Hostname: page-component-cd9895bd7-gbm5v Total loading time: 0 Render date: 2024-12-27T12:46:35.302Z Has data issue: false hasContentIssue false

Strengthening the conservation value of ex situ tree collections

Published online by Cambridge University Press:  09 February 2015

Nicole Cavender
Affiliation:
The Morton Arboretum, 4100 Illinois Route 53, Lisle, IL 60532, USA
Murphy Westwood*
Affiliation:
The Morton Arboretum, 4100 Illinois Route 53, Lisle, IL 60532, USA
Catherine Bechtoldt
Affiliation:
The Morton Arboretum, 4100 Illinois Route 53, Lisle, IL 60532, USA
Gerard Donnelly
Affiliation:
The Morton Arboretum, 4100 Illinois Route 53, Lisle, IL 60532, USA
Sara Oldfield
Affiliation:
Botanic Gardens Conservation International, Richmond, Surrey, UK
Martin Gardner
Affiliation:
Royal Botanic Garden Edinburgh, UK
David Rae
Affiliation:
Royal Botanic Garden Edinburgh, UK
William McNamara
Affiliation:
Quarryhill Botanical Garden, Glen Ellen, USA
*
(Corresponding author) E-mail [email protected]
Rights & Permissions [Opens in a new window]

Abstract

With 10% of trees (> 8,000 species) threatened with extinction there is an urgent need for botanical gardens to protect threatened trees in dedicated conservation collections. Species conservation is mentioned in the mission statements of most major botanical gardens, yet the actual conservation value of existing ex situ tree collections is low. We conducted interviews with members of the botanical garden community and organized a symposium at the 5th Global Botanic Gardens Congress to identify challenges and collect recommendations to improve living ex situ tree collections. We summarize and evaluate this information to facilitate gardens becoming more effective agents for global tree conservation. Experts agree that gardens offer valuable strengths and assets for tree conservation. Some challenges exist, however, including a lack of strategic conservation focus, collection management limitations, gaps in fundamental biological information for trees, and a lack of global coordination. Solutions are offered to facilitate gardens and arboreta of all sizes to participate more effectively in tree conservation. Prioritizing genetically diverse tree collections, participating in conservation networks, developing tree-specific conservation models and guidelines, and strengthening tree science research efforts are a few examples. Most importantly, a more coordinated global effort is needed to fill knowledge gaps, share information, and build conservation capacity in biodiversity hotspots to prevent the loss of tree species.

Type
Papers
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/3.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © Fauna & Flora International 2015

Introduction

Globally, 10% of all trees (> 8,000 species) are threatened with extinction (Oldfield et al., Reference Oldfield, Lusty and MacKinven1998). Although protecting a threatened species in its natural habitat (in situ conservation) is the ideal and most effective way to prevent extinction, there is a growing realization that complementary protection efforts outside a species’ natural habitat (ex situ conservation) are also crucial for species’ survival (Kramer et al., Reference Kramer, Hird, Shaw, Dosmann and Mims2011; Oldfield & Newton, Reference Oldfield and Newton2012; Pritchard et al., Reference Pritchard, Fa, Oldfield and Harrop2012). The success of in situ conservation is dependent on a variety of factors, including accurate assessment of threats, local community and government engagement, and the susceptibility of native habitat to climate change (Robinson, Reference Robinson, Mansourian, Vallauri and Dudley2005; Oldfield & Newton, Reference Oldfield and Newton2012; Pritchard et al., Reference Pritchard, Fa, Oldfield and Harrop2012). Ex situ conservation approaches can complement in situ conservation by strategically avoiding these confounding factors. In some cases a small population size or an imminent threat could render in situ conservation of a tree species unviable, making ex situ conservation the only option to prevent its immediate extinction (McNamara, Reference McNamara2011; Ma et al., Reference Ma, Chen, Grumbine, Dao, Sun and Guo2013). Storage in a seed bank is the most economic and practical way to protect tree species, but many trees, such as oaks, cannot be stored using existing technologies. These ‘exceptional’ species must be housed in living collections (Pence, Reference Pence2013). Furthermore, while threatened tree species are growing in living collections, experts can study how they develop, reproduce, and combat disease, and how they might respond to climate change and assisted migration efforts.

The field of ex situ conservation by botanical gardens and arboreta (henceforth referred to as gardens) has been developing since the 1980s (Bramwell et al., Reference Bramwell, Hamann, Heywood and Synge1987; Falk, Reference Falk1987; Falk & Holsinger, Reference Falk and Holsinger1991; Guerrant et al., Reference Guerrant, Havens and Maunder2004). Since the first International Botanic Gardens Conservation Congress, in 1985, governments and non-profit organizations have been working to stimulate greater involvement by gardens in plant conservation. Following the 1985 Congress, Botanic Gardens Conservation International was founded to support and coordinate the conservation activities of gardens worldwide. It also promotes and evaluates the progress of national and international conservation policy initiatives, such as the Global Strategy for Plant Conservation, which outlines 16 targets to be achieved by 2020 (CBD, 2012), and the International Agenda for Botanic Gardens in Conservation (BGCI, 2012).

There are several resources available to guide ex situ conservation efforts, such as the IUCN Red List (IUCN, 2013) and NatureServe threat status listings. There are databases available for searching collections of living plants (e.g. Botanic Gardens Conservation International's PlantSearch, and the Global Biodiversity Information Facility), confirming taxonomic identity (e.g. International Plant Names Index), and exploring distribution maps (e.g. Map of Life). For a review of electronic resources see Lughadha & Miller (Reference Lughadha and Miller2009). There are several manuals available that outline the practical application of plant conservation by gardens, addressing issues such as collecting germplasm for genetic diversity, developing propagation techniques and implementing reintroduction programmes (Guerrant et al., Reference Guerrant, Havens and Maunder2004; Kramer et al., Reference Kramer, Hird, Shaw, Dosmann and Mims2011; Maschinski & Haskins, Reference Maschinski and Haskins2012; BGCI, 2014a; Center for Plant Conservation, 2014).

These resources are useful tools for plant conservation. However, what gardens can do to support conservation of trees, specifically, has been given less attention. Conserving tree species in living collections poses particular challenges, such as accession longevity and space constraints, compared with herbaceous plants. These factors, combined with the problem that long-lived trees adapt more slowly to climate change (Aitken et al., Reference Aitken, Yeaman, Holliday, Wang and Curtis-McLane2008; Gill et al., Reference Gill, Magin and Bertram2013), make the development of tree-specific conservation resources vital. One such resource is a reference manual produced by Botanic Gardens Conservation International through the Global Trees Campaign (Oldfield & Newton, Reference Oldfield and Newton2012), which explains the steps institutions can take to protect threatened tree species, starting with ex situ conservation but also emphasizing in situ conservation, environmental education, public engagement, and reintroduction.

Despite these resources, challenges to ex situ tree conservation still exist and much work is needed to improve the conservation quality of living tree collections in gardens. Many threatened trees are underrepresented in ex situ collections, and genetic breadth is limited (Cibrian-Jaramillo et al., Reference Cibrian-Jaramillo, Hird, Oleas, Ma, Meerow, Francisco-Ortega and Griffith2013; Cires et al., Reference Cires, De Smet, Cuesta, Goetghebeur, Sharrock and Gibbs2013). The systemic shortfall in ex situ collections is illustrated by assessments of the progress of U.S. gardens towards achieving Target 8 of the Global Strategy for Plant Conservation, which calls for the preservation of 75% of threatened plant species in ex situ collections, preferably in the country of origin. The USA is less than halfway towards achieving Target 8 and would need to increase the number of new native species protected each year almost tenfold to achieve this target by 2020 (Hird & Kramer, Reference Hird and Kramer2013; BGCI, 2014c). Furthermore, almost 50% of threatened taxa in the USA are held in just one collection, which represents insufficient genetic diversity to be of conservation value. Although these assessments considered all plant species, not only trees, we know that the outlook is even worse for trees.

There is an urgent need and opportunity for botanical gardens to play a more strategic and active role in supporting global tree conservation through dedicated ex situ tree collections: ‘botanic gardens and other ex situ facilities such as seed banks are among the most extensive yet underused plant conservation resources in the world’ (Maunder et al., Reference Maunder, Guerrant, Havens, Dixon, Guerrant, Havens and Maunder2004). Gardens have the expertise, facilities and mission to conserve threatened trees, yet few of them are doing it effectively (Maunder et al., Reference Maunder, Guerrant, Havens, Dixon, Guerrant, Havens and Maunder2004; Kramer et al., Reference Kramer, Hird, Shaw, Dosmann and Mims2011). Clearly, certain barriers exist to establishing and/or maintaining a high-value ex situ conservation collection of threatened trees.

Objectives and methods

We employed two strategies to evaluate the current state of ex situ tree conservation. Firstly, we conducted interviews (Supplementary Material 1) with 18 leaders of the botanical garden and conservation communities (see Acknowledgements) to identify barriers to ex situ tree conservation and to explore solutions to the questions posed in the interviews. Secondly, we organized a symposium at the 5th Global Botanic Gardens Congress in New Zealand in October 2013, which included four talks, by WMN, NC, DR and SO. Each presented a case study of how their institutions are contributing to ex situ conservation (summarized in Supplementary Materials 2–5). The presentations were followed by an open discussion, which included many members of the garden community, to promote the exchange of ideas on ex situ tree conservation.

From the interviews and conference symposium there emerged a wealth of information and ideas relating to the current state of ex situ tree collections. Here, we synthesize the opinions, ideas and recommendations of leaders of the global garden community, and formulate strategies to overcome challenges and streamline efforts to make gardens more effective agents for global tree conservation.

Challenges and recommendations

Evolving the garden mission and collection curation

Protecting plant species for the purpose of conservation is declared explicitly in the mission statements of most major gardens but few maintain ex situ collections with any real in situ conservation value, especially for tree species. There is often a lack of strategic focus. To evolve their missions, gardens need to develop measurable conservation goals, such as those aligned with the targets and time line of the Global Strategy for Plant Conservation. Furthermore, tree conservation should feature in all aspects of garden operations and activities, including horticulture, education, interpretation, database development and fundraising.

A significant challenge to building high-quality living conservation collections is the historical tradition of regarding living tree collections in the same way as stamp collections, where curators focus on acquiring one individual of many species. Such synoptic collections have limited use in conservation because they represent a relatively small gene pool. The most important consideration when assessing the conservation value of an ex situ collection is to maximize the depth and breadth of its genetic diversity, relative to wild populations, across the entire geographical range of the species (Li et al., Reference Li, Chen, Zhang, Tian-Yi, Hui-Ping and Yue-Wei2005; Namoff et al., Reference Namoff, Husby, Francisco-Ortega, Noblick, Lewis and Griffith2010; Samain & Cires, Reference Samain and Cires2012; Cibrian-Jaramillo et al., Reference Cibrian-Jaramillo, Hird, Oleas, Ma, Meerow, Francisco-Ortega and Griffith2013; BGCI, 2014a).

Curating a high-quality living conservation collection of trees is a challenging undertaking that requires a long-term management strategy to maintain genetic diversity and prevent hybridization, genetic drift and artificial selection from degrading its value. There is a trade-off between the number of tree species a garden can maintain in collections and the depth of each collection. Because of diminishing marginal returns there is an ideal size at which a collection preserves the most genetic diversity at the least cost. This size depends on the species’ life history, generation time, breeding system and population dynamics. Pioneering studies have been conducted for a few plant species, to predict the optimal size for a conservation collection, but more research is needed to develop scientifically informed models for a phylogenetic range of tree taxa (Griffith & Husby, Reference Griffith and Husby2010; Griffith et al., Reference Griffith, Lewis and Francisco-Ortega2011; Cibrian-Jaramillo et al., Reference Cibrian-Jaramillo, Hird, Oleas, Ma, Meerow, Francisco-Ortega and Griffith2013; BGCI, 2014a).

The ultimate goal for a garden should be a well-curated ex situ conservation collection of multiple accessions that represents the genetic diversity of wild populations, with collaborative in situ initiatives for reintroduction and habitat protection, leading to recovered wild populations of healthy trees: an integrated conservation management strategy (Falk, Reference Falk1987; Oldfield & Newton, Reference Oldfield and Newton2012). One example is the Acer pentaphyllum conservation programme at Quarryhill Botanical Garden, Glen Ellen, USA. The last remaining wild population of this Critically Endangered Chinese endemic tree is under imminent threat by dam construction. Quarryhill has established a conservation grove of 200 wild-origin trees, and research is underway to improve cultivation methods. The garden is also working with local communities in China to promote in situ conservation of the species (Supplementary Material 2).

Prioritizing tree species for conservation

How to prioritize tree species for conservation was the most controversial topic amongst the experts interviewed. The reality is that no single garden can protect all of the > 8,000 threatened tree species. Many gardens may only have sufficient resources to invest in the conservation of a few or only one target species, but that in itself would be progress. Maunder et al. (Reference Maunder, Guerrant, Havens, Dixon, Guerrant, Havens and Maunder2004) described five factors to consider when making decisions about which tree species to prioritize for ex situ conservation; here we add three more (Table 1).

Table 1 Criteria for prioritizing tree species for ex situ conservation, proposed by Maunder et al. (Reference Maunder, Guerrant, Havens, Dixon, Guerrant, Havens and Maunder2004) and experts interviewed for this study.

Most importantly, gardens should be pragmatic and realistic in scope, and assess their own circumstances when prioritizing species for conservation. Available resources and space, the existing collection, local scientific expertise, regional habitat and climate (and predicted future climate), and the interests of the local community are all important variables to consider. Species must be chosen that complement these needs and conditions, for ease of implementation and to maximize the success of the conservation collection.

Information technology and data management

With the rise of the big-data era the gap in basic biological information and database management technology for tree conservation purposes is obvious. There is a lack of critical biological and ecological information at the species level for the majority of trees. In a 1998 Red List assessment of trees (Oldfield et al., Reference Oldfield, Lusty and MacKinven1998) there were sufficient data available to evaluate c. 10,000 species, just 10% of the predicted total of 100,000 species. Gaps in knowledge about tree taxonomy and phylogeny, reproductive ecology, seed biology (specifically whether a species may be considered exceptional), and species distributions limit the ability of gardens to prioritize tree species for maximum conservation impact.

There are many strategies that gardens can employ, both individually and as a coordinated community, to address these information gaps. Gardens can work with academia to improve scientific rigour in tree research. The dissemination of research and conservation results (both successes and failures) is of utmost importance to enhance collective knowledge and prevent unnecessary duplication of effort. New communication channels such as social media networks can be fast and efficient ways of sharing information. It is important for gardens to promote botanical degree programmes, teach courses and mentor students, to ensure that the next generation of plant scientists, horticulturalists and collections curators is prepared to take over. Another strategy for generating knowledge is to create collaborative hubs of tree science research, linking the garden community with other sectors. Forming these broad institutional alliances promotes the exchange of technology, improves access to conservation facilities (e.g. genetic analysis laboratories, seed banks and tissue culture laboratories), and leverages strengths and resources from different institutions to increase funding opportunities. The Center for Tree Science at The Morton Arboretum is an example of this strategy. It brings together experts from gardens, academia, industry, government and non-profit organizations to catalyse innovative research, provide new training opportunities, and develop solutions to the challenges facing trees in urban areas and in the wild (Supplementary Material 3).

A well-managed database is critical to a collection's conservation value but this is an area where technology, data sharing, and process standardization are limited. Botanic Garden Conservation International's PlantSearch database (BGCI, 2014b) facilitates gardens to make their collection records openly accessible but participation is voluntary and requires regular updating. Not all of the contributed data are made publicly available because of concerns over the security of threatened species. Sharing collections data, especially genetic diversity information, is key to facilitating collaborations and understanding which tree species are receiving ex situ conservation attention. Collections databases also provide valuable information on species distributions. Gardens can improve the conservation quality of their collections by contributing occurrence data (for both living and herbarium collections) to open-access databases such as the Global Biodiversity Information Facility (GBIF, 2014) and iDigBio (iDigBio, 2011), which enable meta-analysis of biodiversity data, encourage standardization of collections data, and improve understanding of the distribution of tree species (e.g. Pimm et al., Reference Pimm, Jenkins, Abell, Brooks, Gittleman and Joppa2014). This is one area where citizen science initiatives can make a significant impact, for example by crowd-sourcing the collation of information from digitized herbarium sheets into databases.

Working together at a global scale

There is limited regional or international coordination of tree conservation efforts within the global community of > 3,200 botanical gardens and arboreta. Although gardens have a long tradition of reciprocal plant exchange and joint collecting expeditions, collaborative conservation programmes are still uncommon. Communication among distant gardens is becoming easier through social media but this network is ad hoc and unorganized. National professional organizations (e.g. the American Public Garden Association) and networks (e.g. the Center for Plant Conservation) are good catalysts and models to promote cross-institutional collaborations for tree conservation but are limited in geographical scope. There is potential to build a stronger, coordinated, global network, which is essential to confront the global tree diversity crisis.

Gardens can collaborate more effectively by participating in international tree-focused networks such as the Global Trees Campaign and ArbNet. The Global Trees Campaign, a joint initiative of Fauna & Flora International and Botanic Gardens Conservation International, has > 20 years’ success in tree conservation, reforestation projects, red-listing initiatives and environmental education programmes, and providing tree conservation resources. The most significant asset of the Global Trees Campaign is its ability to promote cross-institutional collaborations and connect tree-focused gardens with in situ conservation opportunities. ArbNet is another global networking organization that fosters professionalism, provides guides and resources, and promotes conservation collaborations among arboreta (Supplementary Material 3).

Gardens can work more collaboratively by establishing or joining a hub of conservation action, in which one organization or consortium takes responsibility for coordinating the conservation activities for a particular taxonomic group or geographical region. These activities can include maintaining living collections (e.g. North American Plant Collections Consortium), monitoring and restoring wild populations (e.g. Center for Plant Conservation, Ecological Restoration Alliance) and coordinating red-listing efforts (e.g. Global Trees Campaign). The International Conifer Conservation Programme, based at the Royal Botanic Garden Edinburgh, is a conservation consortium that conducts field surveys, threat assessments and propagation research for conifers, 34% of which are threatened (IUCN, 2013). It also operates an innovative programme of safe sites for genetically diverse ex situ conservation collections of threatened conifers. These sites include > 200 public parks, private estates, golf courses, hotels, monasteries and hospitals that are growing thousands of threatened conifers. This model facilitates the participation of non-traditional gardens in tree conservation and provides an exponential increase in the number of threatened trees protected, outsourcing of custodial care for ex situ collections, and a wider choice of growing sites (Supplementary Material 4).

Another way to broaden the impact of the global network is to empower smaller gardens (e.g. college arboreta, public parks, cemeteries, private tree collections) to contribute to ex situ tree conservation. These gardens can collaborate with leading gardens by volunteering to grow threatened tree species, similar to the International Conifer Conservation Programme's safe site approach. This is especially valuable when smaller gardens are located in ecologically unique, valuable or threatened habitats. Smaller gardens can leverage the expertise, resources and germplasm available from larger gardens to support tree conservation efforts, and can also act as local liaisons to facilitate collecting trips, monitor local threatened tree populations and support citizen science programmes. Land owners of all types, such as municipalities, universities, religious organizations, golf courses, cemeteries and private estates, could be recruited to conserve threatened trees on their property through a coordinated approach led by larger gardens or conservation consortia.

In addition to empowering smaller gardens it is particularly important for the global garden community to build capacity and lobby for in situ tree conservation in biodiversity hotspots, where there is generally less access to resources and training opportunities. This is accomplished through institutional partnering and international conservation collaborations. One example is the collaboration between the Global Trees Campaign and Brackenhurst Botanic Garden in Kenya. Established in 2001, Brackenhurst Botanic Garden was created by replanting a clear-cut valley with native trees of East African tropical submontane forest. Several native tree conservation initiatives have been implemented there, including propagation programmes, botanical tours, ecology education programmes and a native seed collecting collaboration with the Millennium Seed Bank Project (Supplementary Material 5). The Global Trees Campaign, Kew Gardens and Missouri Botanical Garden support Brackenhurst by raising global awareness of the programme, providing training and advisory support, garnering additional funding, and managing funds generated in the USA so that donations are exempt from taxation. When leading gardens support tree conservation at gardens in biodiversity hotspots they have a significant impact because of the urgent need for action, the lack of local aid, and the higher relative purchasing power of funds in these regions.

Exchanging plant material is another important way the global garden network can improve tree conservation efforts. Gardens can expand the genetic breadth and thus increase the conservation value of their tree collections in a cost-effective manner by sourcing well-documented, wild-origin accessions from other gardens. National and international conservation policies, such as CITES and the Convention on Biological Diversity, can be both a help and a hindrance to international exchange of plants. These conventions are beneficial because they contribute to global biodiversity conservation, guide governments to enact environmental policy, and regulate international access and benefit sharing. However, inconsistent implementation by some countries has impeded scientific collecting efforts by experts with legitimate research and conservation goals (Roberts & Solow, Reference Roberts and Solow2008). This is a complex and delicate diplomatic situation to resolve but there are two complementary solutions. In the long term the most sustainable solution is to build capacity at gardens in biodiversity hotspots so they can maintain ‘near situ’ conservation collections of threatened endemic trees. In the short term the garden community can advocate for urgently needed ex situ conservation collections, and encourage the Parties to CITES and the Convention on Biological Diversity to consider an exemption for non-profit gardens to export threatened tree species strictly for conservation and research purposes. Table 2 presents a summary of the key conservation recommendations.

Table 2 Practical recommendations for botanical gardens and arboreta to improve conservation efforts and increase the value of ex situ tree collections.

Conclusions

Botanical gardens and arboreta represent the accumulated knowledge of hundreds of years of plant identification, taxonomy, collecting, horticulture and curation. They also have the land and facilities, such as breeding nurseries, tissue culture laboratories and seed banks, required to maintain genetically diverse tree collections in the long term. With these strengths and assets, gardens are in a unique position to play a significant role in mitigating the global tree biodiversity crisis through ex situ conservation.

A number of challenges to effective ex situ tree conservation need to be confronted, however, including a lack of strategic conservation focus, collection management limitations and gaps in fundamental biological information for trees. Some of these challenges are more difficult to solve than others. The dearth of basic information on many tree species and of sharing and management of biological data will require significant effort to overcome. Gardens must unite as a global community to identify the most critical knowledge gaps, coordinate research efforts and share data and results openly. Working with academia and experts from other sectors and establishing collaborative hubs of research and conservation will promote innovative thinking and technological solutions to overcome these problems. Such multidisciplinary collaborations can garner more funding from traditional sources and unlock new funding opportunities from non-traditional sources, such as private corporations and the impact investment market.

An easier limitation to overcome is evolving the collection mentality to be more conservation focused. An important step is prioritizing well-curated, genetically diverse collections of many wild-origin accessions to maximize reintroduction potential. Gardens of all sizes have multiple purposes but more gardens could evolve their missions to include conservation as a core value. There are already frameworks in place (e.g. the Global Strategy for Plant Conservation, the International Agenda for Botanic Gardens in Conservation) that articulate goals, define time lines and guide conservation actions for the international garden community.

Many of the recommendations described here can be implemented by individual gardens but some challenges can only be overcome by gardens working together more effectively. To improve the impact of this global network it is important to empower smaller gardens to participate in conservation action, and to build capacity in gardens in biodiversity hotspots. Networks such as the Global Trees Campaign and ArbNet are already in place to support conservation collaborations within the global garden community and provide a single voice to represent gardens in conservation advocacy. Models of innovative ex situ tree conservation exist for gardens to emulate. Even by taking small steps, such as focusing efforts on one threatened tree species or using living collections to educate the public about global tree conservation issues, gardens of all sizes can contribute significantly to conservation efforts. Because the threats to tree species diversity are complex and global, a coordinated effort is needed to fill knowledge gaps, share information and build global capacity to protect tree species from extinction.

Acknowledgements

We thank everyone who participated in the insightful discussions and interviews, including but not limited to Matthew Albrecht, Pam Allenstein, Kris Bachtell, Dan Beetem, Michael Dosmann, Patrick Griffith, Kunso Kim, Andrea Kramer, Daniel Luscombe, Mark Nicholson, Peter Raven, Mark Richardson, Nigel Taylor, Elango Velautham and Sun Weibang.

Biographical sketches

Nicole Cavender's research interests include ecological restoration, disturbance ecology and conservation biology. Murphy Westwood's interests include ex situ conservation of globally threatened tree species, conservation genetics, and angiosperm evolution. Catherine Bechtoldt's research interests include wildlife ecology and species distributions. Gerard Donnelly's background is forest ecology and he leads The Morton Arboretum's focus on tree conservation and international collaboration. Sara Oldfield's primary research interests are integrated conservation management of threatened tree species and facilitating tree threat assessments. Martin Gardner specializes in conifer species distributions, conservation genetics, and ex situ collections. David Rae's research interests include developing horticultural techniques and living plant collections for conservation purposes. Bill McNamara specializes in the flora of East Asia, focusing on threatened species and ex situ conservation collections.

References

Aitken, S.N., Yeaman, S., Holliday, J.A., Wang, T. & Curtis-McLane, S. (2008) Adaptation, migration or extirpation: climate change outcomes for tree populations. Evolutionary Applications, 1, 95111.Google Scholar
BGCI (Botanic Gardens Conservation International) (2012) International Agenda for Botanic Gardens in Conservation. 2nd edition. Botanic Gardens Conservation International, Richmond, UK.Google Scholar
BGCI (2014a) Building Living Plant Collections to Support Conservation: A Guide for Public Gardens. Botanic Gardens Conservation International, Richmond, UK.Google Scholar
BGCI (2014b) PlantSearch. Http://www.bgci.org/plant_search.php [accessed 25 November 2014].Google Scholar
BGCI (2014c) Progress Report on Target 8 of the Global Strategy for Plant Conservation in the United States. Botanic Gardens Conservation International, Richmond, UK.Google Scholar
Bramwell, D., Hamann, O., Heywood, V. & Synge, H. (eds) (1987) Botanic Gardens and the World Conservation Strategy. Academic Press, Ann Arbor, USA.Google Scholar
CBD (Convention on Biological Diversity) (2012) Global Strategy for Plant Conservation 2011–2020. Botanic Gardens Conservation International, Richmond, UK.Google Scholar
Center for Plant Conservation (2014) Bibliographies. Http://www.centerforplantconservation.org/Bibliographies.asp [accessed 25 November 2014].Google Scholar
Cibrian-Jaramillo, A., Hird, A., Oleas, N., Ma, H., Meerow, A.W., Francisco-Ortega, J. & Griffith, M.P. (2013) What is the conservation value of a plant in a botanic garden? Using indicators to improve management of ex situ collections. The Botanical Review, 79, 559577.Google Scholar
Cires, E., De Smet, Y., Cuesta, C., Goetghebeur, P., Sharrock, S., Gibbs, D. et al. (2013) Gap analyses to support ex situ conservation of genetic diversity in Magnolia, a flagship group. Biodiversity & Conservation, 22, 567590.Google Scholar
Falk, D. (1987) Integrated conservation strategies for endangered plants. Natural Areas Journal, 7, 118123.Google Scholar
Falk, D. & Holsinger, K. (eds) (1991) Genetics and Conservation of Rare Plants. Oxford University Press, Oxford, UK.CrossRefGoogle Scholar
GBIF (Global Biodiversity Information Facility) (2014) Http://www.gbif.org/ [accessed 25 November 2014].Google Scholar
Gill, D., Magin, G. & Bertram, E. (2013) Trees and Climate Change. Fauna & Flora International, Cambridge, UK.Google Scholar
Griffith, P. & Husby, C. (2010) The price of conservation: measuring the mission and its cost. BGJournal, 7, 1214.Google Scholar
Griffith, P., Lewis, C. & Francisco-Ortega, J. (2011) Palm conservation at a botanic garden: a case study of the Keys Thatch Palm. Palms, 55, 93101.Google Scholar
Guerrant, E.O. Jr, Havens, K. & Maunder, M. (eds) (2004) Ex Situ Plant Conservation: Supporting Species Survival in the Wild. Island Press, Washington, DC, USA.Google Scholar
Hird, A. & Kramer, A.T. (2013) Achieving Target 8 of the Global Strategy for Plant Conservation: lessons learned from the North American Collections Assessment. Annals of the Missouri Botanical Garden, 99, 161166.CrossRefGoogle Scholar
iDigBio (Integrated Digitized Biocollections) (2011) Https://www.idigbio.org/ [accessed 25 November 2014].Google Scholar
IUCN (2013) IUCN Red List of Threatened Species v. 2013.2. Http://www.iucnredlist.org [accessed 1 February 2014].Google Scholar
Kramer, A., Hird, A., Shaw, K., Dosmann, M. & Mims, R. (2011) Conserving North America's Threatened Plants: Progress Report on Target 8 of the Global Strategy for Plant Conservation. Botanic Gardens Conservation International U.S., Glencoe, USA.Google Scholar
Li, Y., Chen, X., Zhang, X., Tian-Yi, W., Hui-Ping, L. & Yue-Wei, C. (2005) Genetic differences between wild and artificial populations of Metasequoia glyptostroboides: implications for species recovery. Conservation Biology, 19, 224231.CrossRefGoogle Scholar
Lughadha, E. & Miller, C. (2009) Accelerating global access to plant diversity information. Trends in Plant Science, 14, 622628.Google Scholar
Ma, Y., Chen, G., Grumbine, R.E., Dao, Z., Sun, W. & Guo, H. (2013) Conserving plant species with extremely small populations (PSESP) in China. Biodiversity & Conservation, 22, 803809.CrossRefGoogle Scholar
Maschinski, J. & Haskins, K.E. (eds) (2012) Plant Reintroduction in a Changing Climate. Promises and Perils. Island Press, Washington, DC, USA.Google Scholar
Maunder, M., Guerrant, E.O. Jr, Havens, K. & Dixon, K. (2004) Realizing the full potential of ex situ contributions to global plant conservation. In Ex Situ Plant Conservation: Supporting Species Survivial in the Wild (eds Guerrant, E.O. Jr, Havens, K. & Maunder, M.). Island Press, Washington, DC, USA.Google Scholar
McNamara, W.A. (2011) 708. Acer pentaphyllum . Curtis's Botanical Magazine, 28, 128140.Google Scholar
Namoff, S., Husby, C.E., Francisco-Ortega, J., Noblick, L.R., Lewis, C.E. & Griffith, M.P. (2010) How well does a botanical garden collection of a rare palm capture the genetic variation in a wild population? Biological Conservation, 143, 11101117.Google Scholar
Oldfield, S., Lusty, C. & MacKinven, A. (1998) The World List of Threatened Trees. World Conservation Press, WCMC, Cambridge, UK.Google Scholar
Oldfield, S. & Newton, A. (2012) Integrated Conservation of Tree Species by Botanic Gardens: A Reference Manual. Botanic Gardens Conservation International, Richmond, UK.Google Scholar
Pence, V.C. (2013) In vitro methods and the challenge of exceptional species for Target 8 of the Global Strategy for Plant Conservation. Annals of the Missouri Botanical Garden, 99, 214220.Google Scholar
Pimm, S.L., Jenkins, C.N., Abell, R., Brooks, T.M., Gittleman, J.L., Joppa, L.N. et al. (2014) The biodiversity of species and their rates of extinction, distribution, and protection. Science, 344, 1246752.Google Scholar
Pritchard, D.J., Fa, J.E., Oldfield, S. & Harrop, S.R. (2012) Bring the captive closer to the wild: redefining the role of ex situ conservation. Oryx, 46, 1823.Google Scholar
Roberts, D.L. & Solow, A.R. (2008) The effect of the Convention on International Trade in Endangered Species on scientific collections. Proceedings of the Royal Society B, 275, 987989.Google Scholar
Robinson, D. (2005) Assessing and addressing threats in restoration programmes. In Forest Restoration in Landscapes: Beyond Planting Trees (eds Mansourian, S., Vallauri, D. & Dudley, N.), pp. 7377. Springer, New York, USA.Google Scholar
Samain, M. & Cires, E. (2012) Plants for the future—a future for our planet: towards a protocol for genetic management of ex situ living plant collections. BGJournal, 9, 3.Google Scholar
Figure 0

Table 1 Criteria for prioritizing tree species for ex situ conservation, proposed by Maunder et al. (2004) and experts interviewed for this study.

Figure 1

Table 2 Practical recommendations for botanical gardens and arboreta to improve conservation efforts and increase the value of ex situ tree collections.

Supplementary material: PDF

Cavender supplementary material

Cavender supplementary material

Download Cavender supplementary material(PDF)
PDF 103.6 KB