90 research outputs found
Fostering Conservation via an Integrated Use of Conventional Approaches and High-Throughput SPET Genotyping: A Case Study Using the Endangered Canarian EndemicsSolanum lidiiandS. vespertilio (Solanaceae)
[EN] Islands provide unique opportunities to integrated research approaches to study evolution and conservation because boundaries are circumscribed, geological ages are often precise, and many taxa are greatly imperiled. We combined morphological and hybridization studies with high-throughput genotyping platforms to streamline relationships in the endangered monophyletic and highly diverse lineage ofSolanumin the Canarian archipelago, where three endemic taxa are currently recognized. Inter-taxa hybridizations were performed, and morphological expression was assessed with a common-garden approach. Using the eggplant Single Primer Enrichment Technology (SPET) platform with 5,093 probes, 74 individuals of three endemic taxa (Solanum lidii,S. vespertiliosubsp.vespertilio, andS. vespertiliosubsp.doramae) were sampled for SNPs. While morphological and breeding studies showed clear distinctions and some continuous variation, inter-taxon hybrids were fertile and heterotic for vigor traits. SPET genotyping revealed 1,421 high-quality SNPs and supported four, not three, distinct taxonomic entities associated with post-emergence geological, ecological and geographic factors of the islands. Given the lack of barriers to hybridization among all the taxa and their molecular differences, great care must be taken in population management. Conservation strategies must take account of the sexual and breeding systems and genotypic distribution among populations to successfully conserve and restore threatened/endangered island taxa, as exemplified bySolanumon the Canary Islands.This work was supported by funds from project DEMIURGO to the Jardin Botanico Canario "Viera y Clavijo" -Unidad Asociada al CSIC of the Cabildo de Gran Canaria. Consumables and genotyping were funded by the Jardin Botanico Canario "Viera y Clavijo" -Unidad Asociada al CSIC. Participation of authors from Universitat Politecnica de Valencia has been partially funded by the European Union's Horizon 2020 Research and Innovation Programme under the Grant Agreement No. 677379 (G2P-SOL project: Linking genetic resources, genomes, and phenotypes of solanaceous crops). PG was grateful to Universitat Politecnica de Valencia and to Japan Society for the Promotion of Science for their respective Postdoctoral Grants [PAID-10-18 and FY2019-P19105 JSPS Postdoctoral Fellowship for Research in Japan (Standard)].Gramazio, P.; Jaén-Molina, R.; Vilanova Navarro, S.; Prohens Tomás, J.; Marrero, Á.; Caujapé-Castells, J.; Anderson, GJ. (2020). Fostering Conservation via an Integrated Use of Conventional Approaches and High-Throughput SPET Genotyping: A Case Study Using the Endangered Canarian EndemicsSolanum lidiiandS. vespertilio (Solanaceae). Frontiers in Plant Science. 11:1-17. https://doi.org/10.3389/fpls.2020.00757S11711Ablay, G., & Hürlimann, M. (2000). Evolution of the north flank of Tenerife by recurrent giant landslides. Journal of Volcanology and Geothermal Research, 103(1-4), 135-159. doi:10.1016/s0377-0273(00)00220-1Ancochea, E., Fuster, J., Ibarrola, E., Cendrero, A., Coello, J., Hernan, F., … Jamond, C. (1990). Volcanic evolution of the island of Tenerife (Canary Islands) in the light of new K-Ar data. Journal of Volcanology and Geothermal Research, 44(3-4), 231-249. doi:10.1016/0377-0273(90)90019-cAnderson, G. J. (1975). The Variation and Evolution of Selected Species of Solanum Section Basarthrum. Brittonia, 27(3), 209. doi:10.2307/2805892Anderson, G. J., Bernardello, G., & Santos-Guerra, A. (2014). Reproductive biology of Solanum vespertilio (Solanaceae), a zygomorphic, heterantherous, enantiostylous, and andromonoecious rare Canary Islands endemic. Plant Systematics and Evolution, 301(4), 1191-1206. doi:10.1007/s00606-014-1143-4Anderson, G. J., & Levine, D. A. (1982). THREE TAXA CONSTITUTE THE SEXES OF A SINGLE DIOECIOUS SPECIES OF
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Multiplexed-shotgun-genotyping data resolve phylogeny within a very recently derived insular lineage
Premise of the study: Endemic plants on oceanic islands have long served as model systems for studying patterns and processes
of evolution. However, phylogenetic studies of island plants frequently illustrate a decoupling of molecular divergence and
ecological/morphological diversity, resulting in phylogenies lacking the resolution required to interpret patterns of evolution in
a phylogenetic context. The current study uses the primarily Macaronesian fl owering plant genus Tolpis to illustrate the utility
of multiplexed shotgun genotyping (MSG) for resolving relationships at relatively deep (among archipelagos) and very shallow
(within archipelagos) nodes in this small, yet diverse insular plant lineage that had not been resolved with other molecular
markers.
• Methods: Genomic libraries for 27 accessions of Macaronesian Tolpis were generated for genotyping individuals using MSG,
a form of reduced-representation sequencing, similar to restriction-site-associated DNA markers (RADseq). The resulting data
fi les were processed using the program pyRAD, which clusters MSG loci within and between samples. Phylogenetic analyses
of the aligned data matrix were conducted using RAxML.
• Key results: Analysis of MSG data recovered a highly resolved phylogeny with generally strong support, including the fi rst
robust inference of relationships within the highly diverse Canary Island clade of Tolpis .
• Conclusions: The current study illustrates the utility of MSG data for resolving relationships in lineages that have undergone
recent, rapid diversifi cation resulting in extensive ecological and morphological diversity. We suggest that a similar approach
may prove generally useful for other rapid plant radiations where resolving phylogeny has been diffi cult.info:eu-repo/semantics/publishedVersio
The potential role of hybridization in diversification and speciation in an insular plant lineage: insights from synthetic interspecific hybrids
Hybridization is recognized as an important process in plant evolution, and this may be particularly true for island plants where several biotic and abiotic factors facilitate interspecific hybridization. Although rarely done, experimental studies could provide insights into the potential of natural hybridization to generate diversity when species come into contact in the dynamic island setting. The potential of hybridization to generate morphological variation was analysed within and among 12 families (inbred lines) of an F4 hybrid generation between two species of Tolpis endemic to the Canary Islands. Combinations of characters not seen in the parents were present in hybrids. Several floral and vegetative characters were transgressive relative to their parents. Morphometric studies of floral, vegetative and fruit characters revealed that several F4 families were phenotypically distinct from other families, and from their parents. The study demonstrates that morphologically distinct pollen-fertile lines, potentially worthy of taxonomic recognition if occurring in nature, can be generated in four generations. The ability of the hybrid lines to set self-seed would reduce gene flow among the lines, and among the hybrids and their parental species. Selfing would also facilitate the fixation of characters within each of the lines. Overall, the results show the considerable potential of hybridization for generating diversity and distinct phenotypes in island lineages
Diversification of Aeonium Species Across Macaronesian Archipelagos: Correlations Between Genome-Size Variation and Their Conservation Status
The rich endemic flora of the Macaronesian Islands places these oceanic archipelagos
among the top biodiversity hotspots worldwide. The radiations that have determined the
evolution of many of these insular lineages resulted in a wealth of endemic species, many
of which occur in a wide range of ecological niches, but show small distribution areas in
each of them. Aeonium (Crassulaceae) is the most speciose lineage in the Canary Islands
(ca. 40 taxa), and as such can be considered a good model system to understand the
diversification dynamics of oceanic endemic floras. The present study aims to assess the
genome size variation within Aeonium distribution, i.e., the Macaronesian archipelagos
of Madeira, Canaries and Cabo Verde, and analyse it together with information
on distribution (i.e., geography and conservation status), taxonomy (i.e., sections),
morphological traits (i.e., growth-form), geological data (i.e., island’s geological age),
and environmental variables (i.e., altitude, annual mean temperature, and precipitation).
Based on extensive fieldwork, a cytogeographic screening of 24 Aeonium species was
performed. The conservation status of these species was assessed based on IUCN
criteria. 61% of the taxa were found to be threatened (4% Endangered and 57%
Vulnerable). For the first time, the genome size of a comprehensive sample of Aeonium
across the Macaronesian archipelagos was estimated, and considerable differences in
Cx-values were found, ranging from0.984 pg (A. dodrantale) to 2.768 pg (A. gorgoneum).
An overall positive correlation between genome size and conservation status was found,
with the more endangered species having the larger genomes on average. However,
only slight relationships were found between genome size, morphological traits, and environmental variables. These results underscore the importance of characterizing the
cytogenomic diversity and conservation status of endemic plants found in Macaronesian
Islands, providing, therefore, new data to establish conservation priorities.info:eu-repo/semantics/publishedVersio
In defence of the entity of Macaronesia as a biogeographical region
Since its coinage ca. 1850 AD by Philip Barker Webb, the biogeographical region of Macaronesia, consisting of the North Atlantic volcanic archipelagos of the Azores, Madeira with the tiny Selvagens, the Canaries and Cabo Verde, and for some authors different continental coastal strips, has been under dispute. Herein, after a brief introduction on the terminology and purpose of regionalism, we recover the origins of the Macaronesia name, concept and geographical adscription, as well as its biogeographical implications and how different authors have positioned themselves, using distinct terrestrial or marine floristic and/or faunistic taxa distributions and relationships for accepting or rejecting the existence of this biogeographical region. Four main issues related to Macaronesia are thoroughly discussed: (i) its independence from the Mediterranean phytogeographical region; (ii) discrepancies according to different taxa analysed; (iii) its geographical limits and the role of the continental enclave(s), and, (iv) the validity of the phytogeographical region level. We conclude that Macaronesia has its own identity and a sound phytogeographical foundation, and that this is mainly based on three different floristic components that are shared by the Macaronesian core (Madeira and the Canaries) and the outermost archipelagos (Azores and Cabo Verde). These floristic components are: (i) the Palaeotropical‐Tethyan Geoflora, formerly much more widely distributed in Europe and North Africa and currently restricted to the three northern archipelagos (the Azores, Madeira and the Canaries); (ii) the African Rand Flora, still extant in the coastal margins of Africa and Arabia, and present in the southern archipelagos (Madeira, the Canaries and Cabo Verde), and (iii) the Macaronesian neoendemic floristic component, represented in all the archipelagos, a result of allopatric diversification promoted by isolation of Mediterranean ancestors that manage to colonize Central Macaronesia and, from there, the outer archipelagos. Finally, a differentiating floristic component recently colonized the different archipelagos from the nearest continental coast, providing them with different biogeographic flavours
Towards a glacial-sensitive model of island biogeography
Although the role that Pleistocene glacial cycles have played in shaping the present biota of oceanic islands world-wide has long been recognized, their geographical, biogeographical and ecological implications have not yet been fully incorporated within existing biogeographical models. Here we summarize the different types of impacts that glacial cycles may have had on oceanic islands, including cyclic changes in climate, shifts in marine currents and wind regimes and, especially, cycles of sea level change. The latter have affected geographical parameters such as
island area, isolation and elevation. They have also influenced the configurations of archipelagos via island fusion and fission, and cycles of seamount emergence and submergence. We hypothesize that these sea level cycles have had significant impacts on the biogeographical processes shaping oceanic island biotas, influencing the rates and patterns of immigration and extinction and hence species richness. Here we provide a first step toward the development of a glacial-sensitive model of island biogeography, representing the tentative temporal evolution of those biogeographical parameters during the last glacial cycle. From this reasoning we attempt to derive predictions regarding the imprint of sea level cycles on genetic, demographic or biogeographical patterns within remote island biotas
NEXTGENDEM: información genética, geoespacial y supercomputación para mejorar la gestión de especies y espacios en Macaronesia
Project NEXTGENDEM (MAC2/4.6d/236, https://lupus.itccanarias.org/nextgendem/es/) complements multiple research disciplines to provide verified and validated scientific data that help managers make more informed conservation decisions. As a result of the mobilization and enrichment of the sample and data banks of the Jardín Botánico Canario “Viera y Clavijo” -UA CSIC and the Instituto Nacional de Investigação e Desenvolvimento Agrário de Cabo Verde, tools will be developed for the estimation of phylogenetic diversity of the terrestrial endemic flora of these islands, the approximation to the molecular taxonomic identification of samples, phylogenetic reconstruction, and territorial analysis merging biotic and abiotic variables. Our main objective is to organise, analyse and apply the most relevant scientific knowledge to guide in situ and ex situ actions to improve the conservation status of the flora of Gran Canaria (Canary Islands) and Santiago (Cape Verde), although we plan to incorporate other Macaronesian territories in future projectsEl proyecto NEXTGENDEM (MAC2/4.6d/236, https://lupus.itccanarias.org/nextgendem/es/) complementa múltiples disciplinas de investigación para proporcionar datos científicos contrastados y validados que faciliten a los gestores la toma de decisiones de conservación más informadas. A consecuencia de la movilización y el enriquecimiento de los bancos de muestras y datos del Jardín Botánico Canario ¿Viera y Clavijo¿ ¿ UA CSIC y del Instituto Nacional de Investigação e Desenvolvimento Agrário de Cabo Verde, se pondrán a punto herramientas para la estimación de la diversidad filogenética de la flora terrestre insular, la aproximación a la identificación taxonómica molecular de muestras, la reconstrucción de filogenias, y el análisis territorial integrado con variables bióticas y abióticas. Nuestro objetivo principal es organizar, analizar y aplicar el conocimiento científico más relevante para guiar actuaciones in situ y ex situ que mejoren el estado de conservación de las floras de Gran Canaria (Islas Canarias) y Santiago (Cabo Verde), aunque prevemos incorporar otros territorios macaronésicos en futuros proyecto
Historical Isolation versus Recent Long-Distance Connections between Europe and Africa in Bifid Toadflaxes (Linaria sect. Versicolores)
Background: Due to its complex, dynamic and well-known paleogeography, the Mediterranean region provides an ideal framework to study the colonization history of plant lineages. The genus Linaria has its diversity centre in the Mediterranean region, both in Europe and Africa. The last land connection between both continental plates occurred during the Messinian Salinity Crisis, in the late Miocene (5.96 to 5.33 Ma). Methodology/Principal Findings: We analyzed the colonization history of Linaria sect. Versicolores (bifid toadflaxes), which includes c. 22 species distributed across the Mediterranean, including Europe and Africa. Two cpDNA regions (rpl32-trnL UAG and trnK-matK) were sequenced from 66 samples of Linaria. We conducted phylogenetic, dating, biogeographic and phylogeographic analyses to reconstruct colonization patterns in space and time. Four major clades were found: two of them exclusively contain Iberian samples, while the other two include northern African samples together with some European samples. The bifid toadflaxes have been split in African and European clades since the late Miocene, and most lineage and speciation differentiation occurred during the Pliocene and Quaternary. We have strongly inferred four events of post-Messinian colonization following long-distance dispersal from northern Africa to the Iberian Peninsula, Sicily and Greece. Conclusions/Significance: The current distribution of Linaria sect. Versicolores lineages is explained by both ancien
Surviving in isolation: genetic variation, bottlenecks and reproductive strategies in the Canarian endemic Limonium macrophyllum (Plumbaginaceae)
Oceanic archipelagos are typically rich in endemic taxa, because they offer ideal conditions for diversification and speciation in isolation. One of the most remarkable evolutionary radiations on the Canary Islands comprises the 16 species included in Limonium subsection Nobiles, all of which are subject to diverse threats, and legally protected. Since many of them are single-island endemics limited to one or a few populations, there exists a risk that a loss of genetic variation might limit their longterm survival. In this study, we used eight newly developed microsatellite markers to characterize the levels of genetic variation and inbreeding in L. macrophyllum, a species
endemic to the North-east of Tenerife that belongs to Limonium subsection Nobiles. We detected generally low levels of genetic variation over all populations (HT = 0.363), and substantial differentiation among populations (FST = 0.188;RST = 0.186) coupled with a negligible degree of inbreeding (F = 0.042). Obligate outcrossing may have maintained L. macrophyllum relatively unaffected by inbreeding despite the species’ limited dispersal ability and the genetic bottlenecks likely caused by a prolonged history of grazing. Although several factors still constitute a risk for the conservation of L. macrophyllum, the lack of inbreeding and the recent positive demographic trends observed in the populations of this species are factors that favour its future
persistence
Breeding systems in Tolpis (Asteraceae) in the Macaronesian islands: the Azores, Madeira and the Canaries
Plants on oceanic islands often originate from
self-compatible (SC) colonizers capable of seed set by self fertilization. This fact is supported by empirical studies,
and is rooted in the hypothesis that one (or few) individuals
could find a sexual population, whereas two or more would
be required if the colonizers were self-incompatible (SI).
However, a SC colonizer would have lower heterozygosity
than SI colonizers, which could limit radiation and diver sification of lineages following establishment. Limited
evidence suggests that several species-rich island lineages
in the family Asteraceae originated from SI colonizers with
some ‘‘leakiness’’ (pseudo-self-compatibility, PSC) such
that some self-seed could be produced. This study of Tolpis
(Asteraceae) in Macaronesia provides first reports of the
breeding system in species from the Azores and Madeira,
and additional insights into variation in Canary Islands.
Tolpis from the Azores and Madeira are predominately SI
but with PSC. This study suggests that the breeding sys tems of the ancestors were either PSC, possibly from a
single colonizer, or from SI colonizers by multiple dis seminules either from a single or multiple dispersals. Long distance colonists capable of PSC combine the advantages
of reproductive assurance (via selfing) in the establishment
of sexual populations from even a single colonizer with the
higher heterozygosity resulting from its origin from an
outcrossed source population. Evolution of Tolpis on the
Canaries and Madeira has generated diversity in breeding
systems, including the origin of SC. Macaronesian Tolpis is
an excellent system for studying breeding system evolution
in a small, diverse lineage.info:eu-repo/semantics/publishedVersio
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