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3. Elucidation of the speciation history of three sister species of crown-of-thorns starfish (Acanthaster spp.) based on genomic analysis

Author

Yuasa, H, Kajitani, R, Nakamura, Y, Takahashi, K, Okuno, M, Kobayashi, F, Shinoda, T, Toyoda, A, Suzuki, Y, Thongtham, N, Forsman, Z, Bronstein, O, Seveso, D, Montalbetti, E, Taquet, C, Eyal, G, Yasuda, N, Itoh, T, Yuasa H., Kajitani R., Nakamura Y., Takahashi K., Okuno M., Kobayashi F., Shinoda T., Toyoda A., Suzuki Y., Thongtham N., Forsman Z., Bronstein O., Seveso D., Montalbetti E., Taquet C., Eyal G., Yasuda N., Itoh T., Yuasa, H, Kajitani, R, Nakamura, Y, Takahashi, K, Okuno, M, Kobayashi, F, Shinoda, T, Toyoda, A, Suzuki, Y, Thongtham, N, Forsman, Z, Bronstein, O, Seveso, D, Montalbetti, E, Taquet, C, Eyal, G, Yasuda, N, Itoh, T, Yuasa H., Kajitani R., Nakamura Y., Takahashi K., Okuno M., Kobayashi F., Shinoda T., Toyoda A., Suzuki Y., Thongtham N., Forsman Z., Bronstein O., Seveso D., Montalbetti E., Taquet C., Eyal G., Yasuda N., and Itoh T.

Abstract

The crown-of-thorns starfish (COTS) is a coral predator that is widely distributed in Indo-Pacific Oceans. A previous phylogenetic study using partial mitochondrial sequences suggested that COTS had diverged into four distinct species, but a nuclear genome-based analysis to confirm this was not conducted. To address this, COTS species nuclear genome sequences were analysed here, sequencing Northern Indian Ocean (NIO) and Red Sea (RS) species genomes for the first time, followed by a comparative analysis with the Pacific Ocean (PO) species. Phylogenetic analysis and ADMIXTURE analysis revealed clear divergences between the three COTS species. Furthermore, within the PO species, the phylogenetic position of the Hawaiian sample was further away from the other Pacific-derived samples than expected based on the mitochondrial data, suggesting that it may be a PO subspecies. The pairwise sequentially Markovian coalescent model showed that the trajectories of the population size diverged by region during the Mid-Pleistocene transition when the sea-level was dramatically decreased, strongly suggesting that the three COTS species experienced allopatric speciation. Analysis of the orthologues indicated that there were remarkable genes with species-specific positive selection in the genomes of the PO and RS species, which suggested that there may be local adaptations in the COTS species.

Published
2021

5. Environmental latitudinal gradients and host-specificity shape Symbiodiniaceae distribution in Red Sea Porites corals

Author

Terraneo, T, Fusi, M, Hume, B, Arrigoni, R, Voolstra, C, Benzoni, F, Forsman, Z, Berumen, M, Terraneo T. I., Fusi M., Hume B. C. C., Arrigoni R., Voolstra C. R., Benzoni F., Forsman Z. H., Berumen M. L., Terraneo, T, Fusi, M, Hume, B, Arrigoni, R, Voolstra, C, Benzoni, F, Forsman, Z, Berumen, M, Terraneo T. I., Fusi M., Hume B. C. C., Arrigoni R., Voolstra C. R., Benzoni F., Forsman Z. H., and Berumen M. L.

Abstract

Aim: The aim of the study was to assess the diversity of algal symbionts of the family Symbiodiniaceae associated with the coral genus Porites in the Red Sea, and to test for host-specificity and environmental variables driving biogeographical patterns of algal symbiont distribution. Location: Saudi Arabian Red Sea. Taxon: Endosymbiotic dinoflagellates of the family Symbiodiniaceae in association with the reef-building coral genus Porites. Methods: Eighty Porites coral specimens were collected along the Saudi Arabian Red Sea coast. Species boundaries were assessed morphologically and genetically (putative Control Region – mtCR; ITS region – ITS). Community composition of symbiotic dinoflagellates of the family Symbiodiniaceae was also assessed. Using the ITS2 marker with the SymPortal framework, Symbiodiniaceae data at the genus, majority ITS2 sequence and ITS2 type profile were used to assess symbiont diversity and distribution patterns. These were analysed in relation to coral host diversity, geographic location and environmental variables. Results: Among the 80 Porites samples, 10 morphologies were identified. These corals were clustered into five lineages (clades I–V) by each of the markers independently. Clades I, II and III each comprised of a single Porites morphology, while clades IV and V contained up to five distinct morphologies. The diversity of Symbiodiniaceae associated with Porites was high and latitudinal differentiation was observed. In particular, a shift from a Cladocopium-dominated to a Durusdinium-dominated community was found along the north–south gradient. Symbiont diversity showed the patterns of geographic-specific association at Symbiodiniaceae genus, majority ITS2 sequence and ITS2 type profile level. Specific associations with host genotypes (but not morphological species) were also recovered when considering Symbiodiniaceae majority ITS2 sequence and ITS2 type profiles. Main conclusions: This study provides the first large-scale molecula

Published
2019

8. The complete mitochondrial genome of Porites harrisoni (Cnidaria: Scleractinia) obtained using next-generation sequencing

Author

Terraneo, T, Arrigoni, R, Benzoni, F, Forsman, Z, Berumen, M, Terraneo, Tullia Isotta, Arrigoni, Roberto, Benzoni, Francesca, Forsman, Zac H., Berumen, Michael L., Terraneo, T, Arrigoni, R, Benzoni, F, Forsman, Z, Berumen, M, Terraneo, Tullia Isotta, Arrigoni, Roberto, Benzoni, Francesca, Forsman, Zac H., and Berumen, Michael L.

Abstract

In this study, we sequenced the complete mitochondrial genome of Porites harrisoni using ezRAD and Illumina technology. Genome length consisted of 18,630 bp, with a base composition of 25.92% A, 13.28% T, 23.06% G, and 37.73% C. Consistent with other hard corals, P. harrisoni mitogenome was arranged in 13 protein-coding genes, 2 rRNA, and 2 tRNA genes. nad5 and cox1 contained embedded Group I Introns of 11,133 bp and 965 bp, respectively

Published
2018

9. Using ezRAD to reconstruct the complete mitochondrial genome of Porites fontanesii (Cnidaria: Scleractinia)

Author

Terraneo, T, Arrigoni, R, Benzoni, F, Forsman, Z, Berumen, M, Terraneo, TI, Forsman, ZH, Berumen, ML, Terraneo, T, Arrigoni, R, Benzoni, F, Forsman, Z, Berumen, M, Terraneo, TI, Forsman, ZH, and Berumen, ML

Abstract

Corals in the genus Porites are among the major framework builders of reef structures worldwide, yet the genus has been challenging to study due to a lack of informative molecular markers. Here, we used ezRAD sequencing to reconstruct the complete mitochondrial genome of Porites fontanesii (GenBank accession number MG754069), a widespread coral species endemic to the Red Sea and Gulf of Aden. The gene arrangement of P. fontanesii did not differ from other Scleractinia and consisted of 18,658 bp, organized in 13 protein-coding genes, 2 rRNA genes, and 2 tRNA genes. This mitochondrial genome contributes essential data to work towards a better understanding of evolutionary relationships within Porites

Published
2018

14. Molecular Delineation of Species in the Coral Holobiont

Author

Stat, Michael, Baker, A., Bourne, D., Correa, A., Forsman, Z., Huggett, M., Pochon, X., Skillings, D., Toonen, R., van Oppen, M., Gates, R., Stat, Michael, Baker, A., Bourne, D., Correa, A., Forsman, Z., Huggett, M., Pochon, X., Skillings, D., Toonen, R., van Oppen, M., and Gates, R.

Abstract

The coral holobiont is a complex assemblage of organisms spanning a diverse taxonomic range including a cnidarian host, as well as various dinoflagellate, prokaryotic and acellular symbionts. With the accumulating information on the molecular diversity of these groups, binomial species classification and a reassessment of species boundaries for the partners in the coral holobiont is a logical extension of this work and will help enhance the capacity for comparative research among studies. To aid in this endeavour, we review the current literature on species diversity for the three best studied partners of the coral holobiont (coral, Symbiodinium, prokaryotes) and provide suggestions for future work on systematics within these taxa. We advocate for an integrative approach to the delineation of species using both molecular genetics in combination with phenetic characters. We also suggest that an a priori set of criteria be developed for each taxonomic group as no one species concept or accompanying set of guidelines is appropriate for delineating all members of the coral holobiont. © 2012 Elsevier Ltd.

Published
2012

16. Elucidation of the speciation history of three sister species of crown-of-thorns starfish (Acanthaster spp.) based on genomic analysis

Author

Zac H. Forsman, Yuta Nakamura, Miki Okuno, Yutaka Suzuki, Coralie Taquet, Nina Yasuda, Nalinee Thongtham, Kazuki Takahashi, Gal Eyal, Hideaki Yuasa, Rei Kajitani, Davide Seveso, Omri Bronstein, Takehiko Itoh, Atsushi Toyoda, Takahiro Shinoda, Fumiya Kobayashi, Enrico Montalbetti, Yuasa, H, Kajitani, R, Nakamura, Y, Takahashi, K, Okuno, M, Kobayashi, F, Shinoda, T, Toyoda, A, Suzuki, Y, Thongtham, N, Forsman, Z, Bronstein, O, Seveso, D, Montalbetti, E, Taquet, C, Eyal, G, Yasuda, N, and Itoh, T

Subjects
Starfish, Allopatric speciation, population demographic history, coral predator, Subspecies, Genome, Coalescent theory, Genetics, Animals, Molecular Biology, Phylogeny, common ancestor, biology, Phylogenetic tree, three distinct sister specie, Acanthaster, Genomics, Sequence Analysis, DNA, General Medicine, biology.organism_classification, Biological Evolution, Phylogeography, Crown-of-thorns starfish, phylogenetic analysi, Evolutionary biology, Research Article
Abstract

The crown-of-thorns starfish (COTS) is a coral predator that is widely distributed in Indo-Pacific Oceans. A previous phylogenetic study using partial mitochondrial sequences suggested that COTS had diverged into four distinct species, but a nuclear genome-based analysis to confirm this was not conducted. To address this, COTS species nuclear genome sequences were analysed here, sequencing Northern Indian Ocean (NIO) and Red Sea (RS) species genomes for the first time, followed by a comparative analysis with the Pacific Ocean (PO) species. Phylogenetic analysis and ADMIXTURE analysis revealed clear divergences between the three COTS species. Furthermore, within the PO species, the phylogenetic position of the Hawaiian sample was further away from the other Pacific-derived samples than expected based on the mitochondrial data, suggesting that it may be a PO subspecies. The pairwise sequentially Markovian coalescent model showed that the trajectories of the population size diverged by region during the Mid-Pleistocene transition when the sea-level was dramatically decreased, strongly suggesting that the three COTS species experienced allopatric speciation. Analysis of the orthologues indicated that there were remarkable genes with species-specific positive selection in the genomes of the PO and RS species, which suggested that there may be local adaptations in the COTS species.

Published
2021
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17. Environmental latitudinal gradients and host‐specificity shape Symbiodiniaceae distribution in Red Sea Porites corals

Author

Marco Fusi, Christian R. Voolstra, Benjamin C. C. Hume, Zac H. Forsman, Tullia Isotta Terraneo, Michael L. Berumen, Roberto Arrigoni, Francesca Benzoni, Terraneo, T, Fusi, M, Hume, B, Arrigoni, R, Voolstra, C, Benzoni, F, Forsman, Z, and Berumen, M

Subjects
symbiosi, 0106 biological sciences, Coral, Porites, ITS2, Scleractinia, Zoology, ITS2, Latitudinal gradient, next‐generation sequencing, Scleractinia, symbiosis, SymPortal, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, Symbiosis, Genus, ddc:570, parasitic diseases, Clade, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, 0303 health sciences, Ecology, biology, SymPortal, Host (biology), fungi, biochemical phenomena, metabolism, and nutrition, Latitudinal gradient, biology.organism_classification, Taxon, next-generation sequencing, BIO/05 - ZOOLOGIA
Abstract

AimThe aim of the study was to assess the diversity of algal symbionts of the family Symbiodiniaceae associated with the coral genus Porites in the Red Sea, and to test for host‐specificity and environmental variables driving biogeographical patterns of algal symbiont distribution.LocationSaudi Arabian Red Sea.TaxonEndosymbiotic dinoflagellates of the family Symbiodiniaceae in association with the reef‐building coral genus Porites.MethodsEighty Porites coral specimens were collected along the Saudi Arabian Red Sea coast. Species boundaries were assessed morphologically and genetically (putative Control Region – mtCR; ITS region – ITS). Community composition of symbiotic dinoflagellates of the family Symbiodiniaceae was also assessed. Using the ITS2 marker with the SymPortal framework, Symbiodiniaceae data at the genus, majority ITS2 sequence and ITS2 type profile were used to assess symbiont diversity and distribution patterns. These were analysed in relation to coral host diversity, geographic location and environmental variables.ResultsAmong the 80 Porites samples, 10 morphologies were identified. These corals were clustered into five lineages (clades I–V) by each of the markers independently. Clades I, II and III each comprised of a single Porites morphology, while clades IV and V contained up to five distinct morphologies. The diversity of Symbiodiniaceae associated with Porites was high and latitudinal differentiation was observed. In particular, a shift from a Cladocopium‐dominated to a Durusdinium‐dominated community was found along the north–south gradient. Symbiont diversity showed the patterns of geographic‐specific association at Symbiodiniaceae genus, majority ITS2 sequence and ITS2 type profile level. Specific associations with host genotypes (but not morphological species) were also recovered when considering Symbiodiniaceae majority ITS2 sequence and ITS2 type profiles.Main conclusionsThis study provides the first large‐scale molecular characterization of Symbiodiniaceae communities associated with Porites corals from the Saudi Arabian Red Sea. The use of intragenomic diversity data enabled the resolution of host‐symbiont specificity and biogeographical patterns of distribution, previously unachievable with the ITS2 marker alone. Finally, correlation among symbiont diversity and Red Sea environmental gradients was documented. published

Published
2019

18. The complete mitochondrial genome of Porites harrisoni (Cnidaria: Scleractinia) obtained using next-generation sequencing

Author

Michael L. Berumen, Zac H. Forsman, Tullia Isotta Terraneo, Roberto Arrigoni, Francesca Benzoni, Terraneo, T, Arrigoni, R, Benzoni, F, Forsman, Z, and Berumen, M

Subjects
0301 basic medicine, Cnidaria, Mitochondrial DNA, Scleractiania, biology, Scleractinia, biology.organism_classification, Genome, DNA sequencing, 03 medical and health sciences, Mitogenome, 030104 developmental biology, Porites harrisoni, Evolutionary biology, Genetics, Molecular Biology, ezRAD sequencing, Mitogenome Announcement, BIO/05 - ZOOLOGIA, Research Article
Abstract

In this study, we sequenced the complete mitochondrial genome of Porites harrisoni using ezRAD and Illumina technology. Genome length consisted of 18,630 bp, with a base composition of 25.92% A, 13.28% T, 23.06% G, and 37.73% C. Consistent with other hard corals, P. harrisoni mitogenome was arranged in 13 protein-coding genes, 2 rRNA, and 2 tRNA genes. nad5 and cox1 contained embedded Group I Introns of 11,133 bp and 965 bp, respectively.

Published
2018

19. Using ezRAD to reconstruct the complete mitochondrial genome of Porites fontanesii (Cnidaria: Scleractinia)

Author

Michael L. Berumen, Tullia Isotta Terraneo, Zac H. Forsman, Roberto Arrigoni, Francesca Benzoni, Terraneo, T, Arrigoni, R, Benzoni, F, Forsman, Z, and Berumen, M

Subjects
0106 biological sciences, 0301 basic medicine, Cnidaria, Mitochondrial DNA, Scleractiania, biology, Porites, Scleractinia, Ribosomal RNA, RAD sequencing, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, 030104 developmental biology, Mitochondrial genome, Evolutionary biology, Genus, GenBank, Genetics, Molecular Biology, Gene, Mitogenome Announcement, Research Article
Abstract

Corals in the genus Porites are among the major framework builders of reef structures worldwide, yet the genus has been challenging to study due to a lack of informative molecular markers. Here, we used ezRAD sequencing to reconstruct the complete mitochondrial genome of Porites fontanesii (GenBank accession number MG754069), a widespread coral species endemic to the Red Sea and Gulf of Aden. The gene arrangement of P. fontanesii did not differ from other Scleractinia and consisted of 18,658 bp, organized in 13 protein-coding genes, 2 rRNA genes, and 2 tRNA genes. This mitochondrial genome contributes essential data to work towards a better understanding of evolutionary relationships within Porites.

Published
2018

20. Mitochondrial Genome of Nonmodel Marine Metazoans by Next-Generation Sequencing (NGS).

Author

Terraneo TI, Mariappan KG, Forsman Z, and Arrigoni R

Subjects
Animals, Computational Biology, DNA, Gene Library, High-Throughput Nucleotide Sequencing methods, Sequence Analysis, DNA methods, Genome, Mitochondrial
Abstract

Mitochondrial genomes (mtgenome) represent an important source of information for addressing fundamental evolutionary, phylogeographic, systematic, and ecological questions in marine organisms. In the last two decades the advent of high-throughput next-generation sequencing (NGS) has provided an unprecedented possibility to access large amount of genomic data and, as such, there has been a rapid growth in mtgenome resources and studies. In particular, NGS strategies represent a great advantage for investigating nonmodel marine organisms for which no or limited genomic resources are available. Here, we describe a routinely used standardized protocol to obtain mtgenome of nonmodel marine organisms by NGS. The protocol is composed of five main steps, including DNA extraction, DNA fragmentation, library preparation, high-throughput sequencing, and bioinformatic analyses. Each of the first three steps is followed by size/quality and concentration validations. The advantages of the described protocol rely on the assumption that no a priori information on mtgenome of the studied organism is needed and on its versatility as researchers may choose several kits for DNA extraction and library preparation and adopt different methods for DNA fragmentation depending on their needs, experience, and suppliers., (© 2022. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published
2022
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21. A ubiquitous subcuticular bacterial symbiont of a coral predator, the crown-of-thorns starfish, in the Indo-Pacific.

Author

Wada N, Yuasa H, Kajitani R, Gotoh Y, Ogura Y, Yoshimura D, Toyoda A, Tang SL, Higashimura Y, Sweatman H, Forsman Z, Bronstein O, Eyal G, Thongtham N, Itoh T, Hayashi T, and Yasuda N

Subjects
Animals, Bacteria genetics, Coral Reefs, Indian Ocean, Male, Pacific Ocean, Phylogeny, RNA, Ribosomal, 16S genetics, Starfish genetics, Anthozoa, Bacteria isolation & purification, Predatory Behavior, Starfish microbiology, Starfish physiology, Symbiosis
Abstract

Background: Population outbreaks of the crown-of-thorns starfish (Acanthaster planci sensu lato; COTS), a primary predator of reef-building corals in the Indo-Pacific Ocean, are a major threat to coral reefs. While biological and ecological knowledge of COTS has been accumulating since the 1960s, little is known about its associated bacteria. The aim of this study was to provide fundamental information on the dominant COTS-associated bacteria through a multifaceted molecular approach., Methods: A total of 205 COTS individuals from 17 locations throughout the Indo-Pacific Ocean were examined for the presence of COTS-associated bacteria. We conducted 16S rRNA metabarcoding of COTS to determine the bacterial profiles of different parts of the body and generated a full-length 16S rRNA gene sequence from a single dominant bacterium, which we designated COTS27. We performed phylogenetic analysis to determine the taxonomy, screening of COTS27 across the Indo-Pacific, FISH to visualize it within the COTS tissues, and reconstruction of the bacterial genome from the hologenome sequence data., Results: We discovered that a single bacterium exists at high densities in the subcuticular space in COTS forming a biofilm-like structure between the cuticle and the epidermis. COTS27 belongs to a clade that presumably represents a distinct order (so-called marine spirochetes) in the phylum Spirochaetes and is universally present in COTS throughout the Indo-Pacific Ocean. The reconstructed genome of COTS27 includes some genetic traits that are probably linked to adaptation to marine environments and evolution as an extracellular endosymbiont in subcuticular spaces., Conclusions: COTS27 can be found in three allopatric COTS species, ranging from the northern Red Sea to the Pacific, implying that the symbiotic relationship arose before the speciation events (approximately 2 million years ago). The universal association of COTS27 with COTS and nearly mono-specific association at least with the Indo-Pacific COTS provides a useful model system for studying symbiont-host interactions in marine invertebrates and may have applications for coral reef conservation. Video Abstract.

Published
2020
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22. CoralCam: A flexible, low-cost ecological monitoring platform.

Author

Greene A, Forsman Z, Toonen RJ, and Donahue MJ

Abstract

The study and conservation of biological communities, such as coral reefs, frequently requires repeated surveys to measure the growth of organisms or the occurrence of ecological processes, such as recruitment, predation, competition, or mortality. In the case of coral reefs, processes influencing coral community structure occur on time scales of days (recruitment, predation), months (seasonal environmental stress), or years (competition for space). In both marine and terrestrial systems, observing the ecology of remote locations at fine temporal scales is made difficult by the high cost or complexity of resurveying the same location at high frequency. These restrictions have produced limited understanding of in-situ ecological processes which occur at fine temporal scales and influence community structure but are easily missed during infrequent surveys. We present a low-cost method for the conversion of consumer cameras into programmable time-lapse platforms, allowing scheduled daily video or photo capture in remote locations for extended time periods. Results of a 1-month deployment with twice-daily photo capture are presented. Total cost to construct and deploy CoralCam in-situ (up to 45 m) is approximately $80 USD, providing a low-cost platform for fine scale data collection where these data are not otherwise logistically or financially possible., Competing Interests: The authors declare that there is no conflict of interest regarding the publication of this article. Human and animal rights, (© 2019 The Authors.)

Published
2019
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23. Clone wars: asexual reproduction dominates in the invasive range of Tubastraea spp. (Anthozoa: Scleractinia) in the South-Atlantic Ocean.

Author

Capel KCC, Toonen RJ, Rachid CTCC, Creed JC, Kitahara MV, Forsman Z, and Zilberberg C

Abstract

Although the invasive azooxanthellate corals Tubastraea coccinea and T. tagusensis are spreading quickly and outcompeting native species in the Atlantic Ocean, there is little information regarding the genetic structure and path of introduction for these species. Here we present the first data on genetic diversity and clonal structure from these two species using a new set of microsatellite markers. High proportions of clones were observed, indicating that asexual reproduction has a major role in the local population dynamics and, therefore, represents one of the main reasons for the invasion success. Although no significant population structure was found, results suggest the occurrence of multiple invasions for T. coccinea and also that both species are being transported along the coast by vectors such as oil platforms and monobouys, spreading these invasive species. In addition to the description of novel microsatellite markers, this study sheds new light into the invasive process of Tubastraea ., Competing Interests: Robert J. Toonen is an Academic Editor for PeerJ.

Published
2017
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24. Coral hybridization or phenotypic variation? Genomic data reveal gene flow between Porites lobata and P. Compressa.

Author

Forsman ZH, Knapp ISS, Tisthammer K, Eaton DAR, Belcaid M, and Toonen RJ

Subjects
Animals, Genome, Mitochondrial, Geography, Hawaii, Likelihood Functions, Phenotype, Phylogeny, Polymorphism, Single Nucleotide genetics, Principal Component Analysis, Sequence Alignment, Species Specificity, Anthozoa genetics, Gene Flow genetics, Genomics methods, Hybridization, Genetic
Abstract

Major gaps remain in our understanding of the ecology, evolution, biodiversity, biogeography, extinction risk, and adaptive potential of reef building corals. One of the central challenges remains that there are few informative genetic markers for studying boundaries between species, and variation within species. Reduced representation sequencing approaches, such as RADseq (Restriction site Associated DNA sequencing) have great potential for resolving such relationships. However, it is necessary to identify loci in order to make inferences for endosymbiotic organisms such as corals. Here, we examined twenty-one coral holobiont ezRAD libraries from Hawai'i, focusing on P. lobata and P. compressa, two species with contrasting morphology and habitat preference that previous studies have not resolved. We used a combination of de novo assembly and reference mapping approaches to identify and compare loci: we used reference mapping to extract and compare nearly complete mitochondrial genomes, ribosomal arrays, and histone genes. We used de novo clustering and phylogenomic methods to compare the complete holobiont data set with coral and symbiont subsets that map to transcriptomic data. In addition, we used reference assemblies to examine genetic structure from SNPs (Single Nucleotide Polymorphisms). All approaches resolved outgroup taxa but failed to resolve P. lobata and P. compressa as distinct, with mito-nuclear discordance and shared mitochondrial haplotypes within the species complex. The holobiont and 'coral transcriptomic' datasets were highly concordant, revealing stronger genetic structure between sites than between coral morphospecies. These results suggest that either branching morphology is a polymorphic trait, or that these species frequently hybridize. This study provides examples of several approaches to acquire, identify, and compare loci across metagenomic samples such as the coral holobiont while providing insights into the nature of coral variability., (Copyright © 2017 Elsevier Inc. All rights reserved.)

Published
2017
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25. Clues to unraveling the coral species problem: distinguishing species from geographic variation in Porites across the Pacific with molecular markers and microskeletal traits.

Author

Forsman Z, Wellington GM, Fox GE, and Toonen RJ

Abstract

Morphological variation in the geographically widespread coral Porites lobata can make it difficult to distinguish from other massive congeneric species. This morphological variation could be attributed to geographic variability, phenotypic plasticity, or a combination of such factors. We examined genetic and microscopic morphological variability in P. lobata samples from the Galápagos, Easter Island, Tahiti, Fiji, Rarotonga, and Australia. Panamanian P. evermanni specimens were used as a previously established distinct outgroup against which to test genetic and morphological methods of discrimination. We employed a molecular analysis of variance (AMOVA) based on ribosomal internal transcribed spacer region (ITS) sequence, principal component analysis (PCA) of skeletal landmarks, and Mantel tests to compare genetic and morphological variation. Both genetic and morphometric methods clearly distinguished P. lobata and P. evermanni, while significant genetic and morphological variance was attributed to differences among geographic regions for P. lobata. Mantel tests indicate a correlation between genetic and morphological variation for P. lobata across the Pacific. Here we highlight landmark morphometric measures that correlate well with genetic differences, showing promise for resolving species of Porites, one of the most ubiquitous yet challenging to identify architects of coral reefs.

Published
2015
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26. Molecular delineation of species in the coral holobiont.

Author

Stat M, Baker AC, Bourne DG, Correa AM, Forsman Z, Huggett MJ, Pochon X, Skillings D, Toonen RJ, van Oppen MJ, and Gates RD

Subjects
Animals, Anthozoa genetics, Climate Change, Anthozoa classification, Anthozoa physiology, Biodiversity, Coral Reefs, Genetic Speciation
Abstract

The coral holobiont is a complex assemblage of organisms spanning a diverse taxonomic range including a cnidarian host, as well as various dinoflagellate, prokaryotic and acellular symbionts. With the accumulating information on the molecular diversity of these groups, binomial species classification and a reassessment of species boundaries for the partners in the coral holobiont is a logical extension of this work and will help enhance the capacity for comparative research among studies. To aid in this endeavour, we review the current literature on species diversity for the three best studied partners of the coral holobiont (coral, Symbiodinium, prokaryotes) and provide suggestions for future work on systematics within these taxa. We advocate for an integrative approach to the delineation of species using both molecular genetics in combination with phenetic characters. We also suggest that an a priori set of criteria be developed for each taxonomic group as no one species concept or accompanying set of guidelines is appropriate for delineating all members of the coral holobiont., (Copyright © 2012 Elsevier Ltd. All rights reserved.)

Published
2012
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