Your search keyword '"Christian R. Voolstra"' showing total 15 results

1. Algal symbioses with fire corals demonstrate host genotype specificity and niche adaptation at subspecies resolution

Author

Caroline E Dubé, Benjamin CC Hume, Emilie Boissin, Alexandre Mercière, Chloé A-F Bourmaud, Maren Ziegler, and Christian R Voolstra

Abstract

Corals share an intimate relationship with photosynthetic dinoflagellates that contribute to the biology of the emerging metaorganism. While many coral-algal associations exhibit high host fidelity, the extent of this specificity under environmental change remains to be fully understood and is a prerequisite to forecasting the adaptive potential of this obligate symbiosis. Here, we disentangled the contribution of host genotype and environment on governing coral-algae associations by working at subspecies resolution. We used fine-scale genotyping of algal symbionts from 198 fire coral colonies (Milleporacf.platyphylla)that map to ten distinct sexually produced clonal host genotypes across three environmentally distinct reef habitats. Based on microalgal ITS2 genotyping, we show that algal-host specificity extends down to the Symbiodiniaceae subspecies level in a natural reef environment. Closely relatedSymbiodinium(A7)-dominated algal assemblages almost perfectly mapped to fire coral host genotype. Furthermore, identification of host genotype- and habitat-specificSymbiodiniumalga suggest the presence of algal phenotypic diversity even at this taxonomic resolution (i.e., withinSymbiodiniumA7), which may aid environmental niche adaptation of the metaorganism. Our results suggest that the here-identifiedMillepora-Symbiodiniumassociations are co-evolved to match their prevailing environment. Thus, despite the presence of rarer host generalistCladocopiumalgae, scope for environmentally induced modification of the cnidarian-algal association is likely constrained by host genotype.

Published

2023

2. Coupled carbon and nitrogen cycling regulates the cnidarian-algal symbiosis

Author

Nils Rädecker, Stéphane Escrig, Jorge E. Spangenberg, Christian R. Voolstra, and Anders Meibom

Abstract

Efficient nutrient recycling underpins the ecological success of the cnidarian-algal symbiosis in oligotrophic waters that forms the basis of coral reef ecosystems. In a stable symbiosis, nitrogen limitation restricts the growth of algal endosymbionts and stimulates their release of photosynthates to the cnidarian animal host. However, the detailed mechanisms controlling nitrogen availabilityin hospiteand their role in symbiosis regulation remain poorly understood. Here, we studied the metabolic regulation of symbiotic nitrogen cycling in the sea anemone Aiptasia by experimentally altering labile carbon availability in a series of experiments. Using isotope labeling experiments and NanoSIMS imaging, we show that the competition for environmental ammonium between the host and its algal symbionts is regulated by carbon availability. Light regimes that were optimal for algal photosynthesis increased carbon availability in the holobiont and enhanced symbiotic competition for nitrogen. Consequently, algal symbiont densities were lowest under optimal environmental conditions and increased toward the tolerance limits of the symbiosis. This metabolic regulation promotes efficient carbon recycling in a stable symbiosis across a wide range of environmental conditions. At the same time, the dependence on resource competition can favor parasitic interactions that may explain the instability of the symbiosis as the environmental conditions in the Anthropocene shift towards its tolerance limits.

Published

2022

3. From genome wide SNPs to genomic islands of differentiation: the quest for species diagnostic markers in two scleractinian corals,PocilloporaandPorites

Author

Romane Deshuraud, Alexandre Ottaviani, Julie Poulain, Marine Leprêtre, Odette Beluche, Eric Mahieu, Sandrine Lebled, Caroline Belser, Alice Rouan, Clementine Moulin, Emilie Boissin, Guillaume Bourdin, Guillaume Iwankow, Sarah Romac, Sylvain Agostini, Bernard Banaigs, Emmanuel Boss, Chris Bowler, Colomban de Vargas, Eric Douville, Michel Flores, Paola Furla, Pierre Galand, Fabien Lombard, Stéphane Pesant, Stéphanie Reynaud, Matthew B Sullivan, Shinichi Sunagawa, Olivier Thomas, Romain Troublé, Rebecca Vega Thurber, Christian R. Voolstra, Patrick Wincker, Didier Zoccola, Serge Planes, Denis Allemand, Eric Gilson, and Didier Forcioli

Abstract

Coral reefs are of paramount importance in marine ecosystems, where they provide support for a large part of the biodiversity. Being quite sensitive to global changes, they are therefore the prime targets for biodiversity conservation policies. However, such conservation goals require accurate species identification, which are notoriously difficult to get in these highly morphologically variable organisms, rich in cryptic species. There is an acute need for easy-to-use and resolutive species diagnostic molecular markers. The present study builds on the huge sequencing effort developed during the TARA Pacific expedition to develop a genotyping strategy to assign coral samples to the correct species within two coral genera (PoritesandPocillopora). For this purpose, we developed a technique that we called “Divergent Fragment” based on the sequencing of a less than 2kb long diagnostic genomic fragment determined from the metagenomic data of a subset of the corals collected. This method has proven to be rapid, resolvable and cost-effective. Sequencing of PCR fragments nested along the species diagnostic fragment allowed us to assign 232 individuals of the genusPocilloporaand 247 individuals of the genusPoritesto previously identified independent genetic lineages (i.e. species). This genotyping method will allow to fully analyze the coral samples collected across the Pacific during the Tara Pacific expedition and opens technological perspectives in the field of population genomics-guided conservation.

Published

2022

4. Disparate patterns of genetic divergence in three widespread corals across a pan-Pacific environmental gradient highlights species-specific adaptation trajectories

Author

Benjamin C C Hume, Christian R Voolstra, Eric Armstrong, Guinther Mitushasi, Barbara Porro, Nicolas Oury, Sylvain Agostini, Emilie Boissin, Julie Poulain, Quentin Carradec, David A. Paz-García, Didier Zoccola, Hélène Magalon, Clémentine Moulin, Guillaume Bourdin, Guillaume Iwankow, Sarah Romac, Bernard Banaigs, Emmanuel Boss, Chris Bowler, Colomban de Vargas, Eric Douville, Michel Flores, Paola Furla, Pierre E Galand, Eric Gilson, Fabien Lombard, Stéphane Pesant, Stéphanie Reynaud, Matthew B. Sullivan, Shinichi Sunagawa, Olivier Thomas, Romain Troublé, Rebecca Vega Thurber, Patrick Wincker, Serge Planes, Denis Allemand, and Didier Forcioli

Abstract

Tropical coral reefs are among the worst affected ecosystems by climate change with predictions ranging between a 70-90% loss of reefs in the coming decades. Effective conservation strategies that maximize ecosystem resilience, and potential for recovery, must be informed by the accurate characterization of extant genetic diversity and population structure together with an understanding of the adaptive potential of keystone species. Here, we analyzed samples from theTaraPacific Expedition (2016 to 2018) that completed an 18,000 km longitudinal transect of the Pacific Ocean sampling three widespread corals –Pocillopora meandrina, Porites lobata, andMilleporacf.platyphylla– across 33 sites from 11 islands. Using deep metagenomic sequencing of 269 colonies in conjunction with morphological analyses and climate variability data we can show that the sampled transect encompasses multiple morphologically cryptic species that exhibit disparate biogeographic patterns, and most importantly, distinct evolutionary patterns, despite exposure to identical environmental regimes. Our findings demonstrate on a basin-scale that evolutionary trajectories are species-specific and complex, and can only in part be predicted from the environment. This highlights that conservation strategies must integrate multi-species investigations to consider the distinct genomic footprints shaped by selection as well as the genetic potential for adaptive change.

Published

2022

5. A Novel Bacterial Speciation Process Observed in a Symbiotic Marine Population

Author

Xiaojun Wang, Keigo Uematsu, Aubrie O’Rourke, Tetsuya Akita, Kei Kimura, Yuji Tomaru, Christian R Voolstra, and Haiwei Luo

Abstract

Bacteria undergo asexual reproduction, but genetic exchange is common. Current models posit that speciation of sexual bacteria is a gradual and long process, and genetic exchanges decrease but never cease between nascent species. Here, we show that in a panmictic bacterial lineage found in symbiosis with invertebrate hosts across multi-marine ecosystems, a series of speciation events occurred unusually fast with between-species genetic exchange approximating a complete halt. The speciation process is too rapid to sort out ancestral polymorphisms, giving rise to between-species phylogenetic incongruence at a genome-wide scale. This novel bacterial speciation process leads to incomplete lineage sorting, which to date has only been observed in eukaryotes but is 100-1000 times faster. Our finding allows for a more unified understanding of the speciation process across prokaryotes and eukaryotes.

Published

2022

6. Endogenous viral elements reveal associations between a non-retroviral RNA virus and symbiotic dinoflagellate genomes

Author

Alex J. Veglia, Kalia S.I. Bistolas, Christian R. Voolstra, Benjamin C. C. Hume, Serge Planes, Denis Allemand, Emilie Boissin, Patrick Wincker, Julie Poulain, Clémentine Moulin, Guillaume Bourdin, Guillaume Iwankow, Sarah Romac, Sylvain Agostini, Bernard Banaigs, Emmanuel Boss, Chris Bowler, Colomban de Vargas, Eric Douville, Michel Flores, Didier Forcioli, Paola Furla, Pierre Galand, Eric Gilson, Fabien Lombard, Stéphane Pesant, Stéphanie Reynaud, Shinichi Sunagawa, Olivier Thomas, Romain Troublé, Didier Zoccola, Adrienne M.S. Correa, and Rebecca L. Vega Thurber

Subjects

fungi

Abstract

Endogenous viral elements (EVEs) offer insight into the evolutionary histories and hosts of contemporary viruses. This study leveraged DNA metagenomics and genomics to detect and infer the host of a non-retroviral dinoflagellate-infecting +ssRNA virus (dinoRNAV) common in coral reefs. As part of the Tara Pacific Expedition, this study surveyed 269 newly sequenced cnidarians and their resident symbiotic dinoflagellates (Symbiodiniaceae), associated metabarcodes, and publicly available metagenomes, revealing 178 dinoRNAV EVEs, predominantly among hydrocoral-dinoflagellate metagenomes. Putative associations between Symbiodiniaceae and dinoRNAV EVEs were corroborated by the characterization of dinoRNAV-like sequences in 17 of 18 scaffold-scale and one chromosome-scale dinoflagellate genome assembly, flanked by characteristically cellular sequences and in proximity to retroelements, suggesting potential mechanisms of integration. EVEs were not detected in dinoflagellate-free (aposymbiotic) cnidarian genome assemblies, including stony corals, hydrocorals, jellyfish, or seawater. The pervasive nature of dinoRNAV EVEs within dinoflagellate genomes (especially Symbiodinium), as well as their inconsistent within-genome distribution and fragmented nature, suggest ancestral or recurrent integration of this virus with variable conservation. Broadly, these findings illustrate how +ssRNA viruses may obscure their genomes as members of nested symbioses, with implications for host evolution, exaptation, and immunity in the context of reef health and disease.

Published

2022

7. A comparative baseline of coral disease across the central Red Sea

Author

Christian R. Voolstra, Greta S. Aeby, Maren Ziegler, Thor Jensen, Thierry M. Work, and Amanda Shore

Subjects

geography, geography.geographical_feature_category, biology, Coral bleaching, Ecology, Effects of global warming on oceans, Coral, fungi, Black band disease, medicine.disease, biology.organism_classification, medicine, Transect, Reef, geographic locations, Skeletal eroding band, Environmental gradient

Abstract

The Red Sea is a unique environment for corals with a strong environmental gradient characterized by temperature extremes and high salinities, but minimal terrestrial runoff or riverine input and their associated pollution. Disease surveys were conducted along 22 reefs in the central Red Sea along the Saudi Arabian coast in October 2015, which coincided with a bleaching event. Our objectives were to 1) document types, prevalence, and distribution of coral diseases in a region with minimal terrestrial input, 2) compare regional differences in diseases and bleaching along a latitudinal gradient of environmental conditions, and 3) use histopathology to characterize disease lesions at the cellular level. Coral reefs of the central Red Sea had a widespread but a surprisingly low prevalence of disease (75,750 colonies. Twenty diseases were recorded affecting 16 coral taxa and included black band disease, white syndromes, endolithic hypermycosis, skeletal eroding band, growth anomalies and focal bleached patches. The three most common diseases were Acropora white syndrome (59.1% of the survey sites), Porites growth anomalies (40.9%), and Porites white syndrome (31.8%). Over half of the coral genera within transects had lesions and corals from the genera Acropora, Millepora and Lobophyllia were the most commonly affected. Cell-associated microbial aggregates were found in four coral genera resembling patterns found in the Indo-Pacific. Differences in disease prevalence, coral cover, amount of heat stress as measured by degree heating weeks (DHW) and extent of bleaching was evident among sites. Disease prevalence was not explained by coral cover or DHW, and a negative relationship between coral bleaching and disease prevalence was found. The northern-most sites off the coast of Yanbu had the highest average DHW values but absence of bleaching and the highest average disease prevalence was recorded. Our study provides a foundation and baseline data for coral disease prevalence in the Red Sea, which is projected to increase as a consequence of increased frequency and severity of ocean warming.

Published

2021

8. Chromosome-scale assembly of the coral endosymbiont Symbiodinium microadriaticum genome provides insight into the unique biology of dinoflagellate chromosomes

Author

Octavio R. Salazar, Manuel Aranda, Job Dekker, Ye Zhan, Christian R. Voolstra, and Ankita Nand

Subjects

biology, Evolutionary biology, Systems biology, Dinoflagellate, Chromosome, Genomics, Marine invertebrates, Mobile genetic elements, biology.organism_classification, Gene, Genome

Abstract

Dinoflagellates are major primary producers in the world’s oceans, the cause of harmful algal blooms, and endosymbionts of marine invertebrates. Much remains to be understood about their biology including their peculiar crystalline chromosomes. Here we used Hi-C to order short read-based sub-scaffolds into 94 chromosome-scale scaffolds of the genome of the coral endosymbiont Symbiodinium microadriaticum. Hi-C data show that chromosomes are folded as linear rods within which loci separated by up to several Mb are highly packed. Each chromosome is composed of a series of structural domains separated by boundaries. Genes are enriched towards the ends of chromosomes and are arranged in unidirectional blocks that alternate between top and bottom strands. Strikingly, the boundaries of chromosomal domains are positioned at sites where transcription of two gene blocks converges, indicating a correlation between gene orientation, transcription and chromosome folding. Some chromosomes are enriched for genes involved in specific biological processes (e.g., photosynthesis, and nitrogen-cycling), and functionally related genes tend to co-occur at adjacent sites in the genome. All chromosomes contain several repeated segments that are enriched in mobile elements. The assembly of the S. microadriaticum genome and initial description of its genetic and spatial organization provide a foundation for deeper exploration of the extraordinary biology of dinoflagellates and their chromosomes.

Published

2020

9. Diatom Modulation of Microbial Consortia Through Use of Two Unique Secondary Metabolites

Author

Michael A. Ochsenkühn, Gregory Behringer, Anny Cárdenas, Nizar Drou, Christian R. Voolstra, Cong Fei, Marc Arnoux, Ashley Isaac, Shady A. Amin, Ahmed A. Shibl, Miraflor P. Santos, and Kris C. Gunsalus

Subjects

Diatom, Abu dhabi, biology, Earth science, fungi, Environmental science, biology.organism_classification

Abstract

Unicellular eukaryotic phytoplankton, such as diatoms, rely on microbial communities for survival despite lacking specialized compartments to house microbiomes (e.g., animal gut). Microbial communities have been widely shown to benefit from diatom excretions that accumulate within the microenvironment surrounding phytoplankton cells, known as the phycosphere. However, mechanisms that enable diatoms and other unicellular eukaryotes to nurture specific microbiomes by fostering beneficial bacteria and repelling harmful ones are mostly unknown. We hypothesized that diatom exudates may attune microbial communities and employed an integrated multi-omics approach using the ubiquitous diatom Asterionellopsis glacialis to reveal how it modulates its naturally associated bacteria. We show that A. glacialis reprograms its transcriptional and metabolic profiles in response to bacteria to secrete a suite of central metabolites and two unusual secondary metabolites, rosmarinic acid and azelaic acid. While central metabolites are utilized by potential bacterial symbionts and opportunists alike, rosmarinic acid promotes attachment of beneficial bacteria to the diatom and simultaneously suppresses the attachment of opportunists. Similarly, azelaic acid enhances growth of beneficial bacteria, while simultaneously inhibiting growth of opportunistic ones. We further show that the bacterial response to azelaic acid is widespread in the world’s oceans and taxonomically restricted to a handful of bacterial genera. Our results demonstrate the innate ability of an important unicellular eukaryotic group to modulate their microbial consortia, similar to higher eukaryotes, using unique secondary metabolites that regulate bacterial growth and behavior inversely in different bacterial populations.

Published

2020

10. A framework forin situmolecular characterization of coral holobionts using nanopore sequencing

Author

Stefan Engelen, Benjamin C. C. Hume, Emilie Boissin, Serge Planes, Quentin Carradec, Maren Ziegler, Patrick Wincker, Julie Poulain, Christian R. Voolstra, and Corinne Cruaud

Subjects

Holobiont, geography, geography.geographical_feature_category, Coral, Context (language use), Computational biology, Nanopore sequencing, Coral reef, Microbiome, Biology, Marker gene, Reef

Abstract

Molecular characterization of the coral host and the microbial assemblages associated with it (referred to as the coral holobiont) is currently undertaken via marker gene sequencing. This requires bulky instruments and controlled laboratory conditions which are impractical for environmental experiments in remote areas. Recent advances in sequencing technologies now permit rapid sequencing in the field; however, development of specific protocols and pipelines for the effective processing of complex microbial systems are currently lacking. Here, we used a combination of 3 marker genes targeting the coral animal host, its symbiotic alga, and the associated bacterial microbiome to characterize 60 coral colonies collected and processedin situ, during theTaraPacific expedition. We used Oxford Nanopore Technologies to sequence marker gene amplicons and developed bioinformatics pipelines to analyze nanopore reads on a laptop, obtaining results in less than 24 hours. Reef scale network analysis of coral-associated bacteria reveals broadly distributed taxa, as well as host-specific associations. Protocols and tools used in this work may be applicable for rapid coral holobiont surveys, immediate adaptation of sampling strategy in the field, and to make informed and timely decisions in the context of the current challenges affecting coral reefs worldwide.

Published

2020

11. Aiptasia as a model to study metabolic diversity and specificity in cnidarian-dinoflagellate symbioses

Author

Paul Guagliardo, Manuel Aranda, Matt R. Kilburn, Mathieu Pernice, Gabriela Perna, Christian R. Voolstra, Nils Rädecker, and Jean-Baptiste Raina

Subjects

biology, Endowment, Research council, Political science, State government, Library science, biology.organism_classification, Aiptasia, Metabolic diversity

Abstract

The symbiosis between cnidarian hosts and microalgae of the genusSymbiodiniumprovides the foundation of coral reefs in oligotrophic waters. Understanding the nutrient-exchange between these partners is key to identifying the fundamental mechanisms behind this symbiosis. However, deciphering the individual role of host and algal partners in the uptake and cycling of nutrients has proven difficult, given the endosymbiotic nature of this relationship. In this study, we highlight the advantages of the emerging model system Aiptasia to investigate the metabolic diversity and specificity of cnidarian – dinoflagellate symbiosis. For this, we combined traditional measurements with nano-scale secondary ion mass spectrometry (NanoSIMS) and stable isotope labeling to investigate carbon and nitrogen cycling both at the organismal scale and the cellular scale. Our results suggest that the individual nutrient assimilation by hosts and symbionts depends on the identity of their respective symbiotic partner. Further,δ13C enrichment patterns revealed that alterations in carbon fixation rates only affected carbon assimilation in the cnidarian host but not the algal symbiont, suggesting a ‘selfish’ character of this symbiotic association. Based on our findings, we identify new venues for future research regarding the role and regulation of nutrient exchange in the cnidarian - dinoflagellate symbiosis. In this context, the model system approach outlined in this study constitutes a powerful tool set to address these questions.

Published

2017

12. DNA methylation regulates transcriptional homeostasis of algal endosymbiosis in the coral modelAiptasia

Author

Craig T. Michell, Guoxin Cui, Noura Ibrahim Omar Zahran, Yi Jin Liew, Christian R. Voolstra, Manuel Aranda Lastra, Maha J. Cziesielski, and Yong Li

Subjects

biology, medicine.disease, biology.organism_classification, Cell biology, Aposymbiotic, Histone, Transcription (biology), DNA methylation, medicine, biology.protein, Transcriptional regulation, Epigenetics, Aiptasia, Transcriptional noise

Abstract

The symbiotic relationship between cnidarians and dinoflagellates is the cornerstone of coral reef ecosystems. Although research is focusing on the molecular mechanisms underlying this symbiosis, the role of epigenetic mechanisms, which have been implicated in transcriptional regulation and acclimation to environmental change, is unknown. To assess the role of DNA methylation in the cnidarian-dinoflagellate symbiosis, we analyzed genome-wide CpG methylation, histone associations, and transcriptomic states of symbiotic and aposymbiotic anemones in the model systemAiptasia. We find methylated genes are marked by histone H3K36me3 and show significant reduction of spurious transcription and transcriptional noise, revealing a role of DNA methylation in the maintenance of transcriptional homeostasis. Changes in DNA methylation and expression show enrichment for symbiosis-related processes such as immunity, apoptosis, phagocytosis recognition and phagosome formation, and unveil intricate interactions between the underlying pathways. Our results demonstrate that DNA methylation provides an epigenetic mechanism of transcriptional homeostasis during symbiosis.

Published

2017

13. Coral reef carbonate budgets and ecological drivers in the naturally high temperature and high alkalinity environment of the Red Sea

Author

Till Röthig, Anna Krystyna Roik, Claudia Pogoreutz, and Christian R. Voolstra

Subjects

geography, geography.geographical_feature_category, biology, Ecology, Effects of global warming on oceans, Aragonite, fungi, Alkalinity, Coral reef, engineering.material, biology.organism_classification, chemistry.chemical_compound, chemistry, engineering, Carbonate, Environmental science, Ecosystem, Parrotfish, Reef

Abstract

The coral structural framework is crucial for maintaining reef ecosystem function and services. In the central Red Sea, a naturally high alkalinity is beneficial to reef growth, but rising water temperatures impair the calcification capacity of reef-building organisms. However, it is currently unknown how beneficial and detrimental factors affect the balance between calcification and erosion, and thereby the overall growth of the reef framework. To provide insight into present-day carbonate budgets and reef growth dynamics in the central Red Sea, we measuredin situnet-accretion and net-erosion rates (Gnet) by deployment of limestone blocks and estimated census-based carbonate budgets (Gbudget) in four reef sites along a cross-shelf gradient (25 km). We assessed abiotic variables (i.e., temperature, inorganic nutrients, and carbonate system variables) and biotic drivers (i.e., calcifier and bioeroder abundances). On average, total alkalinity AT(2346 - 2431 μmol kg−1), aragonite saturation state (4.5 - 5.2 Ωa), and pCO2(283 -315 μatm) were close to estimates of pre-industrial global ocean surface waters. Despite these calcification-favorable carbonate system conditions, Gnetand Gbudgetencompassed positive (offshore) and negative net-production (midshore-lagoon and exposed nearshore site) estimates. Notably, Gbudgetmaxima were lower compared to reef growth from pristine Indian Ocean sites. Yet, a comparison with historical data from the northern Red Sea suggests that overall reef growth in the Red Sea has likely remained similar since 1995. When assessing sites across the shelf gradient, ATcorrelated well with reef growth rates (ρ = 0.89), while temperature was a weaker, negative correlate (ρ = −0.71). Further, ATexplained about 65 % of Gbudgetin a best fitting distance-based linear model. Interestingly, parrotfish abundances added up to 82% of explained variation, further substantiating recent studies highlighting the importance of parrotfish to reef ecosystem function. Our study provides a baseline that will be particularly useful in assessing future trajectories of reef growth capacities in the Red Sea under continuous ocean warming and acidification.

Published

2017

14. Symbiodiniumgenomes reveal adaptive evolution of functions related to symbiosis

Author

Christian R. Voolstra, Sylvain Forêt, Madeleine J. H. van Oppen, Ira Cooke, Bruno Lapeyre, Huanle Liu, Victor H. Beltran, Cheong Xin Chan, Mark A. Ragan, David G. Bourne, Timothy G. Stephens, Raúl A. González-Pech, David J. Miller, and Pim Bongaerts

Subjects

Government, biology, Ecology, fungi, technology, industry, and agriculture, Library science, Genomics, biochemical phenomena, metabolism, and nutrition, biology.organism_classification, Genome, Great barrier reef, Symbiodinium, natural sciences, × Aranda, Adaptive evolution

Abstract

Symbiosis between dinoflagellates of the genusSymbiodiniumand reef-building corals forms the trophic foundation of the world’s coral reef ecosystems. Here we present the first draft genome ofSymbiodinium goreaui(Clade C, type C1: 1.03 Gbp), one of the most ubiquitous endosymbionts associated with corals, and an improved draft genome ofSymbiodinium kawagutii(Clade F, strain CS-156: 1.05 Gbp), previously sequenced as strain CCMP2468, to further elucidate genomic signatures of this symbiosis. Comparative analysis of four availableSymbiodiniumgenomes against other dinoflagellate genomes led to the identification of 2460 nuclear gene families that show evidence of positive selection, including genes involved in photosynthesis, transmembrane ion transport, synthesis and modification of amino acids and glycoproteins, and stress response. Further, we identified extensive sets of genes for meiosis and response to light stress. These draft genomes provide a foundational resource for advancing our understandingSymbiodiniumbiology and the coral-algal symbiosis.

Published

2017

15. Contrasting evolution of expression differences in the testis between species and subspecies of the house mouse

Author

Diethard Tautz, Bettina Harr, Patrick Farbrother, Ludwig Eichinger, and Christian R. Voolstra

Subjects

Male, Letter, Genetic Speciation, Mus spretus, Gene Expression, Subspecies, Kidney, House mouse, Evolution, Molecular, Sexual conflict, Mice, Species Specificity, Testis, Genetic algorithm, Genetics, Animals, Gene, Genetics (clinical), Oligonucleotide Array Sequence Analysis, Base Sequence, biology, Microarray analysis techniques, Gene Expression Profiling, Brain, biology.organism_classification, Mice, Inbred C57BL, Sexual selection

Abstract

Regulatory changes in genes involved in reproduction are thought to be prime targets for divergence during speciation, since they are expected to play an important role in sexual selection and sexual conflict. We used microarray analysis of RNA from different wild populations of house mouse subspecies (including Mus m. musculus, Mus m. domesticus, and Mus m. castaneus) and from the sister species Mus spretus to test this assumption. A comparison of expression divergence in brain, liver/kidney, and testis shows a major difference in the evolutionary dynamics of testis-related genes. While the comparison between species confirms an excess in divergence in testis genes, we find that all comparisons between subspecies yield only a very small number of genes with significantly different expression levels in the testis. These results suggest that the early phase of the speciation process may not be driven by regulatory changes in genes that are potential targets of sexual selection, and that the divergence in these genes is only established during a later phase of the speciation process.

Published

2006