Importance of <Emphasis Type="Italic">in vitro</Emphasis> technology to future conservation programmes worldwide

The latest IUCN statistics show that of over 12,000 plant species, 70% are threatened, 19% are critically endangered and 28 species are extinct in the wild. Target 8 of the Global Strategy for Plant Conservation (GSPC) highlights the importance of ex situ conservation of critically endangered plants. Long-term germplasm storage for species with recalcitrant seeds needs alternative measures. In vitro methods complement seed banking and other ex situ measures and are vital for long-term conservation. Conservation Biotechnology at RBG Kew is currently working on a number of rare and threatened recalcitrant species from biodiversity-rich areas of the world to develop good quality in vitro propagules for cryopreservation, recovery and restoration projects. The importance of successful in vitro propagation methods, transplantation technologies, cryopreservation and international networking for the integrated conservation of these species are discussed in detail.     

The possibilities and challenges of <Emphasis Type="Italic">in vitro</Emphasis> methods for plant conservation

Seed-based methods are generally the most efficient for propagating and storing plant germplasm, but these methods are not always adequate, and some species can benefit from in vitro methods for conservation. For species that produce few or no seeds in the wild, plants may be propagated in vitro, and in vitro shoot tips can provide material for cryostorage when seeds are not available or are recalcitrant. In vitro propagated plants may also serve as subjects for research, without depleting the genetic resources of the species. Clonal plants can be used to test out suitable habitat and can be used for basic research on endangered species, without disturbing the wild population. Despite the effectiveness of widely used techniques, however, there are still species that resist initiation into culture or that may be difficult to root or acclimatise. Similarly, tissue cryopreservation methods may be restrained by cost, particularly in maintaining multiple genotypes of many species. Maintaining such genotypes in vitro is also costly and runs the risk of loss or change over time. Examples of the successful use of in vitro methods will illustrate the variety of applications of these techniques, but costs and specific challenges will also be discussed to help define areas where further research is needed to realise the potential of in vitro methods as a tool for conservation.     

<Emphasis Type="Italic">In Vitro</Emphasis> Preservation of Spanish Biodiversity

Spanish territories contain many of the hot spots of plant biodiversity among European countries. Most of the Spanish territory is found in the Mediterranean basin and in the Canary Islands, a region of great floral singularity and diversity (Macaronesian bioregion). Therefore, an important effort must be made to contribute to its conservation. Several strategies can be considered, but seed conservation under standard conditions is the most resource-efficient method. However, the application of this methodology is not always possible for recalcitrant seeds or species for which vegetative propagation is necessary or convenient under some circumstances. Micropropagation is one of the measures suggested for preserving endangered species. During the 1990s, several in vitro culture protocols for Spanish endemics were established. The main purpose of this strategy was to obtain a considerable number of individuals to reduce the loss of natural populations. Likewise, diverse slow growth protocols were developed for this material. However, these efforts usually did not lead to the establishment of in vitro collections. The advantages and disadvantages of the in vitro conservation strategy will be reviewed for some cases. The establishment of the in vitro protocols together with the development of cryopreservation techniques created the ideal conditions to generate cryogenic collections. In this paper, we review the knowledge and experience accumulated during the last decades in micropropagation, slow growth, and cryopreservation for Spanish plant wild species. Their application in the development ex situ collections and their contribution toward an integrated system to conserve threatened species will be discussed.     

In vitro propagation of Notocactus magnificus

Most commercially grown cacti can be easily propagated by seed and/or cuttings. A group of rare and endangered species does not fit into this category and is therefore a good candidate for in vitro propagation productions as a tool to overcome habitat and plant-destruction. The number of rare and endangered species of Cacti goes into about 100. Many show a low production and germination of seeds and plantlets are prone to damping-off, making the in vitro propagation a feasible alternative for the multiplication and conservation of their germplasm. The aim of the present investigation is to establish a protocol for the in vitro culture and plant regeneration of Notocactus magnificus, the blue cactus, a highly ornamental species, native to Brazil. The surface sterilization of the explants was achieved with immersion for 10 min in sodium hypochlorite solution for either seeds (0.25% v/v) or ribs segments (1% v/v). Callus formation was observed when explants were cultured on MS medium supplemented with sucrose at 2% (w/v), 2,4-dichlorophenoxyacetic acid 0.5 μM, benzylaminopurine 4.4 μM, thiamine HCl 0.4 mg l⁻¹ and i-inositol 100 mg l⁻¹. The regeneration of shoots was carried out on MS medium supplemented with either different concentrations of benzylaminopurine and 1-naphthaleneacetic acid, or kinetin and indole-3-acetic acid. The highest number of shoots occurred when MS medium was supplemented with benzylaminopurine 22.2 μM, sucrose 3% (w/v) and agar 0,6% (w/v). In vitro spontaneous rooting of shoots was observed after eight months under culture on MS medium. Only in vitro rooted shoots developed into normal plants under glasshouse culture conditions. This in vitro protocol should be useful for the conservation as well as mass propagation of Notocactus magnificus.     

Use of biotechnologies for the conservation of plant biodiversity

In vitro techniques are very useful for conserving plant biodiversity, including (a) genetic resources of recalcitrant seed and vegetatively propagated species, (b) rare and endangered plant species and (c) biotechnology products such as elite genotypes and genetically engineered material. Explants from recalcitrant seed and vegetatively propagated species can be efficiently collected under field conditions using in vitro techniques. In vitro culture techniques ensure the production and rapid multiplication of disease-free material. Medium-term conservation is achieved by reducing growth of plant material, thus increasing intervals between subcultures. For long-term conservation, cryopreservation (liquid nitrogen, −196°C) allows storing plant material without modification or alteration for extended periods, protected from contaminations and with limited maintenance. Slow growth storage protocols are routinely employed for a large number of species, including numerous endangered plants, from temperate and tropical origin. Cryopreservation is well advanced for vegetatively propagated species, and techniques are ready for large-scale experimentation in an increasing number of cases. Research is much less advanced for recalcitrant species due to their seed characteristics, viz., very high sensitivity to desiccation, structural complexity and heterogeneity in terms of developmental stage and water content at maturity. However, various technical approaches should be explored to develop cryopreservation techniques for a larger number of recalcitrant seed species. A range of analytical techniques are available, which allow understanding physical and biological processes taking place in explants during cryopreservation. These techniques are extremely useful to assist in the development of cryopreservation protocols. In comparison with crop species, only limited research has been performed on cryopreservation of rare and endangered species. Even though routine use of cryopreservation is still limited, an increasing number of examples where cryopreservation is used on a large scale can be found both in genebanks for crops and in botanical gardens for endangered species.     

The establishment of axenic seed and embryo cultures of endangered Hawaiian plant species: special review of disinfestation protocols

More than one third of the USA’s federally listed endangered and threatened plants are endemic to Hawaii. Because of the accelerating rate of environmental pressures resulting from habitat degradation to loss, the Hawaiian Rare Plant Program (HRPP, Lyon Arboretum, Honolulu, Hawaii) utilizes in vitro culture and seed storage to rescue, recover, and restore Hawaii’s most critically endangered native plant taxa. These in vitro methods complement existing ex situ and in situ efforts in the state. Wild-collected seeds tend to be hard to clean, and obtaining contamination-free seeds or embryos without damage or over sterilization is one of the most difficult obstacles in the successful establishment of in vitro cultures. Loss of rare and valuable propagation material occurs when seed samples succumb to contamination or mortality during the initial disinfestation stage. This study reviews pre-treatments and provides examples of three general disinfestation protocols successfully used in the HRPP to establish axenic ovule and embryo cultures of some endangered Hawaiian species. Three disinfestation protocols are described: bleach sterilization, gas sterilization, and ethanol dip and flame. Since 1998, the HRPP has been successful in establishing in vitro cultures of 135 endangered Hawaiian plant taxa representing 30 genera.     

Biotechnology for saving rare and threatened flora in a biodiversity hotspot

The Southwest Australian Floristic Region (SWAFR) is a plant biodiversity hotspot with a geographically isolated and predominantly endemic flora. Known threatening processes (i.e. excessive clearing of native vegetation, soil salinity, soil erosion and chronic weed infestation) combined with uncertain but potentially deleterious environmental (climate) changes pose great challenges for conservation and restoration efforts. With a paucity of nature reserves, in situ protection of species can be problematic. For many species, ex situ conservation becomes the only viable strategy for saving species from extinction via seed banking or living collections established through vegetative propagation, or tissue (in vitro) culture methods. Development of specific in vitro protocols is necessary to successfully initiate culture lines, with considerable development of nutrient media, plant growth regulator regimes and incubation conditions required to optimise shoot regeneration and multiplication, especially with woody species of the SWAFR. In addition, integration of root induction and acclimatization stages has allowed significant improvements in speed and success of plant production of both endangered and difficult-to-propagate woody species. We contend that there is also considerable potential for expansion of alternative in vitro technologies such as somatic embryogenesis for difficult taxa to complement existing ex situ conservation and restoration strategies in biodiversity hotspots such as SWAFR.     

<Emphasis Type="Italic">In vitro</Emphasis> propagation of some important chinese medicinal plants and their sustainable usage

Summary Medicinal plants are valuable sources of medicinal and many other pharmaceutical products. The conventional propagation method is the principal means of propagation and takes a long time for multiplication because of a low rate of fruit set, and/or poor germination and also sometimes clonal uniformity is not maintained through seeds. The plants used in the phyto-pharmaceutical preparations are obtained mainly from the natural growing areas. With the increase in the demand for the erude drugs, the plants are being overexploited, threatening the survival of many rate species. Also, many medicinal plant species are disappearing at an alarming rate due to rapid agricultural and urban development, uncontrolled deforestation, and indiscriminate collection. Advanced biotechnological methods of culturing plant cells and tissues should provide new means for conserving and rapidly propagating valuable, rare, and endangered medicinal plants. The purpose of the present review is to focus the application of tissue culture technology for in vitro propagation via somatic embryogenesis and organogenesis and the cell suspension culture with suitable examples reported earlier. An overview of tissue culture studies on important Chinese medicinal plants and related species is presented.     

<Emphasis Type="Italic">In vitro</Emphasis> conservation of Malaysian biodiversity—achievements,challenges and future directions

Malaysia is fortunate and proud to contain some of the world’s richest biodiversity. In Malaysia, there are an estimated 185,000 species of fauna and 12,500 species of flowering plants, many of which are endemic to tropical forests in this region. Indeed, such diversity is an important and invaluable national asset to safeguard both present and future generations. In vitro conservation offers possible techniques for the preservation of plant germplasm that at present is difficult to maintain or is maintained with limited success. Research at the Universiti Kebangsaan Malaysia (The National University of Malaysia) focuses on the cryopreservation of woody fruit species with seeds that cannot tolerate cryopreservation (recalcitrant or intermediate). Among the plants with recalcitrant seeds are such traditionally important edible tropical fruits as mangosteen, langsat, and rambai (Garcinia mangostana, Lansium domesticum, and Baccaurea motleyana). Citrus aurantifolia, Citrus suhuiensis, Citrus madurensis, Citrus hystrix, and Fortunella polyandra are among the Citrus and Citrus-related species studied. Cryopreservation studies include the Nepenthes species (pitcher plants) of Malaysia. Fundamental research on desiccation and low-temperature tolerance and on the physiology of desiccation are used to understand seed behavior, a prerequisite for the development of successful conservation techniques. At the same time, cryopreservation protocols for several Citrus and forestry species were developed for embryonic axes and adventitious shoots, mainly using rapid dehydration and PVS2 vitrification techniques. There are no successful standard techniques or protocols for species with highly recalcitrant seeds such as Garcinia species. Modification of existing protocols or development of new methods is required, but this can be accomplished only when a detailed understanding of the recalcitrant nature of the seeds or explants is achieved. While we have considerable knowledge concerning the basics of biochemical processes and some molecular data from work on desiccation-tolerant seeds, a great need remains for understanding the cause of the recalcitrance or desiccation sensitivity of these seeds. It may be necessary to use a systems biology approach that exploits the “omics” technologies to generate global molecular data. In combination with bioinformatics for data integration and analyses, this approach would move toward improved modeling of the biological pathways associated with the development of recalcitrant seeds.     

Conservation <Emphasis Type="BoldItalic">in vitro</Emphasis> of rare and threatened ferns—case studies of biodiversity hotspot and island species

The importance of in vitro tools to complement other ex situ methods for saving plants from extinction is more relevant than ever before. More than 50% of the world’s plant species are endemic to the 34 global biodiversity hotspots (GBHs), each holding at least 1,500 endemic plant species. In addition, a large number of small islands hold a number of endemic species on the brink of extinction. Conservation support concentrating more on these hotspots and small islands would significantly reduce the loss of species that is currently occurring. In the majority of these cases, the resources are either locally scarce or difficult to access for in vitro conservation to support other ex situ measures. Most island countries are small, and their geographical position is a stumbling block to initiate active partnerships with other countries when they need to use in vitro tools to rescue plants that produce recalcitrant seeds/spores or propagate only by vegetative means. However, many biodiversity hotspot countries have facilities and expertise, and they concentrate on their own flora for in vitro conservation programmes. For decades, because of the grave threat these plants face, the Conservation Biotechnology Unit, previously known as the Micropropagation Unit, at Royal Botanic Gardens Kew (RBG Kew) has been at the forefront of assisting countries to save their valuable biodiversity through both in situ and ex situ methods. Approaches mentioned here highlight work on recalcitrant ferns from GBHs and small islands. Source materials from recalcitrant species, either spore or seed and in some cases vegetative material, need to be used immediately after collection for tangible results in vitro. This becomes more difficult when only a few plants or small populations are left in the wild. The task becomes harder when available material is small in quantity, and there is greater restriction on the use of available genetic diversity in the wild. This paper highlights the importance of proper collection measures, in vitro culture procedures and cryopreservation and methods for the integrated conservation of threatened ferns from both GBHs and small islands. The importance of international networking to achieve these conservation goals also will be discussed.     

Towards integrated conservation of Australian endangered plants—the Western Australian model

Four percent of the Australian flora is rare and endangered with over 100 taxa presumed extinct. Western Australia contains a large proportion of the endangered flora of Australia with 238 taxa in a critical state of conservation and 70 species presumed extinct. Kings Park and Botanic Garden in south-west Australia is responsible for developing specialized collections of rare and endangered indigenous flora. Macro-and micropropagation procedures are used including conventional cutting and seed propagation, grafting and in thein vitro programme whole seeds (asymbiotic and symbiotic germination), excised seed embryos, shoot apices and inflorescence sections. Wherever possible explants are collected from major provenances of the species and a wide cross section of a species population. Although many of the rare flora of Western Australia are now in theex situ collection maintained by Kings Park and Botanic Garden attempts are being made to develop slow growth storage forin vitro cultures and cryostorage. Trial recovery programmes have commenced with a number of species including the rare and endangered Purdie's donkey orchid (Diuris purdiei). Results of these recovery programmes will guide future efforts in conserving and recovering rare Australian species.     

木兰科植物组织培养技术研究进展

我国木兰科(Magnoliaceae)植物栽培历史悠久且种类丰富,具有很高的科研价值、观赏价值、生态价值与经济价值。但是,生境的破坏和自身繁殖能力的限制,使木兰科许多种的生存受到威胁。由于传统繁殖方式繁殖效率低下,而组织培养技术是推进木兰科种质资源保存及开发利用的有效途径,因此组织培养技术可以应用于濒危资源保护、育种和无性系苗木的商业化生产。木兰科植物的组织培养中无菌短枝扦插途径研究较多,体系已相对完善,一些种类的木兰科植物可以通过此途径得到生根苗;而关于器官发生途径的研究相对较少,愈伤组织诱导困难及不定芽分化困难的问题仍没有得到有效解决,并且体细胞胚发生途径在国内鲜有研究。该文从无菌短枝扦插、器官发生、体细胞胚发生等不同再生途径出发,分析了外植体类型、培养基类型、生长调节剂浓度、培养条件等方面对离体生长的影响,归纳了组培过程中生根困难与褐化等技术问题与解决措施,展望了木兰科植物组织培养技术未来的研究方向,以期为木兰科植物的组培快繁技术研究提供理论依据和技术参考。     

Conservation In vitro of threatened plants—Progress in the past decade

Summary In vitro techniques have found increasing use in the conservation of threatened plants in recent years and this trend is likely to continue as more species face risk of extinction. The Micropropagation Unit at Royal Botanic Gardens, Kew, UK (RBG Kew) has an extensive collection of in vitro plants including many threatened species from throughout the world. The long history of the unit and the range of plants cultured have enabled considerable expertise to be amassed in identifying the problems and developing experimental strategies for propagation and conservation of threatened plants. While a large body of knowledge is available on the in vitro culture of plants, there are limited publications relating to threatened plant conservation. This review highlights the progress in in vitro culture and conservation of threatened plants in the past decade (1995–2005) and suggests future research directions. Works on non-threatened plants are also included wherever methods have applications in rare plant conservation. Recalcitrant plant materials collected from the wild or ex situ collections are difficult to grow in culture. Different methods of sterilization and other treatments to establish clean material for culture initiation are reviewed. Application of different culture methods for multiplication, and use of unconventional materials for rooting and transplantation are reviewed. As the available plant material for culture initiation is scarce and in many cases associated with inherent problems such as low viability and endogenous contamination, reliable protocols on multiplication, rooting, and storage methods are very important. In this context, photoautotrophic micropropagation has the potential for development as a routine method for the in vitro conservation of endangered plants. Long-term storage of material in culture is challenging and the potential applications of cryopreservation are significant in this area. Future conservation biotechnology research and its applications must be aimed at conserving highly threatened, mainly endemic, plants from conservation hotspots.     

In vitro rescue of isolated embryos of Bactris major jacq. and Desmoncus orthacanthos mart., potentially useful native palms from the Yucatan Peninsula (Mexico)

Summary Bactris major and Desmoncus orthacanthos are native palms from the Yucatan Peninsula which could be used as substitutes for rattan. When their seeds were germinated in vivo and in vitro they proved to be highly recalcitrant. Therefore, the culture of isolated embryos was studied as an alternative means of producing planting material for nurseries. It was found that the in vitro germination of the isolated embryos was gradually reduced by storage, falling to zero by 5 wk. However, isolated embryos from freshly collected seeds germinated at ∼100% frequency. The presence of the endosperm, whether still attached to the embryos or separated from them but in direct contact with the nutrient medium, greatly reduced germination in both species. High concentrations of abscisic acid (ABA, 100 μM) only slightly diminished it, suggesting a different cause for the observed endosperm-induced inhibition. This embryo rescue method permits the production of sufficient plants for in vitro micropropagation and the establishment of experimental plots to evaluate the full potential of these materials.     

<Emphasis Type="Italic">In vitro</Emphasis> propagation of the wild carrot <Emphasis Type="Italic">Daucus carota</Emphasis> L. subsp. <Emphasis Type="Italic">halophilus</Emphasis> (Brot.) A. Pujadas for conservation purposes

Daucus carota subsp. halophilus, is a wild crop relative of domestic carrot. It is an aromatic plant widely used in folk medicine due to recognized therapeutic properties of its essential oils. Experiments were carried out to evaluate the potential of in vitro propagation techniques to the conservation of this endemic and endangered taxon. The results showed that shoot tips of in vitro germinated seeds were able to proliferate in the presence of benzyladenine, with the best results being achieved using 4.4 μM, both in the first and second cultures. Shoots rooted after being transferred to 1/2-Murashige and Skoog basal medium. The results indicated that the concentration of benzyladenine used during the multiplication phase did not interfere with the rate of root formation. The obtained plantlets were morphologically and anatomically identical to those obtained by seeds. Some of the in vitro produced shoots developed flowers that produced viable pollen. Plant regeneration was also achieved by somatic embryogenesis induction in cotyledons and root segments cultured in the presence of 4.5 μM 2,4-dichlorophenoxyacetic acid. Somatic embryos converted into plantlets in a medium without growth regulators. Plants obtained either by shoot proliferation or somatic embryogenesis were acclimatized and are now growing at the Coimbra Botanical Garden. The first attempts to reintroduce these plants in the original habitat were successful. It can be concluded that the protocols developed are a useful approach to the conservation of this endemic species.     

Plant regeneration from callus cultures of <Emphasis Type="Italic">Maclura tinctoria</Emphasis>, an endangered woody species

Summary Some native species produce seeds with a low frequency of germination accompanied with a period of dormancy. These features make it difficult to produce new phenotypes through sexual propagation. Maclura tinctoria has been considered an endangered species due to extensive use of its wood and low frequency of seed germination. The objective of the present study is to establish an in vitro propagation system for this species. Organogenic friable callus formation from nodal segments has been obtained using woody plant medium (WPM) supplemented with 10.74 μM 1-naphthaleneacetic acid (NAA)+4.43 μM 6-benzylaminopurine (BA). Results indicate that the highest frequency of shoot formation is observed when WPM supplemented with 4.03 μM NAA+4.43 BA is used. For root formation, the use of WPM medium (pH adjusted to 7.0) supplemented with 23.62 μM indole-3-butyric acid (IBA) and 4.7gl⁻¹ activated charcoal is recommended. For acelimatization, subjecting rooted plantlets to 70%, 50%, and 30% mesh screen, each successively for a period of 7 d, has resulted in 97% plantlet survival.     

Synseed technology—A complete synthesis

Progress in biotechnological research over the last two decades has provided greater scope for the improvement of crops, forest trees and other important plant species. Plant propagation using synthetic seeds has opened new vistas in the field of agriculture. Synseed technology is a highly promising tool for the management of transgenic and seedless plant species, polyploid plants with elite traits and plant lines that are difficult to propagate through conventional propagation methods. Delivery of synseeds also alleviates issues like undertaking several passages for scaling up in vitro cultures as well as acclimatization to ex vitro conditions. Optimization of synchronized propagule development followed by automation of the whole process (sorting, harvesting, encapsulation and conversion) can enhance the pace of synseed production. Cryopreservation of encapsulated germplasm has now been increasingly used as an ex vitro conservation tool with the possible minimization of adverse effects of cryoprotectants and post-preservation damages. Through synseed technology, germplasm exchange between countries could be accelerated as a result of reduced plant quarantine requirements because of the aseptic condition of the plant material.     

Symbiotic seed germination and evidence for <Emphasis Type="Italic">in vitro</Emphasis> mycobiont specificity in <Emphasis Type="Italic">Spiranthes brevilabris</Emphasis> (Orchidaceae) and its implications for species-level conservation

Orchid–mycobiont specificity in the Orchidaceae was considered controversial and not well understood for many years. Differences in mycobiont specificity during germination in vitro vs in situ have lead some to consider orchid–mycobiont specificity as being generally low; however, others have suggested that specificity, especially in vitro, is surprisingly high. Mycobiont specificity may be genus or species specific. An in vitro symbiotic seed germination experiment was designed to examine mycobiont specificity of the endangered Florida terrestrial orchid Spiranthes brevilabris using mycobionts isolated from both the study species and the endemic congener Spiranthes floridana. In a screen of mycobionts, isolates Sflo-305 (99.5%), Sflo-306 (99.5%), and Sflo-308 (89.9%) (originating from S. floridana) supported higher initial (stage 1) seed germination than isolate Sbrev-266 (32.4%) (originating from S. brevilabris) after 3 wk culture. However, only isolate Sbrev-266 supported advanced germination and protocorm development to stage 5 (53.1%) after 12 wk culture. These findings suggest that S. brevilabris maintains a high degree of mycobiont specificity under in vitro symbiotic seed germination conditions. High orchid–mycobiont specificity in S. brevilabris may be indicative of the rare status of this orchid in Florida.     

Photoperiod modulates growth,morphoanatomy, and linalool content in Lippia alba L. (Verbenaceae) cultured in vitro

Biotechnology provides valuable tools to support conservation of plant species, especially in case of threatened taxa or when dealing with seed unavailability, low viability or sterility. However, plant cell culture methods have often to face problems associated with tissue recalcitrance to in vitro systems. Recalcitrance can be related to a variety of triggering factors, involving many efforts and manipulations within one or more of the micropropagation stages before obtaining successful results. An in vitro propagation protocol was developed for Zelkova sicula, a very rare and endangered relict tree, endemic to Sicily (Southern Italy). The species revealed extremely recalcitrant to in vitro culture approaches, but after many trials throughout a number of years an effective micropropagation protocol was completed. The rooting rate was about 84% of the treated explants, 8% of which were successfully acclimatized outdoor and reintroduced in the wild within a comprehensive conservation project. The technique allowed to overcome the problems of sexual sterility of this species, hence contributing concretely to contrast the problems connected with its conservation. However, additional efforts need to be carried out in order to refine the acclimatization step and further improve the whole process effectiveness.

     

Goldenseal (<Emphasis Type="Italic">Hydrastis canadensis</Emphasis> L.): <Emphasis Type="Italic">In vitro</Emphasis> regeneration for germplasm conservation and elimination of heavy metal contamination

Summary Hydrastis canadensis L. (Goldenseal) is an endangered medicinal plant used in the treatment of many ailments, such as gastrointestinal disturbances, urinary disorders, hemorrhage, skin, mouth and eye infections, and inflammation. Commercial preparations of wild-harvested goldenseal were found to contain heavy metal contaminants including aluminum (848 μgg⁻¹), cadmium (0.4μgg⁻¹), lead (18.7μgg⁻¹), and mercury (0.1 μgg⁻¹). As well, goldenseal is an endangered species listed in the Convention on International Trade in Endangered Species of Wild Fauna and Flora (CITES) Appendix II. Therefore, the practice of wild-harvest is actually decimating natural populations of goldenseal and endangering its genetic diversity. In vitro propagation protocol by tissue culture was developed for producing high-quality tissues of goldenseal. Significantly more de novo regeneration was induced on stem explants of 3-mo.-old plants cultured on a medium containing 10 μM 6-benzylaminopurine (BA) (22 regenerants per explant) than any other treatment. Subculture of the regenerants on a medium devoid of growth regulators resulted in the development of complete plants that were acclimatized and thrived in standard greenhouse conditions. The plants regenerated in vitro contained the lowest levels of heavy metals. The findings of this study provide the first evidence that heavy metal contaminants bioaccumulate in goldenseal tissues and also provide a method for germplasm conservation, mass multiplication, and production of goldenseal tissues free from abiotic contamination.