Search

Your search keyword '"Creedy, Thomas J."' showing total 44 results
Start Over Author "Creedy, Thomas J."
44 results on '"Creedy, Thomas J."'

4. Phylogenetic origin of an insect fauna at the boundary of the Palaearctic and Oriental realms: Evidence from 'site‐based' mitogenomics.

Author

Nie, Rui‐E, Li, Lu‐Lu, Feijó, Anderson, Yang, Mei‐Xia, Bai, Ming, Creedy, Thomas J., Jin, Xu, Hao, Jia‐Sheng, Ruan, Yong‐Ying, Liu, Hua‐Xi, Garner, Beulah H., Bocak, Ladislav, Yang, Xing‐Ke, and Vogler, Alfried P.

Subjects
BIOLOGICAL classification, PALEARCTIC, MITOCHONDRIAL DNA, BIOGEOGRAPHY, PHYLOGEOGRAPHY, SPECIES distribution, AQUATIC invertebrates
Abstract

Aim: Knowledge of taxonomy and species distributions in highly diverse lineages of invertebrates remains too incomplete for the study of biogeographical patterns at the global scale. This limits the understanding of processes leading to the formation and maintenance of boundaries between major biogeographical realms. Site‐based metagenomic approaches may provide an alternative source of data for inference of historical processes of in situ speciation and interchange among biogeographical regions. We applied the methodology to explore the historical biogeography of the Qinling Mountains at the boundary of the Oriental and Palaearctic regions. Location: The focal area in the Qinling Mountains; sites in Borneo, Panama, and Spain, representing the Oriental, Neotropical and Palaearctic faunas. Time Period: Contemporary. Major Taxa Studied: Chrysomelidae, a group of ~40,000 species with worldwide distribution. Methods: Mass‐trapped insects were subjected to deep Illumina DNA sequencing and mitochondrial genome assembly, followed by phylogenetic analysis and historical biogeographical inference on a dated tree. The methodology produced 622 mitogenomes (304 newly sequenced) each representing a morphologically distinct species. Results: Ancestral area reconstruction revealed that the Qinling fauna is a composite of distinct clades that, respectively, have Oriental or Palaearctic ancient origins, while in situ speciation and local clade formation were limited. The global diversity of Chrysomelidae consists of regionalised deep clades at the level of the major zoogeographic realms, which remain recognisable where these realms abut in the Qinling mountains. Yet, the Qinling fauna is clearly distinct from the source areas although local lineage ages are generally <20 Ma. Main Conclusions: The Qinling fauna is a composite of clades that have either Oriental or Palaearctic origin, indicating the important role of immigration at the realm boundary. Global site‐based phylogenetic analyses based on metagenomic sequencing can address previously intractable questions about the historical biogeography of poorly studied groups even without a fully developed taxonomy. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

5. The taxonomic composition and chronology of a museum collection of Coleoptera revealed through large-scale digitisation.

Author

Garner, Beulah H., Creedy, Thomas J., Allan, Elizabeth L., Crowther, Robyn, Devenish, Elizabeth, Kokkini, Phaedra, Livermore, Laurence, Lohonya, Krisztina, Lowndes, Nicola, Wing, Peter, Vogler, Alfried P., Ahrens, Dirk, and Lewthwaite, Jayme

Subjects
NATURAL history, NATURAL history museums, LITERARY sources, CURATORSHIP, BIOGEOGRAPHY
Abstract

Introduction: Historic museum collections hold a wealth of biodiversity data that are essential to our understanding of the rapidly changing natural world. Novel curatorial practices are needed to extract and digitise these data, especially for the innumerable pinned insects whose collecting information is held on small labels. Methods: We piloted semi-automated specimen imaging and digitisation of specimen labels for a collection of ~29,000 pinned insects of ground beetles (Carabidae: Lebiinae) held at the Natural History Museum, London. Raw transcription data were curated against literature sources and non-digital collection records. The primary data were subjected to statistical analyses to infer trends in collection activities and descriptive taxonomy over the past two centuries. Results: This work produced research-ready digitised records for 2,546 species (40% of known species of Lebiinae). Label information was available on geography in 91% of identified specimens, and the time of collection in 39.8% of specimens and could be approximated for nearly all specimens. Label data revealed the great age of this collection (average age 91.4 years) and the peak period of specimen acquisition between 1880 and 1930, with little differences among continents. Specimen acquisition declined greatly after about 1950. Early detected species generally were present in numerous specimens but were missing records from recent decades, while more recently acquired species (after 1950) were represented mostly by singleton specimens only. The slowing collection growth was mirrored by the decreasing rate of species description, which was affected by huge time lags of several decades to formal description after the initial specimen acquisition. Discussion: Historic label information provides a unique resource for assessing the state of biodiversity backwards to pre-industrial times. Many species held in historical collections especially from tropical super-diverse areas may not be discovered ever again, and if they do, their recognition requires access to digital resources and more complete levels of species description. A final challenge is to link the historical specimens to contemporary collections that are mostly conducted with mechanical trapping of specimens and DNA-based species recognition. [ABSTRACT FROM AUTHOR]

Published
2024
Full Text
View/download PDF

10. Towards a genetic theory of island biogeography: Inferring processes from multidimensional community-scale data

Author

Overcast, Isaac, Achaz, Guillaume, Aguilée, Robin, Andújar, Carmelo, Arribas, Paula, Creedy, Thomas J., Economo, Evan P., Etienne, Rampal S., Gillespie, Rosemary, Jacquet, Claire, Jay, Flora, Kennedy, Susan, Krehenwinkel, Henrik, Lambert, Amaury, Meramveliotakis, Emmanouil, Noguerales, Victor, Perez-Lamarque, Benoit, Roderick, George, Rogers, Haldre, Ruffley, Megan, Sanmartín, Isabel, Vogler, Alfried P., Papadopoulou, Anna, Emerson, Brent C., Morlon, Hèléne, Overcast, Isaac, Achaz, Guillaume, Aguilée, Robin, Andújar, Carmelo, Arribas, Paula, Creedy, Thomas J., Economo, Evan P., Etienne, Rampal S., Gillespie, Rosemary, Jacquet, Claire, Jay, Flora, Kennedy, Susan, Krehenwinkel, Henrik, Lambert, Amaury, Meramveliotakis, Emmanouil, Noguerales, Victor, Perez-Lamarque, Benoit, Roderick, George, Rogers, Haldre, Ruffley, Megan, Sanmartín, Isabel, Vogler, Alfried P., Papadopoulou, Anna, Emerson, Brent C., and Morlon, Hèléne

Abstract

Background: MacArthur and Wilson's theory of island biogeography has been a foundation for obtaining testable predictions from models of community assembly and for developing models that integrate across scales and disciplines. Historically, however, these developments have focused on integration across ecological and macroevolutionary scales and on predicting patterns of species richness, abundance distributions, trait data and/or phylogenies. The distribution of genetic variation across species within a community is an emerging pattern that contains signatures of past population histories, which might provide an historical lens for the study of contemporary communities. As intraspecific genetic diversity data become increasingly available at the scale of entire communities, there is an opportunity to integrate microevolutionary processes into our models, moving towards development of a genetic theory of island biogeography. Motivation/goal: We aim to promote the development of process-based biodiversity models that predict community genetic diversity patterns together with other community-scale patterns. To this end, we review models of ecological, microevolutionary and macroevolutionary processes that are best suited to the creation of unified models, and the patterns that these predict. We then discuss ongoing and potential future efforts to unify models operating at different organizational levels, with the goal of predicting multidimensional community-scale data including a genetic component. Main conclusions: Our review of the literature shows that despite recent efforts, further methodological developments are needed, not only to incorporate the genetic component into existing island biogeography models, but also to unify processes across scales of biological organization. To catalyse these developments, we outline two potential ways forward, adopting either a top-down or a bottom-up approach. Finally, we highlight key ecological and evolutionary questions t

Published
2023

11. Collective and harmonized high throughput barcoding of insular arthropod biodiversity: Toward a Genomic Observatories Network for islands

Author

European Commission, Emerson, Brent C., Borges, Paulo A. V., Cardoso, Pedro, Convey, Peter, deWaard, Jeremy R., Economo, Evan P., Gillespie, Rosemary G., Kennedy, Susan, Krehenwinkel, Henrik, Meier, Rudolf, Roderick, George K., Strasberg, Dominique, Thébaud, Christophe, Traveset, Anna, Creedy, Thomas J., Meramveliotakis, Emmanouil, Noguerales, Víctor, Overcast, Isaac, Morlon, Hélène, Papadopoulou, Anna, Vogler, Alfried P., Arribas, Paula, Andújar, Carmelo, European Commission, Emerson, Brent C., Borges, Paulo A. V., Cardoso, Pedro, Convey, Peter, deWaard, Jeremy R., Economo, Evan P., Gillespie, Rosemary G., Kennedy, Susan, Krehenwinkel, Henrik, Meier, Rudolf, Roderick, George K., Strasberg, Dominique, Thébaud, Christophe, Traveset, Anna, Creedy, Thomas J., Meramveliotakis, Emmanouil, Noguerales, Víctor, Overcast, Isaac, Morlon, Hélène, Papadopoulou, Anna, Vogler, Alfried P., Arribas, Paula, and Andújar, Carmelo

Abstract

Current understanding of ecological and evolutionary processes underlying island biodiversity is heavily shaped by empirical data from plants and birds, although arthropods comprise the overwhelming majority of known animal species, and as such can provide key insights into processes governing biodiversity. Novel high throughput sequencing (HTS) approaches are now emerging as powerful tools to overcome limitations in the availability of arthropod biodiversity data, and hence provide insights into these processes. Here, we explored how these tools might be most effectively exploited for comprehensive and comparable inventory and monitoring of insular arthropod biodiversity. We first reviewed the strengths, limitations and potential synergies among existing approaches of high throughput barcode sequencing. We considered how this could be complemented with deep learning approaches applied to image analysis to study arthropod biodiversity. We then explored how these approaches could be implemented within the framework of an island Genomic Observatories Network (iGON) for the advancement of fundamental and applied understanding of island biodiversity. To this end, we identified seven island biology themes at the interface of ecology, evolution and conservation biology, within which collective and harmonized efforts in HTS arthropod inventory could yield significant advances in island biodiversity research.

Published
2023

12. Collective and harmonized high throughput barcoding of insular arthropod biodiversity: Toward a Genomic Observatories Network for islands

Author

Emerson, Brent C., Borges, Paulo A.V., Cardoso, Pedro, Convey, Peter, deWaard, Jeremy R., Economo, Evan P., Gillespie, Rosie, Kennedy, Susan, Krehenwinkel, Henrik, Meier, Rudolf, Roderick, George, Strasberg, Dominique, Thébaud, Christophe, Traveset, Anna, Creedy, Thomas J., Meramveliotakis, Emmanouil, Noguerales, Víctor, Overcast, Isaac, Morlon, Hélène, Papadopoulou, Anna, Vogler, Alfried P., Arribas, Paula, Andújar, Carmelo, Emerson, Brent C., Borges, Paulo A.V., Cardoso, Pedro, Convey, Peter, deWaard, Jeremy R., Economo, Evan P., Gillespie, Rosie, Kennedy, Susan, Krehenwinkel, Henrik, Meier, Rudolf, Roderick, George, Strasberg, Dominique, Thébaud, Christophe, Traveset, Anna, Creedy, Thomas J., Meramveliotakis, Emmanouil, Noguerales, Víctor, Overcast, Isaac, Morlon, Hélène, Papadopoulou, Anna, Vogler, Alfried P., Arribas, Paula, and Andújar, Carmelo

Abstract

Current understanding of ecological and evolutionary processes underlying island biodiversity is heavily shaped by empirical data from plants and birds, although arthropods comprise the overwhelming majority of known animal species, and as such can provide key insights into processes governing biodiversity. Novel high throughput sequencing (HTS) approaches are now emerging as powerful tools to overcome limitations in the availability of arthropod biodiversity data, and hence provide insights into these processes. Here we explore how these tools might be most effectively exploited for comprehensive and comparable inventory and monitoring of insular arthropod biodiversity. We first review the strengths, limitations and potential synergies among existing approaches of high throughput barcode sequencing. We consider how this can be complemented with deep learning approaches applied to image analysis to study arthropod biodiversity. We then explore how these approaches can be implemented within the framework of an island Genomic Observatories Network (iGON) for the advancement of fundamental and applied understanding of island biodiversity. To this end, we identify seven island biology themes at the interface of ecology, evolution and conservation biology, within which collective and harmonised efforts in HTS arthropod inventory could yield significant advances in island biodiversity research.

Published
2023

13. Inferring the ecological and evolutionary determinants of community genetic diversity

Author

Agencia Estatal de Investigación (España), European Commission, Overcast, Isaac, Noguerales, Víctor, Meramveliotakis, Emmanouil, Andújar, Carmelo, Arribas, Paula, Creedy, Thomas J., Emerson, Brent C., Vogler, Alfried P., Papadopoulou, Anna, Morlon, Hélène, Agencia Estatal de Investigación (España), European Commission, Overcast, Isaac, Noguerales, Víctor, Meramveliotakis, Emmanouil, Andújar, Carmelo, Arribas, Paula, Creedy, Thomas J., Emerson, Brent C., Vogler, Alfried P., Papadopoulou, Anna, and Morlon, Hélène

Abstract

Understanding the relative contributions of ecological and evolutionary processes to the structuring of ecological communities is needed to improve our ability to predict how communities may respond to future changes in an increasingly human-modified world. Metabarcoding methods make it possible to gather population genetic data for all species within a community, unlocking a new axis of data to potentially unveil the origins and maintenance of biodiversity at local scales. Here, we present a new eco-evolutionary simulation model for investigating community assembly dynamics using metabarcoding data. The model makes joint predictions of species abundance, genetic variation, trait distributions and phylogenetic relationships under a wide range of parameter settings (e.g. high speciation/low dispersal or vice versa) and across a range of community states, from pristine and unmodified to heavily disturbed. We first demonstrate that parameters governing metacommunity and local community processes leave detectable signatures in simulated biodiversity data axes. Next, using a simulation-based machine learning approach we show that neutral and non-neutral models are distinguishable and that reasonable estimates of several model parameters within the local community can be obtained using only community-scale genetic data, while phylogenetic information is required to estimate those describing metacommunity dynamics. Finally, we apply the model to soil microarthropod metabarcoding data from the Troodos mountains of Cyprus, where we find that communities in widespread forest habitats are structured by neutral processes, while high-elevation and isolated habitats act as an abiotic filter generating non-neutral community structure. We implement our model within the ibiogen R package, a package dedicated to the investigation of island, and more generally community-scale, biodiversity using community-scale genetic data.

Published
2023

14. Community metabarcoding reveals the relative role of environmental filtering and spatial processes in metacommunity dynamics of soil microarthropods across a mosaic of montane forests.

Author

Noguerales, Víctor, Meramveliotakis, Emmanouil, Castro‐Insua, Adrián, Andújar, Carmelo, Arribas, Paula, Creedy, Thomas J., Overcast, Isaac, Morlon, Hélène, Emerson, Brent C., Vogler, Alfried P., and Papadopoulou, Anna

Subjects
MOUNTAIN forests, SOIL dynamics, SPATIAL filters, GENETIC barcoding, GENETIC variation
Abstract

Disentangling the relative role of environmental filtering and spatial processes in driving metacommunity structure across mountainous regions remains challenging, as the way we quantify spatial connectivity in topographically and environmentally heterogeneous landscapes can influence our perception of which process predominates. More empirical data sets are required to account for taxon‐ and context‐dependency, but relevant research in understudied areas is often compromised by the taxonomic impediment. Here we used haplotype‐level community DNA metabarcoding, enabled by stringent filtering of amplicon sequence variants (ASVs), to characterize metacommunity structure of soil microarthropod assemblages across a mosaic of five forest habitats on the Troodos mountain range in Cyprus. We found similar β diversity patterns at ASV and species (OTU, operational taxonomic unit) levels, which pointed to a primary role of habitat filtering resulting in the existence of largely distinct metacommunities linked to different forest types. Within‐habitat turnover was correlated to topoclimatic heterogeneity, again emphasizing the role of environmental filtering. However, when integrating landscape matrix information for the highly fragmented Quercus alnifolia habitat, we also detected a major role of spatial isolation determined by patch connectivity, indicating that stochastic and niche‐based processes synergistically govern community assembly. Alpha diversity patterns varied between ASV and OTU levels, with OTU richness decreasing with elevation and ASV richness following a longitudinal gradient, potentially reflecting a decline of genetic diversity eastwards due to historical pressures. Our study demonstrates the utility of haplotype‐level community metabarcoding for characterizing metacommunity structure of complex assemblages and improving our understanding of biodiversity dynamics across mountainous landscapes worldwide. [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

16. Comparing the Accuracy and Efficiency of Third Generation Sequencing Technologies, Oxford Nanopore Technologies, and Pacific Biosciences, for DNA Barcode Sequencing Applications

Author

Cuber, Piotr, primary, Chooneea, Darren, additional, Geeves, Clementine, additional, Salatino, Silvia, additional, Creedy, Thomas J., additional, Griffin, Claire, additional, Sivess, Laura, additional, Barnes, Ian, additional, Price, Ben, additional, and Misra, Raju, additional

Published
2023
Full Text
View/download PDF

17. Towards a genetic theory of island biogeography: Inferring processes from multidimensional community‐scale data

Author

Overcast, Isaac, primary, Achaz, Guillaume, additional, Aguilée, Robin, additional, Andújar, Carmelo, additional, Arribas, Paula, additional, Creedy, Thomas J., additional, Economo, Evan P., additional, Etienne, Rampal S., additional, Gillespie, Rosemary, additional, Jacquet, Claire, additional, Jay, Flora, additional, Kennedy, Susan, additional, Krehenwinkel, Henrik, additional, Lambert, Amaury, additional, Meramveliotakis, Emmanouil, additional, Noguerales, Víctor, additional, Perez‐Lamarque, Benoit, additional, Roderick, George, additional, Rogers, Haldre, additional, Ruffley, Megan, additional, Sanmartin, Isabel, additional, Vogler, Alfried P., additional, Papadopoulou, Anna, additional, Emerson, Brent C., additional, and Morlon, Hélène, additional

Published
2022
Full Text
View/download PDF

18. Collective and harmonized high throughput barcoding of insular arthropod biodiversity: Toward a Genomic Observatories Network for islands

Author

Emerson, Brent C., primary, Borges, Paulo A. V., additional, Cardoso, Pedro, additional, Convey, Peter, additional, deWaard, Jeremy R., additional, Economo, Evan P., additional, Gillespie, Rosemary G., additional, Kennedy, Susan, additional, Krehenwinkel, Henrik, additional, Meier, Rudolf, additional, Roderick, George K., additional, Strasberg, Dominique, additional, Thébaud, Christophe, additional, Traveset, Anna, additional, Creedy, Thomas J., additional, Meramveliotakis, Emmanouil, additional, Noguerales, Víctor, additional, Overcast, Isaac, additional, Morlon, Hélène, additional, Papadopoulou, Anna, additional, Vogler, Alfried P., additional, Arribas, Paula, additional, and Andújar, Carmelo, additional

Published
2022
Full Text
View/download PDF

19. Collective and harmonised high throughput barcoding of insular arthropod biodiversity: toward a Genomic Observatories Network for islands

Author

Emerson, Brent C., Borges, Paulo A.V., Cardoso, Pedro, Convey, Peter, deWaard, Jeremy R., Economo, Evan P., Gillespie, Rosie, Kennedy, Susan, Krehenwinkel, Henrik, Meier, Rudolf, Roderick, George, Strasberg, Dominique, Thébaud, Christophe, Traveset, Anna, Creedy, Thomas J., Meramveliotakis, Emmanouil, Noguerales, Víctor, Overcast, Isaac, Morlon, Hélène, Papadopoulou, Anna, Vogler, Alfried P., Arribas, Paula, Andújar, Carmelo, Emerson, Brent C., Borges, Paulo A.V., Cardoso, Pedro, Convey, Peter, deWaard, Jeremy R., Economo, Evan P., Gillespie, Rosie, Kennedy, Susan, Krehenwinkel, Henrik, Meier, Rudolf, Roderick, George, Strasberg, Dominique, Thébaud, Christophe, Traveset, Anna, Creedy, Thomas J., Meramveliotakis, Emmanouil, Noguerales, Víctor, Overcast, Isaac, Morlon, Hélène, Papadopoulou, Anna, Vogler, Alfried P., Arribas, Paula, and Andújar, Carmelo

Abstract

Current understanding of ecological and evolutionary processes underlying island biodiversity is heavily shaped by empirical data from plants and birds, although arthropods comprise the overwhelming majority of known animal species, and as such can provide key insights into processes governing biodiversity. Novel high throughput sequencing (HTS) approaches are now emerging as powerful tools to overcome limitations in the availability of arthropod biodiversity data, and hence provide insights into these processes. Here we explore how these tools might be most effectively exploited for comprehensive and comparable inventory and monitoring of insular arthropod biodiversity. We first review the strengths, limitations and potential synergies among existing approaches of high throughput barcode sequencing. We consider how this can be complemented with deep learning approaches applied to image analysis to study arthropod biodiversity. We then explore how these approaches can be implemented within the framework of an island Genomic Observatories Network (iGON) for the advancement of fundamental and applied understanding of island biodiversity. To this end, we identify seven island biology themes at the interface of ecology, evolution and conservation biology, within which collective and harmonised efforts in HTS arthropod inventory could yield significant advances in island biodiversity research.

Published
2022

20. Toward global integration of biodiversity big data: a harmonized metabarcode data generation module for terrestrial arthropods

Author

European Commission, Fundación la Caixa, Arribas, Paula, Andújar, Carmelo, Bohmann, Kristine, deWaard, Jeremy R., Economo, Evan P., Elbrecht, Vasco, Geisen, Stefan, Goberna, M., Krehenwinkel, Henrik, Novotny, Vojtech, Zinger, Lucie, Creedy, Thomas J., Meramveliotakis, Emmanouil, Noguerales, Víctor, Overcast, Isaac, Morlon, Hélène, Papadopoulou, Anna, Vogler, Alfried P., Emerson, Brent C., European Commission, Fundación la Caixa, Arribas, Paula, Andújar, Carmelo, Bohmann, Kristine, deWaard, Jeremy R., Economo, Evan P., Elbrecht, Vasco, Geisen, Stefan, Goberna, M., Krehenwinkel, Henrik, Novotny, Vojtech, Zinger, Lucie, Creedy, Thomas J., Meramveliotakis, Emmanouil, Noguerales, Víctor, Overcast, Isaac, Morlon, Hélène, Papadopoulou, Anna, Vogler, Alfried P., and Emerson, Brent C.

Abstract

Metazoan metabarcoding is emerging as an essential strategy for inventorying biodiversity,with diverse projects currently generating massive quantities of community-level data. The potential for integrating across such data sets offers new opportunities to better understand biodiversity and how it might respond to global change. However, large-scale synthesesmay be compromised if metabarcoding workflows differ from each other. There are ongoing efforts to improve standardization for the reporting of inventory data. However, harmonization at the stage of generating metabarcode data has yet to be addressed. A modular framework for harmonized data generation offers a pathway to navigate the complex structure of terrestrial metazoan biodiversity. Here, through our collective expertise as practitioners,method developers, and researchers leading metabarcoding initiatives to inventory terrestrial biodiversity, we seek to initiate a harmonized framework for metabarcode data generation, with a terrestrial arthropod module. We develop an initial set of submodules covering the 5 main steps of metabarcode data generation: (i) sample acquisition; (ii) sample processing; (iii) DNA extraction; (iv) polymerase chain reaction amplification, library preparation, and sequencing; and (v) DNA sequence and metadata deposition, providing a backbone for a terrestrial arthropod module. To achieve this, we (i) identified key points for harmonization, (ii) reviewed the current state of the art, and (iii) distilled existing knowledge within submodules, thus promoting best practice by providing guidelines and recommendations to reduce the universe of methodological options.We advocate the adoption and further development of the terrestrial arthropodmodule.We further encourage the development of modules for other biodiversity fractions as an essential step toward large-scale biodiversity synthesis through harmonization.

Published
2022

21. Toward global integration of biodiversity big data:a harmonized metabarcode data generation module for terrestrial arthropods

Author

Arribas, Paula, Andújar, Carmelo, Bohmann, Kristine, deWaard, Jeremy R., Economo, Evan P., Elbrecht, Vasco, Geisen, Stefan, Goberna, Marta, Krehenwinkel, Henrik, Novotny, Vojtech, Zinger, Lucie, Creedy, Thomas J., Meramveliotakis, Emmanouil, Noguerales, Víctor, Overcast, Isaac, Morlon, Hélène, Papadopoulou, Anna, Vogler, Alfried P., Emerson, Brent C., Arribas, Paula, Andújar, Carmelo, Bohmann, Kristine, deWaard, Jeremy R., Economo, Evan P., Elbrecht, Vasco, Geisen, Stefan, Goberna, Marta, Krehenwinkel, Henrik, Novotny, Vojtech, Zinger, Lucie, Creedy, Thomas J., Meramveliotakis, Emmanouil, Noguerales, Víctor, Overcast, Isaac, Morlon, Hélène, Papadopoulou, Anna, Vogler, Alfried P., and Emerson, Brent C.

Abstract

Metazoan metabarcoding is emerging as an essential strategy for inventorying biodiversity,with diverse projects currently generating massive quantities of community-level data. The potential for integrating across such data sets offers new opportunities to better understand biodiversity and how it might respond to global change. However, large-scale synthesesmay be compromised if metabarcoding workflows differ from each other. There are ongoing efforts to improve standardization for the reporting of inventory data. However, harmonization at the stage of generating metabarcode data has yet to be addressed. A modular framework for harmonized data generation offers a pathway to navigate the complex structure of terrestrial metazoan biodiversity. Here, through our collective expertise as practitioners,method developers, and researchers leading metabarcoding initiatives to inventory terrestrial biodiversity, we seek to initiate a harmonized framework for metabarcode data generation, with a terrestrial arthropod module. We develop an initial set of submodules covering the 5 main steps of metabarcode data generation: (i) sample acquisition; (ii) sample processing; (iii) DNA extraction; (iv) polymerase chain reaction amplification, library preparation, and sequencing; and (v) DNA sequence and metadata deposition, providing a backbone for a terrestrial arthropod module. To achieve this, we (i) identified key points for harmonization, (ii) reviewed the current state of the art, and (iii) distilled existing knowledge within submodules, thus promoting best practice by providing guidelines and recommendations to reduce the universe of methodological options.We advocate the adoption and further development of the terrestrial arthropodmodule.We further encourage the development of modules for other biodiversity fractions as an essential step toward large-scale biodiversity synthesis through harmonization.

Published
2022

22. Toward global integration of biodiversity big data : a harmonized metabarcode data generation module for terrestrial arthropods

Author

Arribas, Paula, Andújar, Carmelo, Bohmann, Kristine, deWaard, Jeremy R., Economo, Evan P., Elbrecht, Vasco, Geisen, Stefan, Goberna, Marta, Krehenwinkel, Henrik, Novotny, Vojtech, Zinger, Lucie, Creedy, Thomas J., Meramveliotakis, Emmanouil, Noguerales, Víctor, Overcast, Isaac, Morlon, Hélène, Papadopoulou, Anna, Vogler, Alfried P., Emerson, Brent C., Arribas, Paula, Andújar, Carmelo, Bohmann, Kristine, deWaard, Jeremy R., Economo, Evan P., Elbrecht, Vasco, Geisen, Stefan, Goberna, Marta, Krehenwinkel, Henrik, Novotny, Vojtech, Zinger, Lucie, Creedy, Thomas J., Meramveliotakis, Emmanouil, Noguerales, Víctor, Overcast, Isaac, Morlon, Hélène, Papadopoulou, Anna, Vogler, Alfried P., and Emerson, Brent C.

Abstract

Metazoan metabarcoding is emerging as an essential strategy for inventorying biodiversity, with diverse projects currently generating massive quantities of community-level data. The potential for integrating across such data sets offers new opportunities to better understand biodiversity and how it might respond to global change. However, large-scale syntheses may be compromised if metabarcoding workflows differ from each other. There are ongoing efforts to improve standardization for the reporting of inventory data. However, harmonization at the stage of generating metabarcode data has yet to be addressed. A modular framework for harmonized data generation offers a pathway to navigate the complex structure of terrestrial metazoan biodiversity. Here, through our collective expertise as practitioners, method developers, and researchers leading metabarcoding initiatives to inventory terrestrial biodiversity, we seek to initiate a harmonized framework for metabarcode data generation, with a terrestrial arthropod module. We develop an initial set of submodules covering the 5 main steps of metabarcode data generation: (i) sample acquisition; (ii) sample processing; (iii) DNA extraction; (iv) polymerase chain reaction amplification, library preparation, and sequencing; and (v) DNA sequence and metadata deposition, providing a backbone for a terrestrial arthropod module. To achieve this, we (i) identified key points for harmonization, (ii) reviewed the current state of the art, and (iii) distilled existing knowledge within submodules, thus promoting best practice by providing guidelines and recommendations to reduce the universe of methodological options. We advocate the adoption and further development of the terrestrial arthropod module. We further encourage the development of modules for other biodiversity fractions as an essential step toward large-scale biodiversity synthesis through harmonization.

Published
2022

24. Toward global integration of biodiversity big data: a harmonized metabarcode data generation module for terrestrial arthropods

Author

Arribas, Paula, primary, Andújar, Carmelo, additional, Bohmann, Kristine, additional, deWaard, Jeremy R, additional, Economo, Evan P, additional, Elbrecht, Vasco, additional, Geisen, Stefan, additional, Goberna, Marta, additional, Krehenwinkel, Henrik, additional, Novotny, Vojtech, additional, Zinger, Lucie, additional, Creedy, Thomas J, additional, Meramveliotakis, Emmanouil, additional, Noguerales, Víctor, additional, Overcast, Isaac, additional, Morlon, Hélène, additional, Papadopoulou, Anna, additional, Vogler, Alfried P, additional, and Emerson, Brent C, additional

Published
2022
Full Text
View/download PDF

25. Community metabarcoding reveals the relative role of environmental filtering and spatial processes in metacommunity dynamics of soil microarthropods across a mosaic of montane forests

Author

Noguerales, Víctor, primary, Meramveliotakis, Emmanouil, additional, Castro‐Insua, Adrián, additional, Andújar, Carmelo, additional, Arribas, Paula, additional, Creedy, Thomas J., additional, Overcast, Isaac, additional, Morlon, Hélène, additional, Emerson, Brent C., additional, Vogler, Alfried P., additional, and Papadopoulou, Anna, additional

Published
2021
Full Text
View/download PDF

28. A review of the ecological value of Cusuco National Park: an urgent call for conservation action in a highly threatened Mesoamerican cloud forest

Author

Martin, Thomas E., Jones, Samuel E.L., Creedy, Thomas J., Hoskins, Hannah M.J., McCann, Niall, Batke, Sven P., Kelly, Daniel L., Kolby, Jonathan E., Downing, Roberto, Zelaya, Sandra M.S., Green, Stephen E.W., Lonsdale, George, Brown, Tom, Waters, Shaun, Rodríguez-Vásquez, Fabiola, McCravy, Kenneth W., D'Souza, Michelle L., Grace, Declan, Nuñez-Mino, Jose M., Haelewaters, Danny, Medina-Van Berkum, Pamela, Phipps, Christopher D., Barker, Rik J., Castañeda, Franklin, Reid, Neil, and Jocque, Merlijn

Subjects
Deforestration, Biology and Life Sciences, Central America, Carbon, climate change, Honduras, endemism, chytrid, poaching, SDG 13 - Climate Action, deforestation, protected areas, Protected Area, management, SDG 15 - Life on Land
Abstract

Cloud forests are amongst the most biologically unique, yet threatened, ecosystems in Mesoamerica. We summarize the ecological value and conservation status of a well-studied cloud forest site: Cusuco National Park(CNP), a 23,440 ha protected area in the Merendón mountains, northwest Honduras. We show cnp to have exceptional biodiversity; of 966 taxa identified to a species-level to date, 362 (37.5%) are Mesoamerican endemics, 67 are red-listed by the IUCN, and at least 49 are micro-endemics known only from the Merendón range. CNP also provides key ecosystem services including provision of drinking water and downstream flood mitigation, as well as carbon sequestration, with an estimated stock of 3.5 million megagrams of carbon in 2000. Despite its ecological importance, CNP faces multiple environmental threats and associated stresses, including deforestation (1,759 ha since 2000 equating to 7% of total forest area), poaching (7% loss of mammal relative abundance per year), amphibian declines due to chytridiomycosis (70% of species threatened or near-threatened), and climate change (a mean 2.6 °C increase in temperature and 112 mm decrease in rainfall by 2100). Despite conservation actions, including community ranger patrols, captive-breeding programmes, and ecotourism initiatives, environmental degradation of CNP continues. Further action is urgently required, including reinforcement and expansion of ranger programmes, greater stakeholder engagement, communityeducation programmes, development of alternative livelihood projects, and legislative enforcement and prosecution. Without a thorough and rapid response to understand and mitigate illegal activities, the extirpation and extinction of species and the loss of vital ecosystem services are inevitable in the coming decades.

Published
2021

29. Community metabarcoding reveals the relative role of environmental filtering and spatial processes in metacommunity dynamics of soil microarthropods across a mosaic of montane forests

Author

Noguerales, Víctor, Meramveliotakis, Emmanouil, Castro-Insua, Adrián, Andújar, Carmelo, Arribas, Paula, Creedy, Thomas J., Overcast, Isaac, Morlon, Hélène, Emerson, Brent C., Vogler, Alfried P., Papadopoulou, Anna, European Commission, and Ministerio de Ciencia e Innovación (España)

Subjects
Circuit theory, Cyprus, habitat connectivity, ASVs, habitat filtering, Habitat connectivity, amplicon sequence variants, circuit theory, OTUs, operational taxonomic units, Habitat filtering
Abstract

Disentangling the relative role of environmental filtering and dispersal limitation in driving metacommunity structure across mountainous regions remains challenging, as the way we quantify spatial connectivity in topographically and environmentally heterogeneous landscapes can influence our perception of which process predominates. More empirical datasets are required to account for taxon- and context-dependency but relevant research is often compromised by coarse taxonomic resolution. We here employed haplotype-level community DNA metabarcoding, enabled by stringent filtering of Amplicon Sequence Variants (ASVs), to characterize metacommunity structure of soil microarthropod assemblages across a mosaic of five forest habitats on the Troodos mountain range in Cyprus. We found similar β diversity patterns at ASV and species (OTU, Operational Taxonomic Unit) levels, which pointed to a primary role of habitat filtering resulting in the existence of largely distinct metacommunities linked to different forest types. Within-habitat turnover was correlated to topoclimatic heterogeneity, again emphasizing the role of environmental filtering. However, when integrating landscape matrix information for the highly fragmented Golden Oak habitat, we also detected a major role of dispersal limitation imposed by patch connectivity, indicating that stochastic and niche-based processes synergistically govern community assembly. Alpha diversity patterns varied between ASV and OTU levels, with OTU richness decreasing with elevation and ASV richness following a longitudinal gradient, potentially reflecting a decline of genetic diversity eastwards due to historical pressures. Our study demonstrates the utility of haplotype-level community metabarcoding for characterising metacommunity structure of complex assemblages and improving our understanding of biodiversity dynamics across mountainous landscapes worldwide., This work is a product of the iBioGen project, which has received funding from the European Union’s Horizon 2020 research and innovation programme under grant agreement No 810729. V.N. was supported by a postdoctoral contract under the iBioGen project and a Juan de la Cierva-Formación postdoctoral fellowship (grant FJC2018-035611-I) funded by the Spanish Ministry of Science and Innovation and the European Regional Development Fund

Published
2021

30. Connecting high-throughput biodiversity inventories:Opportunities for a site-based genomic framework for global integration and synthesis

Author

Arribas, Paula, Andujar, Carmelo, Bidartondo, Martin I., Bohmann, Kristine, Coissac, Eric, Creer, Simon, deWaard, Jeremy R., Elbrecht, Vasco, Ficetola, Gentile F., Goberna, Marta, Kennedy, Susan, Krehenwinkel, Henrik, Leese, Florian, Novotny, Vojtech, Ronquist, Fredrik, Yu, Douglas W., Zinger, Lucie, Creedy, Thomas J., Meramveliotakis, Emmanouil, Noguerales, Victor, Overcast, Isaac, Morlon, Helene, Vogler, Alfried P., Papadopoulou, Anna, Emerson, Brent C., Arribas, Paula, Andujar, Carmelo, Bidartondo, Martin I., Bohmann, Kristine, Coissac, Eric, Creer, Simon, deWaard, Jeremy R., Elbrecht, Vasco, Ficetola, Gentile F., Goberna, Marta, Kennedy, Susan, Krehenwinkel, Henrik, Leese, Florian, Novotny, Vojtech, Ronquist, Fredrik, Yu, Douglas W., Zinger, Lucie, Creedy, Thomas J., Meramveliotakis, Emmanouil, Noguerales, Victor, Overcast, Isaac, Morlon, Helene, Vogler, Alfried P., Papadopoulou, Anna, and Emerson, Brent C.

Abstract

High-throughput sequencing (HTS) is increasingly being used for the characterization and monitoring of biodiversity. If applied in a structured way, across broad geographical scales, it offers the potential for a much deeper understanding of global biodiversity through the integration of massive quantities of molecular inventory data generated independently at local, regional and global scales. The universality, reliability and efficiency of HTS data can potentially facilitate the seamless linking of data among species assemblages from different sites, at different hierarchical levels of diversity, for any taxonomic group and regardless of prior taxonomic knowledge. However, collective international efforts are required to optimally exploit the potential of site-based HTS data for global integration and synthesis, efforts that at present are limited to the microbial domain. To contribute to the development of an analogous strategy for the nonmicrobial terrestrial domain, an international symposium entitled "Next Generation Biodiversity Monitoring" was held in November 2019 in Nicosia (Cyprus). The symposium brought together evolutionary geneticists, ecologists and biodiversity scientists involved in diverse regional and global initiatives using HTS as a core tool for biodiversity assessment. In this review, we summarize the consensus that emerged from the 3-day symposium. We converged on the opinion that an effective terrestrial Genomic Observatories network for global biodiversity integration and synthesis should be spatially led and strategically united under the umbrella of the metabarcoding approach. Subsequently, we outline an HTS-based strategy to collectively build an integrative framework for site-based biodiversity data generation.

Published
2021

31. Validated removal of nuclear pseudogenes and sequencing artefacts from mitochondrial metabarcode data

Author

Ministerio de Economía y Competitividad (España), Fundación CajaCanarias, Fundación la Caixa, Andújar, Carmelo, Creedy, Thomas J., Arribas, Paula, López, Heriberto, Salces-Castellano, Antonia, Pérez‐Delgado, Antonio José, Vogler, Alfried P., Emerson, Brent C., Ministerio de Economía y Competitividad (España), Fundación CajaCanarias, Fundación la Caixa, Andújar, Carmelo, Creedy, Thomas J., Arribas, Paula, López, Heriberto, Salces-Castellano, Antonia, Pérez‐Delgado, Antonio José, Vogler, Alfried P., and Emerson, Brent C.

Abstract

Metabarcoding of Metazoa using mitochondrial genes may be confounded by both the accumulation of PCR and sequencing artefacts and the co-amplification of nuclear mitochondrial pseudogenes (NUMTs). The application of read abundance thresholds and denoising methods is efficient in reducing noise accompanying authentic mitochondrial amplicon sequence variants (ASVs). However, these procedures do not fully account for the complex nature of concomitant sequences and the highly variable DNA contribution of specimens in a metabarcoding sample. We propose, as a complement to denoising, the metabarcoding Multidimensional Abundance Threshold Evaluation (metaMATE) framework, a novel approach that allows comprehensive examination of multiple dimensions of abundance filtering and the evaluation of the prevalence of unwanted concomitant sequences in denoised metabarcoding datasets. metaMATE requires a denoised set of ASVs as input, and designates a subset of ASVs as being either authentic (mitochondrial DNA haplotypes) or nonauthentic ASVs (NUMTs and erroneous sequences) by comparison to external reference data and by analysing nucleotide substitution patterns. metaMATE (i) facilitates the application of read abundance filtering strategies, which are structured with regard to sequence library and phylogeny and applied for a range of increasing abundance threshold values, and (ii) evaluates their performance by quantifying the prevalence of nonauthentic ASVs and the collateral effects on the removal of authentic ASVs. The output from metaMATE facilitates decision-making about required filtering stringency and can be used to improve the reliability of intraspecific genetic information derived from metabarcode data. The framework is implemented in the metaMATE software (available at ).

Published
2021

32. Connecting high‐throughput biodiversity inventories: Opportunities for a site‐based genomic framework for global integration and synthesis

Author

European Research Council, European Commission, Arribas, Paula, Andújar, Carmelo, Bidartondo, Martin I., Bohmann, Kristine, Coissac, Eric, Creer, Simon, deWaard, Jeremy R., Elbrecht, Vasco, Ficetola, Gentile Francesco, Goberna, M., Kennedy, Susan, Krehenwinkel, Henrik, Leese, Florian, Novotny, Vojtech, Ronquist, Fredrik, Yu, Douglas W., Zinger, Lucie, Creedy, Thomas J., Meramveliotakis, Emmanouil, Noguerales, Víctor, Overcast, Isaac, Morlon, Hélène, Vogler, Alfried P., Papadopoulou, Anna, Emerson, Brent C., European Research Council, European Commission, Arribas, Paula, Andújar, Carmelo, Bidartondo, Martin I., Bohmann, Kristine, Coissac, Eric, Creer, Simon, deWaard, Jeremy R., Elbrecht, Vasco, Ficetola, Gentile Francesco, Goberna, M., Kennedy, Susan, Krehenwinkel, Henrik, Leese, Florian, Novotny, Vojtech, Ronquist, Fredrik, Yu, Douglas W., Zinger, Lucie, Creedy, Thomas J., Meramveliotakis, Emmanouil, Noguerales, Víctor, Overcast, Isaac, Morlon, Hélène, Vogler, Alfried P., Papadopoulou, Anna, and Emerson, Brent C.

Abstract

High‐throughput sequencing (HTS) is increasingly being used for the characterization and monitoring of biodiversity. If applied in a structured way, across broad geographical scales, it offers the potential for a much deeper understanding of global biodiversity through the integration of massive quantities of molecular inventory data generated independently at local, regional and global scales. The universality, reliability and efficiency of HTS data can potentially facilitate the seamless linking of data among species assemblages from different sites, at different hierarchical levels of diversity, for any taxonomic group and regardless of prior taxonomic knowledge. However, collective international efforts are required to optimally exploit the potential of site‐based HTS data for global integration and synthesis, efforts that at present are limited to the microbial domain. To contribute to the development of an analogous strategy for the nonmicrobial terrestrial domain, an international symposium entitled “Next Generation Biodiversity Monitoring” was held in November 2019 in Nicosia (Cyprus). The symposium brought together evolutionary geneticists, ecologists and biodiversity scientists involved in diverse regional and global initiatives using HTS as a core tool for biodiversity assessment. In this review, we summarize the consensus that emerged from the 3‐day symposium. We converged on the opinion that an effective terrestrial Genomic Observatories network for global biodiversity integration and synthesis should be spatially led and strategically united under the umbrella of the metabarcoding approach. Subsequently, we outline an HTS‐based strategy to collectively build an integrative framework for site‐based biodiversity data generation.

Published
2021

34. Connecting high‐throughput biodiversity inventories: Opportunities for a site‐based genomic framework for global integration and synthesis

Author

Arribas, Paula, primary, Andújar, Carmelo, additional, Bidartondo, Martin I., additional, Bohmann, Kristine, additional, Coissac, Éric, additional, Creer, Simon, additional, deWaard, Jeremy R., additional, Elbrecht, Vasco, additional, Ficetola, Gentile F., additional, Goberna, Marta, additional, Kennedy, Susan, additional, Krehenwinkel, Henrik, additional, Leese, Florian, additional, Novotny, Vojtech, additional, Ronquist, Fredrik, additional, Yu, Douglas W., additional, Zinger, Lucie, additional, Creedy, Thomas J., additional, Meramveliotakis, Emmanouil, additional, Noguerales, Víctor, additional, Overcast, Isaac, additional, Morlon, Hélène, additional, Vogler, Alfried P., additional, Papadopoulou, Anna, additional, and Emerson, Brent C., additional

Published
2021
Full Text
View/download PDF

35. Coming of age for COI metabarcoding of whole organism community DNA: Towards bioinformatic harmonisation.

Author

Creedy, Thomas J., Andújar, Carmelo, Meramveliotakis, Emmanouil, Noguerales, Victor, Overcast, Isaac, Papadopoulou, Anna, Morlon, Hélène, Vogler, Alfried P., Emerson, Brent C., and Arribas, Paula

Subjects
*GENETIC barcoding, *COMING of age, *DNA, *FRESHWATER habitats
Abstract

Metabarcoding of DNA extracted from community samples of whole organisms (whole organism community DNA, wocDNA) is increasingly being applied to terrestrial, marine and freshwater metazoan communities to provide rapid, accurate and high resolution data for novel molecular ecology research. The growth of this field has been accompanied by considerable development that builds on microbial metabarcoding methods to develop appropriate and efficient sampling and laboratory protocols for whole organism metazoan communities. However, considerably less attention has focused on ensuring bioinformatic methods are adapted and applied comprehensively in wocDNA metabarcoding. In this study we examined over 600 papers and identified 111 studies that performed COI metabarcoding of wocDNA. We then systematically reviewed the bioinformatic methods employed by these papers to identify the state‐of‐the‐art. Our results show that the increasing use of wocDNA COI metabarcoding for metazoan diversity is characterised by a clear absence of bioinformatic harmonisation, and the temporal trends show little change in this situation. The reviewed literature showed (i) high heterogeneity across pipelines, tasks and tools used, (ii) limited or no adaptation of bioinformatic procedures to the nature of the COI fragment, and (iii) a worrying underreporting of tasks, software and parameters. Based upon these findings we propose a set of recommendations that we think the metabarcoding community should consider to ensure that bioinformatic methods are appropriate, comprehensive and comparable. We believe that adhering to these recommendations will improve the long‐term integrative potential of wocDNA COI metabarcoding for biodiversity science. [ABSTRACT FROM AUTHOR]

Published
2022
Full Text
View/download PDF

36. A validated workflow for rapid taxonomic assignment and monitoring of a national fauna of bees (Apiformes) using high throughput DNA barcoding

Author

Creedy, Thomas J., Norman, Hannah, Tang, Cuong Q., Qing Chin, Kai, Andujar, Carmelo, Arribas, Paula, O'Connor, Rory S., Carvell, Claire, Notton, David G., Vogler, Alfried P., Creedy, Thomas J., Norman, Hannah, Tang, Cuong Q., Qing Chin, Kai, Andujar, Carmelo, Arribas, Paula, O'Connor, Rory S., Carvell, Claire, Notton, David G., and Vogler, Alfried P.

Abstract

Improved taxonomic methods are needed to quantify declining populations of insect pollinators. This study devises a high‐throughput DNA barcoding protocol for a regional fauna (United Kingdom) of bees (Apiformes), consisting of reference library construction, a proof‐of‐concept monitoring scheme, and the deep barcoding of individuals to assess potential artefacts and organismal associations. A reference database of cytochrome oxidase c subunit 1 (cox1) sequences including 92.4% of 278 bee species known from the UK showed high congruence with morphological taxon concepts, but molecular species delimitations resulted in numerous split and (fewer) lumped entities within the Linnaean species. Double tagging permitted deep Illumina sequencing of 762 separate individuals of bees from a UK‐wide survey. Extracting the target barcode from the amplicon mix required a new protocol employing read abundance and phylogenetic position, which revealed 180 molecular entities of Apiformes identifiable to species. An additional 72 entities were ascribed to nuclear pseudogenes based on patterns of read abundance and phylogenetic relatedness to the reference set. Clustering of reads revealed a range of secondary operational taxonomic units (OTUs) in almost all samples, resulting from traces of insect species caught in the same traps, organisms associated with the insects including a known mite parasite of bees, and the common detection of human DNA, besides evidence for low‐level cross‐contamination in pan traps and laboratory procedures. Custom scripts were generated to conduct critical steps of the bioinformatics protocol. The resources built here will greatly aid DNA‐based monitoring to inform management and conservation policies for the protection of pollinators.

Published
2020

37. A validated workflow for rapid taxonomic assignment and monitoring of a national fauna of bees (Apiformes) using high throughput DNA barcoding

Author

Imperial College London, Natural Environment Research Council (UK), Scottish Government, European Commission, Department for Environment, Food & Rural Affairs (UK), Creedy, Thomas J., Norman, Hannah, Tang, Cuong Q., Qing Chin, Kai, Andújar, Carmelo, Arribas, Paula, O'Connor, Rory S., Carvell, Claire, Notton, David G., Vogler, Alfried P., Imperial College London, Natural Environment Research Council (UK), Scottish Government, European Commission, Department for Environment, Food & Rural Affairs (UK), Creedy, Thomas J., Norman, Hannah, Tang, Cuong Q., Qing Chin, Kai, Andújar, Carmelo, Arribas, Paula, O'Connor, Rory S., Carvell, Claire, Notton, David G., and Vogler, Alfried P.

Abstract

Improved taxonomic methods are needed to quantify declining populations of insect pollinators. This study devises a high-throughput DNA barcoding protocol for a regional fauna (United Kingdom) of bees (Apiformes), consisting of reference library construction, a proof-of-concept monitoring scheme, and the deep barcoding of individuals to assess potential artefacts and organismal associations. A reference database of cytochrome oxidase c subunit 1 (cox1) sequences including 92.4% of 278 bee species known from the UK showed high congruence with morphological taxon concepts, but molecular species delimitations resulted in numerous split and (fewer) lumped entities within the Linnaean species. Double tagging permitted deep Illumina sequencing of 762 separate individuals of bees from a UK-wide survey. Extracting the target barcode from the amplicon mix required a new protocol employing read abundance and phylogenetic position, which revealed 180 molecular entities of Apiformes identifiable to species. An additional 72 entities were ascribed to nuclear pseudogenes based on patterns of read abundance and phylogenetic relatedness to the reference set. Clustering of reads revealed a range of secondary operational taxonomic units (OTUs) in almost all samples, resulting from traces of insect species caught in the same traps, organisms associated with the insects including a known mite parasite of bees, and the common detection of human DNA, besides evidence for low-level cross-contamination in pan traps and laboratory procedures. Custom scripts were generated to conduct critical steps of the bioinformatics protocol. The resources built here will greatly aid DNA-based monitoring to inform management and conservation policies for the protection of pollinators.

Published
2020

41. Forests and their canopies:achievements and horizons in canopy science

Author

Nakamura, Akihiro, Kitching, Roger L., Cao, Min, Creedy, Thomas J., Fayle, Tom M., Freiberg, Martin, Hewitt, C.N., Itioka, Takao, Koh, Lian Pin, Ma, Keping, Malhi, Yadvinder, Mitchell, Andrew, Novotny, Vojtech, Ozanne, Claire M.P., Song, Liang, Wang, Han, Ashton, Louise A., Nakamura, Akihiro, Kitching, Roger L., Cao, Min, Creedy, Thomas J., Fayle, Tom M., Freiberg, Martin, Hewitt, C.N., Itioka, Takao, Koh, Lian Pin, Ma, Keping, Malhi, Yadvinder, Mitchell, Andrew, Novotny, Vojtech, Ozanne, Claire M.P., Song, Liang, Wang, Han, and Ashton, Louise A.

Abstract

Forest canopies are dynamic interfaces between organisms and atmosphere, providing buffered microclimates and complex microhabitats. Canopies form vertically stratified ecosystems interconnected with other strata. Some forest biodiversity patterns and food webs have been documented and measurements of ecophysiology and biogeochemical cycling have allowed analyses of large-scale transfer of CO2, water, and trace gases between forests and the atmosphere. However, many knowledge gaps remain. With global research networks and databases, and new technologies and infrastructure, we envisage rapid advances in our understanding of the mechanisms that drive the spatial and temporal dynamics of forests and their canopies. Such understanding is vital for the successful management and conservation of global forests and the ecosystem services they provide to the world.

Published
2017

43. Collective and harmonized high throughput barcoding of insular arthropod biodiversity: Toward a Genomic Observatories Network for islands.

Author

Emerson BC, Borges PAV, Cardoso P, Convey P, deWaard JR, Economo EP, Gillespie RG, Kennedy S, Krehenwinkel H, Meier R, Roderick GK, Strasberg D, Thébaud C, Traveset A, Creedy TJ, Meramveliotakis E, Noguerales V, Overcast I, Morlon H, Papadopoulou A, Vogler AP, Arribas P, and Andújar C

Subjects
Animals, Biodiversity, Genomics, Plants genetics, DNA Barcoding, Taxonomic methods, Islands, Arthropods genetics
Abstract

Current understanding of ecological and evolutionary processes underlying island biodiversity is heavily shaped by empirical data from plants and birds, although arthropods comprise the overwhelming majority of known animal species, and as such can provide key insights into processes governing biodiversity. Novel high throughput sequencing (HTS) approaches are now emerging as powerful tools to overcome limitations in the availability of arthropod biodiversity data, and hence provide insights into these processes. Here, we explored how these tools might be most effectively exploited for comprehensive and comparable inventory and monitoring of insular arthropod biodiversity. We first reviewed the strengths, limitations and potential synergies among existing approaches of high throughput barcode sequencing. We considered how this could be complemented with deep learning approaches applied to image analysis to study arthropod biodiversity. We then explored how these approaches could be implemented within the framework of an island Genomic Observatories Network (iGON) for the advancement of fundamental and applied understanding of island biodiversity. To this end, we identified seven island biology themes at the interface of ecology, evolution and conservation biology, within which collective and harmonized efforts in HTS arthropod inventory could yield significant advances in island biodiversity research., (© 2022 The Authors. Molecular Ecology published by John Wiley & Sons Ltd.)

Published
2023
Full Text
View/download PDF

44. A validated workflow for rapid taxonomic assignment and monitoring of a national fauna of bees (Apiformes) using high throughput DNA barcoding.

Author

Creedy TJ, Norman H, Tang CQ, Qing Chin K, Andujar C, Arribas P, O'Connor RS, Carvell C, Notton DG, and Vogler AP

Subjects
Animals, Bees genetics, DNA genetics, Phylogeny, United Kingdom, Workflow, Bees classification, DNA Barcoding, Taxonomic methods, High-Throughput Nucleotide Sequencing methods
Abstract

Improved taxonomic methods are needed to quantify declining populations of insect pollinators. This study devises a high-throughput DNA barcoding protocol for a regional fauna (United Kingdom) of bees (Apiformes), consisting of reference library construction, a proof-of-concept monitoring scheme, and the deep barcoding of individuals to assess potential artefacts and organismal associations. A reference database of cytochrome oxidase c subunit 1 (cox1) sequences including 92.4% of 278 bee species known from the UK showed high congruence with morphological taxon concepts, but molecular species delimitations resulted in numerous split and (fewer) lumped entities within the Linnaean species. Double tagging permitted deep Illumina sequencing of 762 separate individuals of bees from a UK-wide survey. Extracting the target barcode from the amplicon mix required a new protocol employing read abundance and phylogenetic position, which revealed 180 molecular entities of Apiformes identifiable to species. An additional 72 entities were ascribed to nuclear pseudogenes based on patterns of read abundance and phylogenetic relatedness to the reference set. Clustering of reads revealed a range of secondary operational taxonomic units (OTUs) in almost all samples, resulting from traces of insect species caught in the same traps, organisms associated with the insects including a known mite parasite of bees, and the common detection of human DNA, besides evidence for low-level cross-contamination in pan traps and laboratory procedures. Custom scripts were generated to conduct critical steps of the bioinformatics protocol. The resources built here will greatly aid DNA-based monitoring to inform management and conservation policies for the protection of pollinators., (© 2019 John Wiley & Sons Ltd.)

Published
2020
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results