Relevant bibliographies by topics / Endangered plants Rare plants Orchids Plant conservation

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  2. Dissertations / Theses
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Academic literature on the topic 'Endangered plants Rare plants Orchids Plant conservation'

Author: Grafiati
Published: 4 June 2021
Last updated: 13 February 2022

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Journal articles on the topic "Endangered plants Rare plants Orchids Plant conservation"

1

Karpukhin, M. Y., and A. V. Abramchuk. "The problem of introduction of rare and endangered plants of the middle Urals’ flora." E3S Web of Conferences 176 (2020): 03008. http://dx.doi.org/10.1051/e3sconf/202017603008.

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The problem of gene pool protection of wild plant species has gained a special relevance in modern times. In connection with the growth of population there is an increase in economic activity of human beings and their active influence on nature: wild lands plowing, overpasses plotting, construction of new and widening the boundaries of existing settlements. In addition, intensive harvesting of plants as medicinal, decorative, food, forage, etc is in progress. All this has a negative effect on the condition of wild plants: their stocks are declining, and some species are disappearing at all. A number of plants such as: spring adonis (Adonis vernalis L.), martagon lily [Liliumpilosisculum(Freyn)) Miscz,L.], butterfly orchid [Platantherabifolia(L.) Rchb], PaeoniaanomalaL. , rosewort (Rhodiolarosea L.) in their status, they belong to the group of rare and endangered species, they are listed in the Red Book of the Middle Urals, and their conservation requires introduction. The study found that the species studied are culturally resistant, adapting well to new conditions. During the growth process, they went through all phenological phases, ending the development cycle with the fruiting phase with seed formation. Seeds with high enough sowing properties was provided by martagon lily, for which self-seeding is characteristic; low germination of seeds is noted in Rhodiolarosea L. and Platantherabifolia (L.) Rchb.
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Batty, A. L., K. W. Dixon, M. Brundrett, and K. Sivasithamparam. "Long-term storage of mycorrhizal fungi and seed as a tool for the conservation of endangered Western Australian terrestrial orchids." Australian Journal of Botany 49, no. 5 (2001): 619. http://dx.doi.org/10.1071/bt01029.

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The impact of seed drying, seed storage and development of testing procedures for seed viability assessment was undertaken for a selection of common taxa with congeners that are rare and endangered (Caladenia, Diuris, Pterostylisand Thelymitra). Freshly collected seed showed significantly lower levels of germination compared with seed that had been subjected to drying over silica gel for 24 h. Seed dried over silica gel for 24 h and plunged into liquid nitrogen exhibited a further increase in germination levels. Germination of seed stored at 4, 18 or 22˚C for 1 year was substantially higher than freshly collected seed (4 weeks after dehiscence), but germination was highest overall after storage of dried seed in liquid nitrogen (–196˚C). Mycorrhizal fungi that promote the germination and growth of plants were also successfully preserved in liquid nitrogen. The use of cryoprotectants on fungal isolates had no observable deleterious effects on fungal regeneration. Histochemical staining procedures (tetrazolium, fluorescein diacetate and Evans blue) substantially overestimated seed viability, relative to symbiotic seed germination, for most seed treatments indicating a need for re-evaluation of the effectiveness of staining procedures for testing viability. The implications of the long-term ex situ storage of orchid seed and fungal symbionts for the conservation of endangered orchids is discussed.
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Belogrudova, Inta, Dace Grauda, Lita Lapiņa, Gunta Jakobsone, Daina Roze, Reinis Ornicāns, Oksana Fokina, and Isaak Rashal. "Genetic Diversity of Liparis loeselii in Latvia." Proceedings of the Latvian Academy of Sciences. Section B. Natural, Exact, and Applied Sciences. 72, no. 6 (December 1, 2018): 341–48. http://dx.doi.org/10.2478/prolas-2018-0042.

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Abstract According to the Global Strategy for Plant Conservation, 75% of endangered species should be preserved in ex situ collections till 2020. The genus Liparis has a lot of recognised taxons, but only one species, Liparis loeselii (L.) Rich., grows in Europe. L. loeselii is a rare and endangered orchid species occurring in Europe. In Latvia L. loeselii is classified as the third category of endangered and protected species. To develop the best conservation strategy, the knowledge concerning the genetic differences of protected plants in a particular area is crucial. For this purpose, the genetic diversity of L. loeselii populations from different Latvian habitats was tested. The inter-retrotransposon amplified polymorphism method (iPBS) was used for population genetic diversity evolution. In total, 54 accessions from nine habitats were collected and analysed. L. loeselii leaves have a high content of phenols that reduce the quality of extracted DNA. It was found that the percentage of polymorph loci varied among the populations of L. loeselii growing in different habitats; some of the populations were genetically homogeneous. The genetic diversity levels of L. loeselii populations are related with the population age and the growing conditions.
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Koval, L. V., L. M. Horshkova, L. O. Kuzmenko, O. M. Mehem, L. V. Burchak, and A. S. Polyakova. "Sozological peculiarities of the flora of the Desna Plateau (Ukraine)." Biosystems Diversity 26, no. 1 (February 9, 2018): 34–45. http://dx.doi.org/10.15421/011806.

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According to the goals and objectives of the Global Strategy for Plant Conservation for 2011–2020 studying and monitoring the rare component of regional floras is highly relevant. This article presents the results of a nature conservation study of the flora of the Desna Plateau (Кrolevets’ and Hlukhiv geobotanic region), situated in the northeast part of Ukraine at the border line of two geomorphological regions (the Central Russian Upland and the Polesia-Dnipro lowland) and of two physical-geographical zones (Novhorod-Sivers`ke Polesia and the Sums`ky forest-steppe. In the orographic aspect, the territory is made up of the western spurs of the Central Russian Upland with the dissectioned forms of the relief. The studied area consists of about 4000 km2. Field route studies aimed at compiling floral lists, geobotanical description and herbarizing were conducted in the period 2002–2016. Separate sites of nature conservation interest were re-examined in different seasonal periods. The basis of the annotated summary of the rare species of vascular plant flora is made up by the materials of original research, as well as herbarium (KW) and literary reviews. The complex floristic analysis of the rare component of the regional flora was carried out in cameral conditions, which made it possible to identify the systematic, geographical, ecological, phytocenological and nature conservation structures of the rare species of vascular plant flora in the investigated area. According to the data received, the total number of species of vascular plants endangered by anthropogenic impact is composed of 85 species belonging to 32 families, 54 genera. Among the families, the following predominate: Orchidaceae (14 genera), Asteraceae, Ranunculaceae (8 genera in each), Iridaceae (5), Aspidiaceae, Cyperaceae (4 genera in each). Among the genera, the following predominate – Carex (4 species); Dryopteris, Orchis, Iris, Jurinea – 3 species in each. It was concluded that among the rare species there are plant species of different physical and geographical zones and this corresponds to the ecotone location of the region. Among species at the edge of their range, 14 are on the extreme northern border of their typical range (Linum flavum L., Carex rhizina Blytt ex Lindb., Centaurea ruthenica Lam., Trinia multicaulis Schishk, Aster amellus L., Galatella linosyris (L.) Rchb. f., Stipa tirsa Steven), 7 species are found on the southern border of their range (Cypripedium calceolus L., Pedicularis sceptrum-carolinum L., Parnassia palustris L., Lycopodium annotinum L., 4 species (Anemone nemorosa L., Salix myrsinifolia Salisb., Galanthus nivalis L., Gladiolus imbricatus L. are found on the eastern border of their distribution. The nature conservation structure includes 4 species from the Bern Convention on the Conservation of European Wildlife and Natural Habitats (Dracocephalum ruyschiana L., Pulsatilla patens (L.) Mill s.l., Salvinia natans L., Ostericum palustre (Bess) Bess); 3 species from the supplement to the CITES Convention (Adonis vernalis L., Cypripedium calceolus L., Orchis militaris L.), 27 species from the Red Book of Ukraine (Lilium martagon L., Allium ursinum L., Neottia nidus-avis (L.) Rich, Stipa pennata L.), 49 species from Sumy region rare species list (Clematis recta L., Pulsatilla patens (L.) Mill., Eremogone saxatilis (L.) Ikonn., Drosera rotundifolia L., Pedicularis kaufmannii Pinzg., Carex limosa L., C. umbrosa Host.). In addition, we suggest including into this list Sanquisorba officinalis L., Briza media L., Beckmania eruciformis (L.) Host., Melica nutans L., Coronilla varia L., Salvia nutans L., Scilla siberica Haw., Corydalis solida (L.) Clairv., Valeriana officinalis L., Vincetoxicum hirundinaria Medic., Menyanthes trifoliata L., Hesperis matronalis L., Naumburgia thyrsiflora (L.) Rchb., Thalictrum aquilegifolium L., T. minus L., Verbascum nigrum L., Polygonatum multiflorum (L.) All. It was found that among the rare species of the region mesophytes predominate and they are confined to meadow and forest habitats. To a lesser extent, xeromesophytes and xerophytes of meadow-steppe, as well as hygrophytes and hydrophytes of shoreline and water habitats are represented. The nature reserve fund of the region was analyzed according to the methodology of assessing the nature reserves by botanical value priority criteria. To optimize the region's nature reserve fund, a rationale for creating a landscape reserve of local significance “Zvenyhorods'ky” with a total area of 2,000 hectares was compiled, giving it the status of a regional biodiversity centre.
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Davis, Stephen, and Thomas S. Elias. "Conservation and Management of Rare and Endangered Plants." Kew Bulletin 44, no. 2 (1989): 374. http://dx.doi.org/10.2307/4110815.

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Tiehm, Arnold, and Thomas S. Elias. "Conservation and Management of Rare and Endangered Plants." Brittonia 40, no. 2 (April 1988): 240. http://dx.doi.org/10.2307/2807014.

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Hossain, Mohammad Musharof. "Ex Vitro Seedling Development from In Vitro Rhizome-Like Bodies in Eulophia promensis Lindl.: A New Technique for Orchid Propagation." Journal of Botany 2015 (January 14, 2015): 1–6. http://dx.doi.org/10.1155/2015/207694.

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This communication describes in vitro seed germination, embryo differentiation, and ex vitro seedling production from in vitro rhizome-like bodies of a terrestrial orchid, Eulophia promensis Lindl. Effects of two nutrient media, namely, Murashige and Skoog (MS) and Phytotechnology Orchid Seed Sowing medium (P723) supplemented with 6-benzylaminopurine (BAP; 0.5–1.0 mgL−1) and/or α-naphthalene acetic acid (NAA; 0.5–1.0 mgL−1) and activated charcoal (2.0 gL−1), were studied on seed germination and subsequent development of embryos. Maximum seed germination (100%) was recorded in P723 medium fortified with 1.0 mgL−1 BAP + 2.0 gL−1 activated charcoal. The different developmental stages of protocorm morphogenesis were traced out. In subsequent subcultures, the protocorms proliferated profusely and developed rhizome-like bodies (RLBs) with numerous hair-like structures. These RLBs were transferred to pots containing potting mixture composed of humus + coir dust + saw dust (1 : 1 : 1) where ∼80% of RLBs survived and produced 1–3 seedlings per RLB. This is the first time report for in vitro germination of seeds and ex vitro seedling production from in vitro raised RLBs in Eulophia promensis. This is a time saving and cost effective protocol that could be extended to other economically important, rare, and endangered orchids for propagation and conservation.
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Saw, L. G., L. S. L. Chua, M. Suhaida, W. S. Y. Yong, and M. Hamidah. "Conservation of some rare and endangered plants from Peninsular Malaysia." Kew Bulletin 65, no. 4 (December 2010): 681–89. http://dx.doi.org/10.1007/s12225-011-9251-6.

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Dimitrov, D., and V. Vutov. "BIODIVERSITY OF PLANTS AND NATURAL HABITATS IN THE VICINITIES OF ARAPYA BAY, ROPOTAMO NATURAL RESERVE, ALEPU BEACH, SINEMORETS AND SILISTAR CAPE (BULGARIAN SOUTHERN BLACK SEA COAST)." Trakia Journal of Sciences 17, no. 4 (2019): 358–60. http://dx.doi.org/10.15547/tjs.2019.04.011.

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The flora in the vicinities of Arapya Bay, Alepu beach, Sinemorets and Silistar cape of the Bulgarian Black Sea coast (which includes three beach zones and two protected natural areas) is rich in rare psammophytic and halophytic species: Hypecoum ponticum Velen., Pancratium maritimum L., Silene thymifolia Sm., Eryngium maritimum L., Limonium latifolium (Sm.) Kuntze, Tulipa thracica Davidov, Centaurea arenaria M. Bieb., Trachomitum venetum (L.) Woodson and Maresia nana (DC.) Batt. Within these areas some Mediterranean geo elements reach their northernmost point: Reichardia picroides (L.) Roth and Romulea linaresii Parl. All of the species mentioned above have been included in the Red List of Bulgarian vascular plants (1) The Tulipa thracica Davidov species fall under a Critically Endangered (CR) category. Nine species have an Endangered (EN) status: Hypecoum ponticum Velen., Pancratium maritimum L., Silene thymifolia Sm., Eryngium maritimum L., Trachomitum venetun (L.) Woodson, Reichardia picroides (L.) Roth, Cistus salviifolius L., Verbascum bugulifolium Lam. and Serapias vomeracea (Burm.) Briq. Six species fall under a Vulnerable (VU) category: Limonium latifolium (Sm.) Kuntze, Centaurea arenaria M. Bieb., Maresia nana (DC.) Batt. and Romulea linaresii Parl., Limodorum abortivum (L.) Schwarz and Orchis papilionacea L. Under a Least Concern (LC) are the following species: Fritillaria pontica Wahlenb. and Mespilus germanica L. Legally protected by (2) are: Pancratium maritimum L., Eryngium maritimum L., Limonium latifolium (Sm.) Kuntze, Tulipa thracica Davidov, Centaurea arenaria M. Bieb., Trachomitum venetum (L.) Woodson, Maresia nana (DC.) Batt, Reichardia picroides (L.) Roth, Romulea linaresii Parl., Verbascum bugulifolium Lam., Cistus salviifolius L., Serapias vomeracea (Burm.) Briq., Limodorum abortivum (L.) Schwarz, Orchis papilionacea L., Fritillaria pontica Wahlenb. In addition, there are five species from the Orchidaceae family with different conservation status: the Endangered Serapias vomeracea (Burm.) Briq., the Vulnerable Limodorum abortivum (L.) Schwarz and Orchis papilionacea L. and two species from the CITES convention - Orchis purpurea Huds.and Orchis morio L. Three habitats were with an Endangered Conservation status: 01B1 Pontic sand beach annual communities, 02B1 Pontic embryonic dunes and 04B1 Southwestern Pontic fixed dunes (3).
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Wu, Jianrong, Huancheng Ma, Mei Lü, Sufen Han, Youyong Zhu, Hui Jin, Junfeng Liang, Li Liu, and Jianping Xu. "Rhizoctonia fungi enhance the growth of the endangered orchid Cymbidium goeringii." Botany 88, no. 1 (January 2010): 20–29. http://dx.doi.org/10.1139/b09-092.

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Orchids are among the most prized ornamental plants in many societies throughout the world. As a result, consumer demands have created a significant pressure on wild populations of many species, including Cymbidium goeringii Rchb. f., a rare terrestrial orchid endemic in China, Korea, and Japan. To help conserve natural populations of C. goeringii, we recently started investigating methods to cultivate these orchids. Here we fulfilled Koch’s postulates and demonstrated that fungal strains isolated from the roots of natural Cymbidium plants increased fresh mass, plant height, number of leaves, and root length of C. goeringii, and that the two fungal strains originally isolated from C. goeringii showed overall greater effects on growth than two other strains from other Cymbidium species. Internal transcribed spacer sequence analyses revealed that the four fungal strains likely represented at least two new taxonomic groups, both belonging to the family Ceratobasidiaceae of the Rhizoctonia fungi. Our study demonstrated that these fungal strains could potentially help the commercial cultivation of the increasingly rare and endangered orchid C. goeringii.
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Dissertations / Theses on the topic "Endangered plants Rare plants Orchids Plant conservation"

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Swarts, Nigel. "Integrated conservation of the rare and endangered terrestrial orchid Caladenia huegelii H.G. Reichb /." Connect to this title, 2007. http://theses.library.uwa.edu.au/adt-WU2008.0044.

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Swarts, Nigel. "Integrated conservation of the rare and endangered terrestrial orchid Caladenia huegelii H.G. Reichb." University of Western Australia. School of Earth and Geographical Sciences, 2008. http://theses.library.uwa.edu.au/adt-WU2008.0044.

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The Orchidaceae is characterized by a remarkably diverse range of life forms and some of the most highly specialized interactions with soil fungi and insect pollinators found in the flowering plants. Many species are rare or threatened with extinction either directly through loss of habitat or over-collection or, indirectly through debilitation or loss of mycorrhizal association or pollinator capacity. Australian temperate terrestrial orchids represent one of the most threatened groups in the Australian flora with many taxa clinging to existence in urban and rural bushland remnants, road verges and unprotected bushland. The aim of this study is to research and develop integrated conservation based on critical aspects of terrestrial orchid biology and ecology, towards the recovery of the rare and endangered Western Australian terrestrial orchid Caladenia huegelii. This study identified key aspects involved in an integrated conservation approach and research focused on conservation genetics, mycorrhizal interactions and in situ and ex situ conservation strategies for this species. Using polymorphic microsatellite molecular markers, high levels of genetic diversity were found within remnant populations of C. huegelii, while weak differentiation was observed among populations over the species geographic range. These results indicate historic genetic exchange between C. huegelii populations, a possible consequence of the sexually deceptive pollination strategy and the capacity for widespread seed dispersal. Symbiotic germination studies revealed compatibility barriers to C. huegelii germination with the orchid possessing a highly specific orchid-mycorrhizal association relative to common sympatric congeners. These results were reflected in a phylogenetic analysis of DNA sequences, revealing C. huegelii associates with only one endophyte species within the fungal family Sebacinaceae across its geographic range. Large scale in situ seed baiting demonstrated that endophytes compatible with C. huegelii were limited in distribution relative to common and widespread orchid species, a feature for C. huegelii that may be a major contributing factor in limiting the distributional range of the species. Detailed, within site seed baiting methods identified hotspots for mycorrhizal fungus compatible with C. huegelii that were unoccupied by the orchid. These mycorrhizal hotspots where used to investigate the effect of endophyte presence on survival of transplanted mature plants and seedling outplants. The in situ survival of glasshouse propagated seedlings was further optimized by incubating seedlings in growth containers before transfer to soil and outplanting seedlings in their second growing season. The findings of this study will substantially advance the recovery of C. huegelii and provide benchmark knowledge for similar projects with other rare and threatened terrestrial orchid species.
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Swart, Carin. "Life history, population dynamics and conservation status of Oldenburgia grandis (Asteraceae), an endemic of the Eastern Cape of South Africa." Thesis, Rhodes University, 2008. http://hdl.handle.net/10962/d1003799.

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Oldenburgia grandis is a rare, long-lived woody paleoendemic of the Fynbos Biome of South Africa. Confined to quartzite outcrops, it has a small geographic range and narrow habitat specificity. O. grandis responds to its fire-prone environment by resprouting. Elasticity analysis of O. grandis reveals that growth and fecundity were traded off for persistence of adult, mature and sapling stages. Morphological adaptations such as a corky fire-resistant bark and the ability to resprout after fire are traits that O. grandis have evolved to persist in a frequently disturbed environment. Population growth rate for sites undisturbed by fire for a number of years (l = 1.01) and sites at various stages of recovery after fire (l = 1.00) were very similar. The highest variation in transition probabilities for all sites was seen in the persistence of the seedling stage and growth from seedling to sapling. Observed population structure and stable stage distribution determined by the matrix model show that sites recently undisturbed by fire had high abundances of the adult and sapling stages. A peak in sapling stages was seen for the stable stage distribution where similar peak in sapling numbers were seen for population structures of sites at various stages of recoveryafter fire. Favourable environmental conditions for the persistence of O. grandis populations include no fire with transition probabilities between the observed minimum and maximum and fire frequency at a 10 year interval where seedling protection from the fire is high and adult and mature mortalities during the fire are low. Stochastic environmental events that could put populations (particularly small populations) at an increased risk of extinction include high to moderate fire intensities where seedling protection from the fire is low and adult and mature mortalities are high as a result of the fire.
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Parsons, Kimberley A. "Reproductive biology and floral variation in the endangered Braya longii and threatened B. fernaldii (Brassicaceae) : implications for conservation management of rare plants /." 2002.

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Books on the topic "Endangered plants Rare plants Orchids Plant conservation"

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Landau, Elaine. Endangered plants. New York: Watts, 1992.

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Southwestern Rare and Endangered Plant Conference (1992 Santa Fe, N.M.). Southwestern rare and endangered plants: Proceedings of the Southwestern Rare and Endangered Plant Conference. Santa Fe, N.M. (P.O. Box 1948, Santa Fe, 87504): New Mexico Forestry and Resources Conservation Division, Energy, Minerals and Natural Resources Dept., 1993.

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Recovery plan for the Molokai plant cluster. Portland, Or: U.S. Fish and Wildlife Service, 1996.

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U.S. Fish and Wildlife Service. Region 1. Recovery plan for the Molokai plant cluster. Portland, Or: U.S. Fish and Wildlife Service, 1996.

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Juvik, James O. Endangered plants and threatened ecosystems on the island of Hawaiʻi. Hilo, Hawaiʻi: Petroglyph Press, 2008.

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Symposium, Southern California Botanists. Endangered plant communities of Southern California: Proceedings of the 15th annual symposium. Claremont, CA: Southern California Botanists (Rancho Santa Ana Botanic Gardens, 1500 N. College Ave., Claremont, CA 91711), 1990.

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Rao, T. A. Conservation of wild orchids of Kodagu in the Western Ghats. [Bangalore: Centre for Technology Development], 1998.

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Lambelet-Haueter, Catherine. Conservation des plantes vasculaires du canton de Genève: Espèces et sites prioritaires. [Genève]: Conservatoire et jardin botaniques de la ville de Genève, 2011.

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Swenson, Chris. Recovery plan for three plant species on Nihoa Island: Technical/agency draft. Portland, Or: U.S. Fish and Wildlife Service, 1997.

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Miasek, Meryl A. Endangered plant species of the world and their endangered habitats: A compilation of the literature. Bronx, N.Y: New York Botanical Garden Library, 1985.

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Book chapters on the topic "Endangered plants Rare plants Orchids Plant conservation"

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Liu, Hong, and Jiangyun Gao. "Orchid Conservation Translocation Efforts in China." In Conservation and Reintroduction of Rare and Endangered Plants in China, 205–24. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-5301-1_19.

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Gao, Jiangyun, Xuli Fan, and Wenke Yang. "Reintroduction and Assisted Colonization of Paphiopedilum spicerianum: An Orchid with Extremely Small Populations in China." In Conservation and Reintroduction of Rare and Endangered Plants in China, 199–204. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-5301-1_18.

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Qin, Haining, Xiaohua Jin, and Ke Guo. "An Overview of China’s Vegetation and Plant Diversity." In Conservation and Reintroduction of Rare and Endangered Plants in China, 3–19. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-5301-1_1.

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Sun, Weibang, Fengrong Li, and Yuan Zhou. "Reintroduction of Trigonobalanus doichangensis, a Threatened Plant Species with Extremely Small Populations." In Conservation and Reintroduction of Rare and Endangered Plants in China, 167–74. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-5301-1_13.

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Zeng, Songjun, Hai Ren, Longna Li, and Kunlin Wu. "Reintroduction of Tigridiopalma magnifica C. Chen, a Critically Endangered Endemic Plant in China." In Conservation and Reintroduction of Rare and Endangered Plants in China, 125–31. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-5301-1_7.

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Yu, Daoping, Xiangying Wen, and Cehong Li. "The Reintroduction of Parakmeria omeiensis Cheng, a Critically Endangered Endemic Plant, in Southwest China." In Conservation and Reintroduction of Rare and Endangered Plants in China, 151–58. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-5301-1_11.

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Ren, Hai, Hongxiao Liu, Qianmei Zhang, Yi Xu, Ju Zhou, and Yan Zeng. "Reintroduction of Camellia changii Ye (Theaceae), a Critically Endangered Plant Endemic to Southern China." In Conservation and Reintroduction of Rare and Endangered Plants in China, 133–37. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-5301-1_8.

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Zang, Runguo, Yi Ding, Jihong Huang, and Yue Xu. "Reintroduction of Hopea hainanensis Merr. and Chun, a Wild Plant with Extremely Small Populations, in Southern China." In Conservation and Reintroduction of Rare and Endangered Plants in China, 159–65. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-5301-1_12.

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"Conservation of the Rare and Endangered Plants Endemic to Spain." In Plant Conservation Biotechnology, 277–90. CRC Press, 1999. http://dx.doi.org/10.1201/9781482273038-24.

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Cheng, Ma, Lin Zhong-Ping, and Hong De-Yuan. "THE STATUS OF RARE AND ENDANGERED PLANTS IN CHINA AND EFFORTS FOR THEIR PROTECTION." In Conservation of Plant Genes, 247–55. Elsevier, 1992. http://dx.doi.org/10.1016/b978-0-12-044140-2.50021-1.

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