optimization of methodology to rapidly induce plantlet formation from callus derived from a wide range of horticulturally superior cypripedium hybrids, and 2) development of grow-out methodology that results in the survival of a large percentage of plantlets into flowering plants within four years from deflasking. Success in this program will allow large scale production of cypripedium cultivars for provision of superior cultivars to the floricultural market. Orchid production is valued at $140 million wholesale in the U.S. Unlike tropical orchids, which are optimally produced in southeast Asia, cypripedium are optimally produced in the northern U.S. While many floriculturally important orchids including the Cattleya alliance, Cymbidium, and Phalaenopsis are mass produced using in vitro micropropagation techniques, ladyslipper orchids have thus far not yielded to micropropagation using commercially relevant methodology. Unlike the seed of many epiphytic orchids, seed of terrestrial orchids is difficult to germinate due to the introduction during seed maturation of growth inhibitory factors that enable seed to survive the harsh weather conditions of winter. Only beginning in the 1980s has germination from seed of some species of cypripedium become routinely practiceable, and the first generally successful protocols for seed germination and maturation of seedlings appeared in the mid-1990s. Indeed, while hybrids of many orchid genera have been registered since the mid-1800s, the cypripedium hybrid was registered in 1991. The availability of uniform, vegetatively mass-produced offspring of commercially important orchids such as Cattleya, Cymbidium and Phalaenopsis dramatically transformed the worldwide markets for hybrids of those species. The market for orchids in the U.S. has been rapidly growing, from $47 million at the wholesale level in 1995 to $144 million in 2005. Virtually all of these orchids are produced using vegetative micropropagation. Today, most mass production of these tropical species occurs outside the U.S., particularly in southeast Asia where the climate dramatically reduces production costs. In contrast, Cypripedium grow in temperate climates and require prolonged freezing conditions during the winter. This makes many regions of the U.S. particularly attractive regions in which to establish commercial production. OBJECTIVES: While many floriculturally important orchids are mass produced using in vitro micropropagation techniques, Cypripedium have thus far not yielded to micropropagation using commercially relevant methodology. Orchids of various genera have been successfully micropropagated from shoot buds, node buds, root tips and leaf explants. In previous attempts at development of methods for micropropagation of Cypripedium, bud explants, root tip explants, nodal explants and leaf explants have been used. In most protocols young Cypripedium seedlings still in flask were used as sources of explant materials. Flasked Cypripedium seedlings do not produce shoot buds typical of older plants. The goals of this research are 1) further optimization of methodology to rapidly induce plantlet formation from callus derived from a wide range of horticulturally superior cypripedium hybrids, and 2) development of grow-out methodology that results in the survival of a large percentage of plantlets into flowering plants within four years of deflasking. Success in this program will allow large scale production of cypripedium cultivars for provision of superior cultivars to the floricultural market. Specific Aim 1: Evaluate and optimize the the micropropagation method developed for Cypripedium reginae (Section Obtusipetala) root tip explants in species from other commercially important subgenera and hybrids. Anticipated Results. As a result of our success with Cypripedium reginae (Phase I grant), we anticipate that conditions may be optimized for species and hybrids from all of the sections of the genus Cypripedium. Specific Aim 2: Optimize a method to induce callus formation and differentiation into plantlets using Cypripedium dormant lateral bud explants. As a backup method of micropropagation, we will also attempt to induce plantlet formation from lateral buds. While lateral buds are generally a less attractive option for micropropagation than root tips owing to the damage rendered to the donor plant, there are circumstances in which it is desirable to have such a method available. Anticipated Results. Cytokinin treatment of dormant lateral buds has been used to induce callus growth. Specific Aim 3: Develop a method that reliably supports maximum growth rate of micropropagated Cypripedium plantlets into flowering size plants. Wild Cypripedium require up to 12 years to produce flowering plants from seed. Laboratory-propagated Cypripedium plants generally require about five-six years to grow to flowering size, although a few plants grown from seed from a given pod may bloom in their fourth year. If plants can be grown to reliably flower after four years, considerable labor resources may be saved, making it possible to dramatically reduce prices that must be charged for these horticulturally important plants. Anticipated Results. Cypripedium require constant moisture around their roots but at the same time require a highly aerated medium or roots and rhizome will rapidly rot with loss of the plant. Hydroponics conditions are expected to allow optimization of automatic watering and fertilization cycles with the goal of growing seedlings rapidly to maturity. APPROACH: Specific Aim 1. We will evaluate our methods optimized to induce callus formation and differentiation of Cypripedium reginae root tip meristem into plantlets in species from Section Cypripedium and Section Macrantha as well as in several important hybrids. Harvais medium with potato homogenate will form the baseline medium. Callus formation will be observed for 16 weeks under conditions of differing ratios of auxin to cytokinin. When callus formation is observed, it will be removed and explanted to new flasks containing either: 1) the same growth factors as the donor flask, 2) only auxin at the same concentration as the donor flask, 3) only cytokinin at the same concentration as the donor flask, or 4) no growth factors. Specific Aim 2. As a backup method of micropropagation, we will also attempt to replicate and extend preliminary observations of plantlet formation from lateral buds. High cytokinin concentration alone has been shown to induce plantlet formation from lateral buds, a standard technique to reduce apical dominance of shoot meristem. All flasks will be incubated at 25 C in the dark and examined for growth once per week. There will be 3 general growth conditions: a) no complex additive will be included in the media, b) potato homogenate in the media, and c) coconut water in the media. In each series of groups, varying ratios of auxin to cytokinin will be used. Specific Aim 3. Wild Cypripedium require up to 12 years to produce flowering plants from seed. Laboratory-propagated Cypripedium plants generally require five-six years to grow to flowering size, although a few plants grown from seed from a given pod may bloom in their fourth year. If plants can be grown to reliably flower after four years, labor resources may be saved. Plantlets will be deflasked in the fall and vernalized over the winter for May plant-out. All plantlets will be grown in the same shade house under 70% shade cloth. Plantlets will be maintained in plastic flats. Plantlets will be grown in the following groups: a) under a regimen of daily watering from overhead at noon with continuous fertilization using complete hydroponics medium diluted to maintain concentration at 100, 300, or 600 ppm; b) under a regimen of daily watering from overhead at noon with fertilization at concentrations of 100, 300, or 600 ppm one time each week; c) under ebb-and-flow hydroponics conditions with twice daily flooding; d) under ebb-and-flow hydroponics conditions with six times daily flooding at ambient (measured) temperature; and e) under ebb-and-flow hydroponics conditions as in group 4, but with water maintained at 80 F. Temperature 1 cm below the surface of the media will be monitored and compared to air temperature 1 meter above the flat. Temperatures of flats will be assessed prior to and after watering at noon (overhead watering) and 4 PM (ebb-and-flow). Plantlets typically go dormant beginning in late September. Thus, during year 1, on August 15 when growth for the season is complete, plantlet height, leaf number and length, wet weight and root weight will be determined. Identical measurements will be made on August 15 of year 2.