Predicting the distribution of <Emphasis Type="Italic">Encephalartos latifrons</Emphasis>, a critically endangered cycad in South Africa

This study evaluates how a modelling approach to determine areas of suitable habitat for the Critically Endangered Albany cycad Encephalartos latifrons can assist in systematic conservation planning for this and other rare and threatened cycads. A map distinguishing suitable from unsuitable habitat for E. latifrons was produced and important environmental predictors (climate, geology, topography and vegetation) influencing the suitable habitat were estimated. The maximum entropy (MaxEnt) modelling technique was chosen for this study as it has consistently performed well compared with alternative modelling methods and is also an appropriate model choice when the sample size is small and locality records are relatively few. Predicted habitat suitability showed that some locations chosen for translocation and restoration of E. latifrons specimens are not suitable. This revealed that modelling suitable habitat can guide relocation and regeneration of E. latifrons and perhaps other threatened cycads with restricted distributions and few locality records. The species distribution model constructed for E. latifrons is the first reported habitat model for a Critically Endangered cycad in South Africa. The results may be incorporated into conservation planning and structured decision-making about translocations and restoration programmes involving vulnerable cycads, which are among the most threatened organisms globally.     

Rapid genetic differentiation between ex situ and their in situ source populations: an example of the endangered Silene otites (Caryophyllaceae)

Ex situ cultivation in botanic gardens could be one possibility to preserve plant species diversity and genetic variation. However, old ex situ populations are often sparsely documented. We were able to retrieve three different ex situ populations and their source in situ populations of the endangered plant species Silene otites after 20–36 years of isolation. Furthermore, three additional wild populations were included in the analysis. Population genetic diversity and differentiation were analysed using AFLP markers. Genetic variation in the ex situ populations was lower than the variation found in the in situ populations. Strong differentiation (F_ST = 0.21–0.36) between corresponding in situ and ex situ populations was observed. Bayesian clustering approach also showed a distinct genetic separation between in situ and ex situ populations. The high genetic differentiation and loss of genetic diversity during spatial and temporal isolation in the ex situ populations can be attributable to small population sizes and unconscious selection during cultivation. Therefore, adequate sampling prior to ex situ cultivation and large effective population sizes are important to preserve genetic diversity. Near‐natural cultivation allowing for generation overlap and interspecific competition without artificial selection is recommended as being best for the maintenance of the genetic constitution. © 2011 The Linnean Society of London, Botanical Journal of the Linnean Society, 2011, ??, ??–??.     

Ex situ cultivation affects genetic structure and diversity in arable plants

Worldwide, botanical gardens cultivate around 80,000 taxa, corresponding to approximately one‐quarter of all vascular plants. Most cultivated taxa are, however, held in a small number of collections, and mostly only in small populations. Lack of genetic exchange and stochastic processes in small populations make them susceptible to detrimental genetic effects, which should be most severe in annual species, as sowing cycles are often short. In order to assess whether ex situ cultivation affects genetic diversity of annuals, five annual arable species with similar breeding systems were assessed with 42 in situ populations being compared to 20 ex situ populations using a random amplified polymorphic DNA (RAPD) analysis approach. Population sizes tended to be lower under ex situ cultivation and levels of genetic diversity also tended to be lower in four of the five species, with differences being significant in only two. Ex situ populations showed incomplete representation of alleles found in the wild. The duration of cultivation did not indicate any effect on genetic diversity. This implies that cultivation strategies resulted in different genetic structures in the garden populations. Although not unequivocally pronounced, differences nonetheless imply that conservation strategies in the involved gardens may need improvement. One option is cold storage of seeds, a practice that is not currently followed in the studied ex situ collections. This may reflect that the respective gardens focus on displaying living plant populations.     

Microsatellite markers indicate genetic differences between cultivated and natural populations of endangered Taxus yunnanensis

Taxus yunnanensis (Taxaceae) is an endangered plant known for its effective natural anti‐cancer metabolite, taxol. To assess the effectiveness of T. yunnanensis ex situ conservation in China, the genetic diversity and genetic structure of nine cultivated and 14 natural populations were compared using 11 polymorphic microsatellite markers. The purpose of this comparison was to determine whether the cultivated populations were genetic representatives of natural types. Among the 14 natural populations studied, three were from Tibet and 11 were from the Hengduan Mountains. There were fewer genetic variations among cultivated populations than among natural populations, but this difference was not significant. However, 23 unique alleles were detected in cultivated populations and 14 were detected in natural populations. Striking differences in genetic structure (G_ST = 0.365) was observed between them. STRUCTURE, AMOVA and cluster analyses also consistently showed a clear genetic separation between the 14 natural and seven cultivated populations. Only five natural populations from the south‐central Hengduan Mountains were genetically represented in two cultivated collections. The reason for the occurrence of distinct genetic differences between cultivated and natural populations and the loss of natural population‐specific alleles in the cultivated populations can be attributed to uneven selection during establishment. These results suggest that the genetic structure of T. yunnanensis may not have been conserved effectively. Based on our study, practical conservation strategies for ex situ preservation of T. yunnanensis have been developed. © 2015 The Linnean Society of London, Botanical Journal of the Linnean Society, 2015, 177 , 450–461.     

Genetic diversity in the US ex situ populations of the endangered Puerto Rican Boa,Chilabothrus inornatus

The Puerto Rican Boa (Chilabothrus inornatus) was placed on the US Endangered Species List in 1970. Progress has been made since to clarify the recovery status of this species, though the design of a new recovery plan must include information regarding genetic variation within and among populations of this species. While measures of genetic diversity in wild populations of this species are finally becoming available, relative genetic diversity represented in ex situ populations is unknown, which hampers efforts to develop an ex situ species management plan. Here, we provide an analysis of genetic diversity in US public and private collections (zoos and breeders) using mitochondrial sequence data and five highly polymorphic nuclear microsatellite loci. We analyzed 50 boas from the US ex situ population and determined overall genetic diversity and relatedness among these individuals. We then compared these data to mitochondrial and microsatellite data obtained from 176 individuals from wild populations across the native range of the species. We found little inbreeding and a large amount of retained genetic diversity in the US ex situ population of C. inornatus relative to wild populations. Genetic diversity in the ex situ population is similar to that found in wild populations. Ours is only the second explicit attempt to characterize genetic diversity at the molecular level in ex situ populations of boid snakes. We anticipate that these results will inform current breeding strategies as well as offer additional information that will facilitate the continuation of ex situ conservation breeding or management in boas.     

Ex Situ Conservation Priorities for the Wild Relatives of Potato (Solanum L. Section Petota)

Crop wild relatives have a long history of use in potato breeding, particularly for pest and disease resistance, and are expected to be increasingly used in the search for tolerance to biotic and abiotic stresses. Their current and future use in crop improvement depends on their availability in ex situ germplasm collections. As these plants are impacted in the wild by habitat destruction and climate change, actions to ensure their conservation ex situ become ever more urgent. We analyzed the state of ex situ conservation of 73 of the closest wild relatives of potato (Solanum section Petota) with the aim of establishing priorities for further collecting to fill important gaps in germplasm collections. A total of 32 species (43.8%), were assigned high priority for further collecting due to severe gaps in their ex situ collections. Such gaps are most pronounced in the geographic center of diversity of the wild relatives in Peru. A total of 20 and 18 species were assessed as medium and low priority for further collecting, respectively, with only three species determined to be sufficiently represented currently. Priorities for further collecting include: (i) species completely lacking representation in germplasm collections; (ii) other high priority taxa, with geographic emphasis on the center of species diversity; (iii) medium priority species. Such collecting efforts combined with further emphasis on improving ex situ conservation technologies and methods, performing genotypic and phenotypic characterization of wild relative diversity, monitoring wild populations in situ, and making conserved wild relatives and their associated data accessible to the global research community, represent key steps in ensuring the long-term availability of the wild genetic resources of this important crop.     

A novel framework for evaluating in situ breeding management strategies in endangered populations

Conservation breeding management aims to reduce inbreeding and maximize the retention of genetic diversity in endangered populations. However, breeding management of wild populations is still rare, and there is a need for approaches that provide data-driven evidence of the likelihood of success of alternative in situ strategies. Here, we provide an analytical framework that uses in silico simulations to evaluate, for real wild populations, (i) the degree of population-level inbreeding avoidance, (ii) the genetic quality of mating pairs, and (iii) the potential genetic benefits of implementing two breeding management strategies. The proposed strategies aim to improve the genetic quality of breeding pairs by splitting detrimental pairs and allowing the members to re-pair in different ways. We apply the framework to the wild population of the Critically Endangered helmeted honeyeater by combining genomic data and field observations to estimate the inbreeding (i.e., pair-kinship) and genetic quality (i.e., Mate Suitability Index) of all mating pairs for seven consecutive breeding seasons. We found no evidence of population-level inbreeding avoidance and that ~91.6% of breeding pairs were detrimental to the genetic health of the population. Furthermore, the framework revealed that neither proposed management strategy would significantly improve the genetic quality or reduce inbreeding of the mating pairs in this population. Our results demonstrate the usefulness of our analytical framework for testing the efficacy of different in situ breeding management strategies and for making evidence-based management decisions.     

Conservation genomics in the fight to help the recovery of the critically endangered Siamese crocodile Crocodylus siamensis

Endangered species are often characterized by low genetic diversity and it is imperative for conservation efforts to incorporate the knowledge obtained from genetic studies for effective management. However, despite the promise of technological advances in sequencing, application of genome‐wide data to endangered populations remains uncommon. In the present study we pursued a holistic conservation‐genomic approach to inform a field‐based management programme of a Critically Endangered species, the Siamese crocodile Crocodylus siamensis. Using thousands of single nucleotide polymorphisms from throughout the genome, we revealed signals of introgression from two other crocodile species within our sample of both wild and captive‐bred Siamese crocodiles from Cambodia. Our genetic screening of the Siamese crocodiles resulted in the subsequent re‐introduction of 12 individuals into the wild as well as the selection of four individuals for captive breeding programmes. Comparison of intraspecific genetic diversity revealed an alarmingly low contemporary effective population size in the wild (<50) with evidence of a recent bottleneck around Tonle Sap Lake. We also projected a probable future extinction in the wild (within fewer than five generations) in this population in the absence of re‐introduction efforts. However, an increase in the number of potential breeders through re‐introductions, including the one resulting from this project, could counter this trend. Our results have been implemented in ongoing re‐introduction and captive breeding programmes, with major implications for the conservation management of Siamese crocodiles, and provide a blueprint for the rescue effort of other “terminally ill” populations of critically endangered species.     

Population structure,population history and DNA barcoding of fruit fly Bactrocera latifrons (Hendel) (Diptera: Tephritidae)

The fruit fly Bactrocera latifrons (Hendel) is an important pest of commercially significant plants such as chili, tomato and eggplant. The species is native to South and Southeast Asia, but has now invaded Japan, Hawaii and Africa. In this study, mitochondrial DNA sequences were used to infer genetic structure and demographic history of B. latifrons. The efficiency of DNA barcodes for identification of B. latifrons was also tested. Ninety‐three specimens infesting four host‐plant species were obtained from 11 sampling locations in Thailand. The mitochondrial haplotype network revealed no major divergent lineage, which was consistent with a phylogenetic analysis that found strong support for the monophyly of B. latifrons. Population pairwise F_ST revealed that most (65%) comparisons were not significantly different, suggesting a high rate of gene flow. Analysis of molecular variance (amova ) found no significant genetic differentiation among populations from different host‐plant species. Sharing of several haplotypes among flies from different host‐plants indicates that the flies were moved freely across the plant species. Demographic history analysis revealed that the population has undergone recent expansion dating back to the end of the last glaciation. Thus, the results indicate that both ongoing and historical factors have played important roles in determining the genetic structure and diversity of B. latifrons. DNA barcoding analysis revealed that B. latifrons specimens were clearly differentiated from other species with 100% correct identification. Therefore, cytochrome oxidase I (COI) barcoding sequences could be effectively used to identify this important pest species, which could encourage monitoring and control efforts for this species.     

Reproductive biology and responses to threats and protection measures of the total population of a Critically Endangered Galápagos plant,Linum cratericola (Linaceae)

We describe a reproductive and population dynamic study of the total population of a Critically Endangered plant over 10 years, during which part of the population was protected from the main threat, feral ungulates. Linum cratericola (Linaceae) was first discovered in 1966 at two sites on Floreana Island, Galápagos. It has since disappeared from one site and survives in three groups of plants at the other, where it has been threatened with extinction by introduced ungulates and invasive plants. Population size, and growth rate and mortality of individual plants, have been monitored since 1997. The population appears highly responsive to changes in threat levels: the three plant groups increased rapidly following protection by fencing and ungulate control, but temporarily declined when feral goat pressure increased and during dry periods. Natural factors that may contribute to population limitation include dry years, grazing by native snails and competition from native vascular plants and cryptogams. Linum cratericola has a single flowering period per year and produces abundant seed with 28% germination after scarification, but with no obvious adaptations for long‐distance dispersal. Potential pollinators included the butterfly Leptotes parrhasioides, the hoverfly Toxomerus crockeri and the carpenter bee Xylocopa darwinii, all endemic to Galápagos. The continued survival of L. cratericola in the wild depends on effective protection from introduced herbivores and invasive plants. © 2009 The Linnean Society of London, Botanical Journal of the Linnean Society, 2009, 161 , 89–102.     

Failure of sexual reproduction found in micropropagated critically endangered plants prior to reintroduction: a cautionary tale

Micropropagation is a useful technique for ex situ multiplication and restoration of critically endangered plant species, but the sexual reproductive behaviour of micropropagated plants is seldom evaluated prior to reintroduction. We examined the critically endangered species Rulingia sp. ‘Trigwell Bridge’, with only three remaining plants known in the wild, as a model case to examine this issue. Abnormalities in micropropagated plants of this species related to four floral traits (lengths of sepals, petals and anthers and width of anthers). The number of pollen grains per flower of abnormal individuals was lower than in plants with apparently normal flowers (wild types), but not significantly so (P = 0.068). Pollen viability for the abnormal plant (0.87 ± 0.26%) was significantly lower than for the plants exhibiting wild‐type floral morphology (45.42 ± 4.47%). Experimental manipulations were used to examine the mating behaviour of normal and abnormal plants. The results showed that both male and female reproductive failure was linked to individuals exhibiting abnormal flowering attributes. Such aberrant reproductive performance in a micropropagated rare species predicates caution when using micropropagated plants in reintroduction programmes, highlighting the importance of screening for reproductive normality prior to release of micropropagated plants (especially for critically endangered species where reliance on in vitro propagation methods is often a necessity). © 2011 The Linnean Society of London, Botanical Journal of the Linnean Society, 2011, 165 , 278–284.     

Conservation of threatened relict trees through living <Emphasis Type="Italic">ex situ</Emphasis> collections: lessons from the global survey of the genus <Emphasis Type="Italic">Zelkova</Emphasis> (Ulmaceae)

Maintaining living ex situ collections is one of the key conservation methods in botanic gardens worldwide. Despite of the existence of many other conservation approaches used nowadays, it offers for many endangered plants an important insurance policy for the future, especially for rare and threatened relict trees. The aim of this research was to investigate the global extent of living ex situ collections, to assess and discuss their viability and inform the development of conservation approaches that respond to latest global conservation challenges. We used as a model taxon the tree genus Zelkova (Ulmaceae). The genus includes six prominent Tertiary relict trees which survived the last glaciation in disjunct and isolated refugial regions. Our comprehensive worldwide survey shows that the majority of botanic institutions with Zelkova collections are in countries with a strong horticultural tradition and not in locations of their origin. More importantly, the acutely threatened Zelkova species are not the most represented in collections, and thus safeguarded through ex situ conservation. Less than 20% of the ex situ collections surveyed contain plant material of known wild provenance while the majority (90%) of collections are generally very small (1–10 trees). Botanic gardens and arboreta particularly in regions where iconic relict trees naturally occur should play a vital role in the conservation of these species. The coordination of conservation efforts between gardens has to be enhanced to prioritise action for the most threatened relict trees. Large scale genetic studies should be undertaken, ideally at genus level, in order to verify or clarify the provenance of ex situ collections of relict trees in cultivation. For the most threatened relict tree genera, well-coordinated specialist groups should be created.     

Partnering conservation actions. <Emphasis Type="Italic">Inter situ</Emphasis> solutions to recover threatened species in South West Western Australia

South West Western Australia has a rich endemic flora of global significance. The threats facing this floral diversity are increasing in type, severity and scale, demonstrated by the rising numbers of species threatened with extinction. In particular, the root-rot pathogen Phytophthora cinnamomi is causing widespread destruction, threatening the survival of many of the region’s unique plants. In situ conservation of wild plants is considered the most essential component of a flora conservation program, but the ability to conserve some species adequately is often unachievable in the short term and urgent management intervention is required to prevent extinction. We present data on the status and management of wild populations of four threatened species from the region, including an ex situ program, and describe our efforts to bridge the gap between these two components. Such inter situ conservation recovery work enables monitoring of biological attributes, research into reproductive biology and collection of genetic material for further ex situ conservation, and provides the source of material for future restoration of wild populations.     

Regional diversity,population trends and threat assessment of the weeds of traditional agriculture in Greece

On the basis of extensive field studies throughout Greece and of about 19 500 field and literature records extracted from the Flora Hellenica Database, we provide the first survey of wild plant species of traditional agriculture in Greece (hereafter TA species). For each of the 138 taxa, life form, rareness (on national scale), local abundance (habitat occupancy) and regional restrictedness are given. We infer population trends from the record chronology of the taxa in the Flora Hellenica Database, and we assess the Red List status of the arable plants using IUCN criteria. According to current knowledge, two TA species are presumed Extinct in Greece and seven Critically Endangered. Almost half of the species are threatened, including 46 Vulnerable and 15 Endangered taxa. There is a high proportion of locally distributed taxa among Greek TA species. Distribution patterns show a pronounced south–north gradient, and the unique character of the East Aegean arable flora is revealed. Most arable species are annuals (83%). Perennial herbs, mostly bulbous or tuberous plants (geophytes), account for 17%, and a major proportion of the latter must be considered as threatened at different levels. The chronology of decline of certain TA species is reflected by processes of agricultural intensification and regional urbanization. We suggest conservation measures for the unique arable flora of Greece. To reflect the geographical and ecoregional variation, in situ measures should focus on areas with species‐rich arable fields in all phytogeographical regions of Greece. © 2014 The Linnean Society of London, Botanical Journal of the Linnean Society, 2014, 175 , 607–623.     

Adaptations to Captivity in the Butterfly Pieris brassicae (L.) and the Implications for Ex situ Conservation

Captive breeding has been suggested as a method of conserving many threatened vertebrates, and is increasingly being proposed as a valuable conservation strategy for invertebrates. Potential genetic problems associated with ex situ conservation are widely recognized, but a further issue has received less attention: the possibility that populations will undergo adaptation to the captive environment, rendering them less well adapted to survival in the wild. We investigated six traits related to dispersal and reproduction in a culture of the large white butterfly Pieris brassicae (L.), that had been captive for c. 100–150 generations, and in recently wild stock reared simultaneously in a common environment. Individuals in the captive culture were heavier, with smaller wings and lower wing aspect ratios. Females from the captive culture laid many more eggs in cage experiments, and had higher ovary mass at the time of peak egg production. These differences are consistent with adaptation to captive conditions. Over time, similar evolutionary changes may affect invertebrates reared in ex situ conservation programmes, decreasing the likelihood that these species can be re-established in the wild. Although the timescale over which most vertebrates are likely to adapt to captivity is longer, and the traits involved will be different, invertebrates like P. brassicae may also provide a model of potential problems in long-term ex situ conservation programmes for both invertebrates and vertebrates. We suggest that measures to reduce or slow adaptation to captivity should be introduced alongside measures to reduce deleterious genetic effects in captive populations.     

Contrasting levels of genetic diversity between the historically rare orchid Cypripedium japonicum and the historically common orchid Cypripedium macranthos in South Korea

Many terrestrial orchids are historically rare and occur in small, spatially isolated populations. Theory predicts that such species will harbour low levels of genetic variation within populations and will exhibit a high degree of population genetic divergence, primarily as a result of genetic drift. If the origin of the present‐day populations is relatively recent from the same genetically depauperate source population, a complete lack of genetic differentiation between conspecific populations is expected. If a terrestrial orchid was historically common with moderate or high levels of genetic diversity, but has experienced more recent anthropogenic disturbance as a result of over‐collection, it would still exhibit initial levels of genetic variation within populations and a low degree of genetic divergence between populations. To test these predictions, we examined the genetic diversity in six populations (N = 131) of the historically and currently rare Cypripedium japonicum and in four populations (N = 94) of the historically common but now rare C. macranthos from South Korea. Fourteen putative allozyme loci resolved from eight enzyme systems revealed no variation either within or among populations of C. japonicum, which supports the first prediction. In contrast, populations of C. macranthos harboured high levels of genetic variation (mean percentage of polymorphic loci %P = 46.7; mean expected heterozygosity H_e = 0.185) and exhibited a low degree of population genetic divergence (G_ST = 0.059), supporting the second prediction. The lack of genetic variation both within and among conspecific populations of C. japonicum may suggest that populations originated from the same genetically depauperate ancestral population. The high levels of genetic diversity maintained in populations of C. macranthos suggest that the collection‐mediated decrease in the number of individuals is still too recent for long‐term effects on genetic variation. Based on current demographic and genetic data, in situ and ex situ conservation strategies should be provided to preserve genetic variation and to ensure the long‐term survival of the two species in the Korean Peninsula. © 2009 The Linnean Society of London, Botanical Journal of the Linnean Society, 2009, 160 , 119–129.     

The effectiveness of botanic garden collections in supporting plant conservation: a European case study

Europe has the greatest concentration of botanic gardens in the world, they cultivate extensive collections of plants that include samples of European threatened plant species. This study looks at the effectiveness of these collections in supporting species conservation. A three part study is presented: (1) the results of a survey and assessment of threatened plants in botanic gardens, as defined by the Bern Convention; (2) case studies illustrating current issues in the ex situ management of European threatened plant species; and (3) presentation of policy recommendations on further improving botanic garden contributions to European plant conservation. The survey indicated that of 119 European botanic gardens in 29 European countries, 105 are cultivating 308 of the 573 threatened plant species listed by the Bern Convention. The survey identified 25 botanic gardens in 14 countries undertaking 51 conservation projects focused on 27 Bern listed species. In particular this survey has established that the majority of taxa are held in a small number of collections, dominated by non-wild origin accessions, and are not adequately documented. The majority of specimens in botanic gardens are cultivated out of the range country and not contributing to a specific conservation project. We review the genetic representation and documentation of origin in collections. Existing plant collections contain representatives of populations, now lost in the wild and maintain samples of at least nine European plant taxa identified as 'Extinct in the Wild'. However, inadequate standards of record keeping has compromised the conservation value of many collections. We highlight the dangers of hybridisation and disease in ex situ collections. The results suggest that botanic garden collections are skewed towards horticulturally robust and ornamental species and do not fully reflect priorities as defined by the Bern Convention. Recognising the limitations of traditional botanic garden collections we propose that botanic gardens more effectively utilise their two core competencies, namely scientific horticulture and public display and interpretation. The unique horticultural skills resident in European botanic gardens could be more effectively utilised through the application of horticulture to the management of wild populations.Journal of the Royal Horticultural Society     

Genetic diversity and similarity revealed via molecular analysis among and within an in situ population and ex situ accessions of chiltepín (Capsicum annuum var. glabriusculum)

Molecular analysis of genetic diversity amongand within phenotypically similar wild Capsicum annuum var. glabriusculum(chile) populations revealed geneticdifferences among accessions spread over abroad geographic range. These chiles areregionally known as chiltepíns and are a 50metric ton per year wild harvest for the spiceindustry, as well as a genetic resource forcrop improvement. Understanding geneticvariability in this species providesinformation related to conservation efforts. The objective of this research was to surveygenetic diversity among and within an insitu population and ex situ accessionsof chiltepíns. Random AmplifiedPolymorphic DNA (RAPD) molecular markers wereused to study the genetic structure of an in situ population found at the nothernmostrange of this species and ex situaccessions collected from Mexico and Guatemala. Novel genetic variation was found in both thein situ northern disjunct population, aswell as some ex situ accessions, thussupporting conservation of this species viaboth in situ and ex situ strategies The evidence presented here supports effortsto conserve outlier populations via insitu management practices.     

Population and genetic status of a critically endangered species in Korea, Euchresta japonica (Leguminosae), and their implications for conservation

The conservation status of Euchresta japonica Hook. f. ex Regel in Korea was investigated, with an emphasis on its genetic diversity. From field surveys, we obtained the only locality record for a wild population in Korea, which contained eight individuals. Genotyping was performed using nine microsatellite markers for all 20 remaining individuals, including those in ex situ collections. Among nine microsatellite loci that amplified within this group, five showed polymorphism with low hererozygosities, and a total of 12 multilocus genotypes were detected. Wild-specific alleles were detected in two individuals, and ex situ-specific alleles were detected in six individuals. Five individuals proved to have individual-specific alleles. The Korean population was also distinguished from the previously reported Japanese population by different alleles and higher diversity. To conserve this species more effectively in Korea, we recommend the following: (1) fencing the remaining wild population; (2) no relocation of wild individuals, as nine ex situ plants are already available; (3) complete ex situ conservation of all genetic diversity via clonal propagation of wild individuals; and (4) continuous protection and monitoring of the wild population.     

Conservation genomics of an Australian cycad Cycas calcicola,and the Absence of Key Genotypes in Botanic Gardens

Understanding the genetic diversity of wild populations is fundamental to conserving species in-situ and ex-situ. To aid conservation plans and to inform ex-situ conservation, we examined the genetic diversity of the cycad Cycas calcicola (Cycadaceae). Samples were collected from wild populations in the Litchfield National Park and Katherine regions in the Northern Territory, Australia. Additional samples were obtained from botanic garden plants that were originally collected in the Katherine region, Daly River and Spirit Hills in the Northern Territory, Australia. Using RADseq we recovered 2271 informative genome-wide SNPs, revealing low to moderate levels of gene diversity (uH_e?=?0.037 to 0.135), very low levels of gene flow, and significant levels of inbreeding (mean F_IS?=?0.491). Population structure and multivariate analysis showed that populations fall into two genetic groups (Katherine vs Litchfield?+?Daly River?+?Spirit Hills). Genetic differentiation was twice as high between populations of the Katherine and Litchfield regions (F_ST?~?0.1) compared to within these two regions (F_ST?~?0.05). Increasing population fragmentation together with high levels of inbreeding and very little gene flow are concerning for the future adaptability of this species. The results indicated that the ex-situ collections (1) had significantly lower genetic diversity than the wild populations, and (2) only partly capture the genetic diversity present, particularly because the Litchfield National Park populations are not represented. We recommend that ex-situ collections be expanded to incorporate the genetic diversity found in Litchfield National Park and to increase the number of representatives from Daly River/Spirit Hills, and that in-situ populations from the Katherine and Greater Litchfield regions be conserved as separate management units.