Your search keyword '"Laurence Dugal"' showing total 11 results

1. Author Correction: Stress-resistant corals may not acclimatize to ocean warming but maintain heat tolerance under cooler temperatures

Author

Verena Schoepf, Steven A. Carrion, Svenja M. Pfeifer, Melissa Naugle, Laurence Dugal, Jennifer Bruyn, and Malcolm T. McCulloch

Subjects

Science

Published

2023

2. Coral monitoring in northwest Australia with environmental DNA metabarcoding using a curated reference database for optimized detection

Author

Laurence Dugal, Luke Thomas, Shaun P. Wilkinson, Zoe T. Richards, Jason B. Alexander, Arne A.S. Adam, W. Jason Kennington, Simon Jarman, Nicole M. Ryan, Michael Bunce, and James P. Gilmour

Subjects

biodiversity, coral reefs, eDNA, ITS2, metabarcoding, monitoring, Environmental sciences, GE1-350, Microbial ecology, QR100-130

Abstract

Abstract The need for efficient and more accurate ways of monitoring threatened ecosystems is becoming increasingly urgent as climate change intensifies. Coral reefs are an example of an ecosystem in crisis, with widespread declines in coral cover and diversity documented over recent decades. Novel molecular approaches such as biomonitoring using environmental DNA (eDNA) from seawater samples show great potential to complement future coral reef monitoring programs, especially when used in combination with conventional methods. However, eDNA metabarcoding studies often rely on public databases (e.g., GenBank) for assigning taxonomy, which generally limits the number of sequences that can be taxonomically identified. The extent to which building reference tissue sequences improves taxonomic resolution has yet to be fully examined. Here, we combined traditional coral reef monitoring data with eDNA assessments derived from seawater collected at the highly diverse Rowley Shoals in Western Australia. Using two ITS2 assays developed to target basal metazoan DNA and a reference database spiked with 70 local coral specimens, we identified 37 genera and 40 species from 56 1 L seawater samples. We identified considerable overlap of taxa with visual survey data and showed that assignment of amplicon sequence variants was significantly improved when “spiking” the taxonomic classifier with curated sequences of locally collected species. Our findings showcase the potential of eDNA metabarcoding for monitoring the biodiversity of reef corals and highlight the importance of custom reference sequence databases for improving taxonomic resolution in metabarcoding studies.

Published

2022

3. Stress-resistant corals may not acclimatize to ocean warming but maintain heat tolerance under cooler temperatures

Author

Verena Schoepf, Steven A. Carrion, Svenja M. Pfeifer, Melissa Naugle, Laurence Dugal, Jennifer Bruyn, and Malcolm T. McCulloch

Subjects

Science

Abstract

Abstract Naturally heat-resistant coral populations hold significant potential for facilitating coral reef survival under rapid climate change. However, it remains poorly understood whether they can acclimatize to ocean warming when superimposed on their already thermally-extreme habitats. Furthermore, it is unknown whether they can maintain their heat tolerance upon larval dispersal or translocation to cooler reefs. We test this in a long-term mesocosm experiment using stress-resistant corals from thermally-extreme reefs in NW Australia. We show that these corals have a remarkable ability to maintain their heat tolerance and health despite acclimation to 3–6 °C cooler, more stable temperatures over 9 months. However, they are unable to increase their bleaching thresholds after 6-months acclimation to + 1 °C warming. This apparent rigidity in the thermal thresholds of even stress-resistant corals highlights the increasing vulnerability of corals to ocean warming, but provides a rationale for human-assisted migration to restore cooler, degraded reefs with corals from thermally-extreme reefs.

Published

2019

4. Distinct coral reef habitat communities characterized by environmental DNA metabarcoding

Author

Laurence Dugal, Luke Thomas, Abinaya Meenakshisundaram, Tiffany Simpson, Rose Lines, Jamie Colquhoun, Simon Jarman, and Mark Meekan

Subjects

Aquatic Science

Abstract

Coral reefs are biodiversity hotspots, places of high endemicity and provide essential services to billions of people globally. With increasing threats to these reefs worldwide, there is a need to implement faster, more efficient ways to monitor spatial and temporal patterns of biodiversity. Environmental DNA (eDNA) metabarcoding offers a promising tool to address this issue, as it has revolutionized our ability to monitor biodiversity from complex environmental samples such as seawater. However, the capacity for eDNA to resolve fine scale shifts in community composition across habitats in seascapes is yet to be fully explored. Here, we applied eDNA metabarcoding using the rRNA 18S Universal eukaryote assay to explore differences in community profiles between samples collected from the lagoon and reef slope habitats across more than 170 km of the Ningaloo Coast World Heritage Area in Western Australia. We recovered 2061 amplicon sequence variants that comprised of 401 taxa spanning 14 different metazoan phyla such as cnidarians, poriferans, molluscs, algae, worms, and echinoderms. Our results revealed strong clustering of samples by habitat type across the length of the reef. Community dissimilarity (beta diversity) between samples collected from the reef slope and lagoon habitats was high and was driven largely by a strong rate of spatial turnover, indicating a distinct set of taxa representing each reef zone community. We also detected a strong pattern of isolation by distance within our slope samples, suggesting that communities are spatially stratified across the length of the reef. Despite high connectivity due to regular flushing of the lagoon environment, our results demonstrate that metabarcoding of seawater eDNA from different habitats can resolve fine scale community structure. By generating multi-trophic biodiversity data, our study also provided baseline data for Ningaloo from which future changes can be assessed.

Published

2022

5. Coral monitoring in northwest Australia with environmental DNA metabarcoding using a curated reference database for optimized detection

Author

Shaun P. Wilkinson, Nicole M. Ryan, Simon N. Jarman, W. Jason Kennington, Arne A. S. Adam, Laurence Dugal, Michael Bunce, Luke Thomas, Jason B. Alexander, James P. Gilmour, and Zoe T. Richards

Subjects

geography, geography.geographical_feature_category, Ecology, Coral, fungi, QR100-130, technology, industry, and agriculture, ITS2, Biodiversity, Coral reef, Biology, Environmental sciences, Microbial ecology, monitoring, metabarcoding, Genetics, Reference database, GE1-350, Environmental DNA, coral reefs, eDNA, Ecology, Evolution, Behavior and Systematics, biodiversity

Abstract

The need for efficient and more accurate ways of monitoring threatened ecosystems is becoming increasingly urgent as climate change intensifies. Coral reefs are an example of an ecosystem in crisis, with widespread declines in coral cover and diversity documented over recent decades. Novel molecular approaches such as biomonitoring using environmental DNA (eDNA) from seawater samples show great potential to complement future coral reef monitoring programs, especially when used in combination with conventional methods. However, eDNA metabarcoding studies often rely on public databases (e.g., GenBank) for assigning taxonomy, which generally limits the number of sequences that can be taxonomically identified. The extent to which building reference tissue sequences improves taxonomic resolution has yet to be fully examined. Here, we combined traditional coral reef monitoring data with eDNA assessments derived from seawater collected at the highly diverse Rowley Shoals in Western Australia. Using two ITS2 assays developed to target basal metazoan DNA and a reference database spiked with 70 local coral specimens, we identified 37 genera and 40 species from 56 1 L seawater samples. We identified considerable overlap of taxa with visual survey data and showed that assignment of amplicon sequence variants was significantly improved when “spiking” the taxonomic classifier with curated sequences of locally collected species. Our findings showcase the potential of eDNA metabarcoding for monitoring the biodiversity of reef corals and highlight the importance of custom reference sequence databases for improving taxonomic resolution in metabarcoding studies.

Published

2021

6. Spatially varying selection between habitats drives physiological shifts and local adaptation in a broadcast spawning coral on a remote atoll in Western Australia

Author

Luke Thomas, Jim N. Underwood, Noah H. Rose, Zachary L. Fuller, Zoe T. Richards, Laurence Dugal, Camille M. Grimaldi, Ira R. Cooke, Stephen R. Palumbi, and James P. Gilmour

Subjects

Multidisciplinary, fungi, technology, industry, and agriculture, population characteristics, social sciences, geographic locations

Abstract

At the Rowley Shoals in Western Australia, the prominent reef flat becomes exposed on low tide and the stagnant water in the shallow atoll lagoons heats up, creating a natural laboratory for characterizing the mechanisms of coral resilience to climate change. To explore these mechanisms in the reef coral Acropora tenuis , we collected samples from lagoon and reef slope habitats and combined whole-genome sequencing, ITS2 metabarcoding, experimental heat stress, and transcriptomics. Despite high gene flow across the atoll, we identified clear shifts in allele frequencies between habitats at relatively small linked genomic islands. Common garden heat stress assays showed corals from the lagoon to be more resistant to bleaching, and RNA sequencing revealed marked differences in baseline levels of gene expression between habitats. Our results provide new insight into the complex mechanisms of coral resilience to climate change and highlight the potential for spatially varying selection across complex coral reef seascapes to drive pronounced ecological divergence in climate-related traits.

Published

2022

7. Individual haplotyping of whale sharks from seawater environmental DNA

Author

Luke Thomas, Tiffany Simpson, Laurence Dugal, Mark G. Meekan, Eva Egelyng Sigsgaard, Philip Francis Thomsen, Simon N. Jarman, and Mads Reinholdt Jensen

Subjects

haplotype, Sample (material), Population, Biodiversity, Population genetics, Whale shark, GENETIC-STRUCTURE, Sharks/genetics, elasmobranchs, biology.animal, Genetics, Animals, Environmental DNA, Seawater, R PACKAGE, education, Ecology, Evolution, Behavior and Systematics, SOUTH, Genetic diversity, education.field_of_study, biology, Whale, mtDNA, Australia, population genetics, biology.organism_classification, environmental DNA, DNA, Environmental, RHINCODON-TYPUS, Haplotypes, Evolutionary biology, LARGEST FISH, Sharks, intraspecific diversity, PATTERNS, eDNA, Biotechnology

Abstract

Population genetic data can provide valuable information on the demography of a species. For rare and elusive marine megafauna, samples for generating the data are traditionally obtained from tissue biopsies, which can be logistically difficult and expensive to collect and require invasive sampling techniques. Analysis of environmental DNA (eDNA) offers an alternative, minimally invasive approach to provide important genetic information. Although eDNA approaches have been studied extensively for species detection and biodiversity monitoring in metabarcoding studies, the potential for the technique to address population-level questions remains largely unexplored. Here, we applied “eDNA haplotyping” to obtain estimates of the intraspecific genetic diversity of a whale shark (Rhincodon typus) aggregation at Ningaloo reef, Australia. Over 2 weeks, we collected seawater samples directly behind individual sharks prior to taking a tissue biopsy sample from the same animal. Our data showed a 100% match between mtDNA sequences recovered in the eDNA and tissue sample for all 28 individuals sampled. In the seawater samples, >97% of all reads were assigned to six dominant haplotypes, and a clear dominant signal (~99% of sample reads) was recovered in each sample. Our study demonstrates accurate individual-level haplotyping from seawater eDNA. When DNA from one individual clearly dominates each eDNA sample, it provides many of the same opportunities for population genetic analyses as a tissue sample, potentially removing the need for tissue sampling. Our results show that eDNA approaches for population-level analyses have the potential to supply critical demographic data for the conservation and management of marine megafauna.

Published

2022

8. Contrasting patterns of genetic connectivity in brooding and spawning corals across a remote atoll system in northwest Australia

Author

Karen Miller, Luke Thomas, Jim N. Underwood, Arne A. S. Adam, James P. Gilmour, Laurence Dugal, and Zoe T. Richards

Subjects

0106 biological sciences, Panmixia, geography, education.field_of_study, geography.geographical_feature_category, Ecology, 010604 marine biology & hydrobiology, Coral, fungi, Population, technology, industry, and agriculture, Atoll, Metapopulation, Aquatic Science, Biology, 010603 evolutionary biology, 01 natural sciences, Gene flow, Genetic structure, Biological dispersal, education

Abstract

An understanding of larval dispersal and connectivity in corals provides valuable insight into the processes of population maintenance and replenishment and is vital for effective management. Here, we used a genotyping by sequencing approach to explore patterns of genetic connectivity in two species of coral with different reproductive modes (brooding and broadcast spawning) at the Rowley Shoals in northwest Australia. Our data revealed strikingly different patterns of genetic structure in the two species. High levels of genetic subdivision in the brooding coral I. brueggemanni was consistent with extensive self-recruitment and restricted connectivity. In contrast, the broadcast spawning coral A. digitifera formed a single panmictic population with extensive gene flow. Our results highlight the wide variation in metapopulation connectivity that exists among corals and support the well-established link between reproductive mode and population genetic structure in the marine environment.

Published

2019

9. Development of a multi-assay approach for monitoring coral diversity using eDNA metabarcoding

Author

Michael Stat, Nicole White, Shaun P. Wilkinson, Zoe T. Richards, Luke Thomas, Arne A. S. Adam, Michael Bunce, Tina E. Berry, Jason B. Alexander, Laurence Dugal, and Stephen J. Newman

Subjects

0106 biological sciences, Species complex, geography, geography.geographical_feature_category, biology, Ecology, 010604 marine biology & hydrobiology, Coral, Scleractinia, Biota, Coral reef, Aquatic Science, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, Marine ecosystem, Ecosystem, Environmental DNA, 14. Life underwater

Abstract

Cumulative anthropogenic pressures have triggered a global decline in the health of marine ecosystems, and coral reefs, in particular, are in crisis. With climate and population-related pressures predicted to intensify in the coming decades, it is increasingly crucial to develop cost-effective and accurate monitoring tools to document changes to these important ecosystems. Environmental DNA (eDNA) coupled with metabarcoding is a powerful tool for surveying a wide variety of biota. Here, we develop a baseline eDNA toolkit targeting scleractinian corals and validate its performance in conjunction with data derived on traditional diver-based visual surveys at the Cocos (Keeling) Islands. Three assays targeting the ITS2 and 16S barcoding regions were designed, which broadly detected diversity within Scleractinia and Porifera. Our eDNA assays recovered 78 ITS2 operational taxonomic units (OTUs) from 25 scleractinian genera which is comparable to the level of diversity recorded on visual surveys (68 species from 26 genera). There were some notable differences in the species detected using eDNA versus visual records that may relate to either misidentifications, intragenic variation, differential assay performance or cryptic species. Our data demonstrate that a multi-assay eDNA analytical approach, applied on surface water collections, represents a powerful and complementary way to survey diversity that can also reveal fine scale spatial differentiation in community composition. With further refinement and improved reference databases, we envisage eDNA to become a powerful complement to visual surveys and to play a key role in monitoring the health and diversity of complex coral reefs ecosystems.

Published

2019

10. Mechanisms of ecological divergence with gene flow in a reef-building coral on an isolated atoll in Western Australia

Author

Laurence Dugal, Noah H. Rose, Camille Grimaldi, Jim Underwood, James Gilmour, Ira Cooke, Stephen R. Palumbi, Zoe T. Richards, Luke Thomas, and Zach L Fuller

Subjects

geography, geography.geographical_feature_category, Habitat, Resistance (ecology), Range (biology), Ecology, Coral, fungi, Climate change, Atoll, Biology, Reef, Gene flow

Abstract

Understanding the mechanisms driving phenotypic variation in traits facing intensified selection from climate change is a crucial step in developing effective conservation and restoration initiatives. This is particularly true for reef-building corals, which are among the most vulnerable to climate change and are in dramatic decline globally. At the Rowley Shoals in Western Australia, the prominent reef flat becomes exposed on low tide and the stagnant water in the shallow atoll lagoons heats up, creating a natural laboratory for characterising the mechanisms that control phenotypic responses to different environments. We combined whole genome re-sequencing, common garden heat stress experiments, transcriptome-wide gene expression analyses, and symbiont metabarcoding to explore the mechanisms that facilitate survival in contrasting habitat conditions. Our data show that, despite high gene flow between habitats, spatially varying selection drives subtle shifts in allele frequencies at hundreds of loci. These changes were concentrated into several islands of divergence spanning hundreds of SNPs that showed strong linkage disequilibrium and were associated with a coordinated increase in minor allele frequencies in corals taken from the lagoon habitat, where the range of environmental conditions is greatest. Common garden heat stress assays showed individuals from the lagoon exhibited higher bleaching resistance than colonies from the reef slope, and RNAseq identified pronounced physiological differences between the corals from the two habitats, primarily associated with molecular pathways including cell signalling, ion transport and metabolism. Despite the pronounced physioloigical and environmental differences between habitats, metabarcoding of theSymbiodiniaceaeITS2 region revealed all colonies to be associated exclusively with the genusCladocopium, with no detectable differences between habitats. This study contributes to the growing number of studies documenting the complex mechanisms that facilitate coral survival in extreme environments, and showcases the utility of combining multiple sequencing techniques to unravel complex climate-related traits.

Published

2021

11. Stress-resistant corals may not acclimatize to ocean warming but maintain heat tolerance under cooler temperatures

Author

Melissa Naugle, Steven A. Carrion, Svenja M. Pfeifer, Verena Schoepf, Malcolm T. McCulloch, Jennifer Bruyn, and Laurence Dugal

Subjects

0106 biological sciences, 0301 basic medicine, Thermotolerance, Coral, Effects of global warming on oceans, Acclimatization, Climate Change, Oceans and Seas, Science, General Physics and Astronomy, Climate change, 010603 evolutionary biology, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Article, Mesocosm, 03 medical and health sciences, Stress, Physiological, Animals, lcsh:Science, Reef, geography, Multidisciplinary, geography.geographical_feature_category, Ecology, Temperature, General Chemistry, Coral reef, Anthozoa, Environmental sciences, 030104 developmental biology, Biological dispersal, Environmental science, lcsh:Q

Abstract

Naturally heat-resistant coral populations hold significant potential for facilitating coral reef survival under rapid climate change. However, it remains poorly understood whether they can acclimatize to ocean warming when superimposed on their already thermally-extreme habitats. Furthermore, it is unknown whether they can maintain their heat tolerance upon larval dispersal or translocation to cooler reefs. We test this in a long-term mesocosm experiment using stress-resistant corals from thermally-extreme reefs in NW Australia. We show that these corals have a remarkable ability to maintain their heat tolerance and health despite acclimation to 3–6 °C cooler, more stable temperatures over 9 months. However, they are unable to increase their bleaching thresholds after 6-months acclimation to + 1 °C warming. This apparent rigidity in the thermal thresholds of even stress-resistant corals highlights the increasing vulnerability of corals to ocean warming, but provides a rationale for human-assisted migration to restore cooler, degraded reefs with corals from thermally-extreme reefs., Coral populations from thermally extreme conditions may help restore reefs degraded by bleaching. Here, the authors show that these corals can maintain their heat tolerance despite acclimation to colder temperatures but have a limited capacity to acclimatize to ocean warming.

Published

2019