Your search keyword '"Bourne, David"' showing total 43 results

1. Comparative genomics identifies key adaptive traits of sponge-associated microbial symbionts.

Author

O'Brien PA, Robbins SJ, Tan S, Rix L, Miller DJ, Webster NS, Zhang G, and Bourne DG

Subjects

Animals, Microbiota, Phylogeny, Genome, Bacterial, Symbiosis, Porifera microbiology, Genomics, Bacteria genetics, Bacteria classification, Bacteria metabolism

Abstract

Sponge microbiomes are often highly diverse making it difficult to determine which lineages are important for maintaining host health and homeostasis. Characterising genomic traits associated with symbiosis can improve our knowledge of which lineages have adapted to their host and what functions they might provide. Here we examined five microbial families associated with sponges that have previously shown evidence of cophylogeny, including Endozoicomonadaceae, Nitrosopumilaceae, Spirochaetaceae, Microtrichaceae and Thermoanaerobaculaceae, to better understand the mechanisms behind their symbiosis. We compared sponge-associated genomes to genomes found in other environments and found that sponge-specific clades were enriched in genes encoding many known mechanisms for symbiont survival, such as avoiding phagocytosis and defence against foreign genetic elements. We expand on previous knowledge to show that glycosyl hydrolases with sulfatases and sulfotransferases likely form multienzyme degradation pathways to break and remodel sulfated polysaccharides and reveal an enrichment in superoxide dismutase that may prevent damage from free oxygen radicals produced by the host. Finally, we identified novel traits in sponge-associated symbionts, such as urea metabolism in Spirochaetaceae which was previously shown to be rare in the phylum Spirochaetota. These results identify putative mechanisms by which symbionts have adapted to living in association with sponges., (© 2024 Commonwealth of Australia and The Author(s). Environmental Microbiology published by John Wiley & Sons Ltd.)

Published

2024

2. The coral microbiome in sickness, in health and in a changing world.

Author

Voolstra CR, Raina JB, Dörr M, Cárdenas A, Pogoreutz C, Silveira CB, Mohamed AR, Bourne DG, Luo H, Amin SA, and Peixoto RS

Subjects

Animals, Coral Reefs, Anthozoa microbiology, Microbiota physiology, Climate Change, Symbiosis, Bacteria classification, Bacteria genetics, Bacteria metabolism

Abstract

Stony corals, the engines and engineers of reef ecosystems, face unprecedented threats from anthropogenic environmental change. Corals are holobionts that comprise the cnidarian animal host and a diverse community of bacteria, archaea, viruses and eukaryotic microorganisms. Recent research shows that the bacterial microbiome has a pivotal role in coral biology. A healthy bacterial assemblage contributes to nutrient cycling and stress resilience, but pollution, overfishing and climate change can break down these symbiotic relationships, which results in disease, bleaching and, ultimately, coral death. Although progress has been made in characterizing the spatial-temporal diversity of bacteria, we are only beginning to appreciate their functional contribution. In this Review, we summarize the ecological and metabolic interactions between bacteria and other holobiont members, highlight the biotic and abiotic factors influencing the structure of bacterial communities and discuss the impact of climate change on these communities and their coral hosts. We emphasize how microbiome-based interventions can help to decipher key mechanisms underpinning coral health and promote reef resilience. Finally, we explore how recent technological developments may be harnessed to address some of the most pressing challenges in coral microbiology, providing a road map for future research in this field., (© 2024. Springer Nature Limited.)

Published

2024

3. Comparative genome-centric analysis reveals seasonal variation in the function of coral reef microbiomes.

Author

Glasl B, Robbins S, Frade PR, Marangon E, Laffy PW, Bourne DG, and Webster NS

Subjects

Animals, Archaea genetics, Bacteria classification, Bacteria isolation & purification, Biomass, Coral Reefs, Metagenome, Seasons, Seawater microbiology, Seaweed classification, Bacteria genetics, Microbiota, Porifera microbiology, Seaweed genetics

Abstract

Microbially mediated processes contribute to coral reef resilience yet, despite extensive characterisation of microbial community variation following environmental perturbation, the effect on microbiome function is poorly understood. We undertook metagenomic sequencing of sponge, macroalgae and seawater microbiomes from a macroalgae-dominated inshore coral reef to define their functional potential and evaluate seasonal shifts in microbially mediated processes. In total, 125 high-quality metagenome-assembled genomes were reconstructed, spanning 15 bacterial and 3 archaeal phyla. Multivariate analysis of the genomes relative abundance revealed changes in the functional potential of reef microbiomes in relation to seasonal environmental fluctuations (e.g. macroalgae biomass, temperature). For example, a shift from Alphaproteobacteria to Bacteroidota-dominated seawater microbiomes occurred during summer, resulting in an increased genomic potential to degrade macroalgal-derived polysaccharides. An 85% reduction of Chloroflexota was observed in the sponge microbiome during summer, with potential consequences for nutrition, waste product removal, and detoxification in the sponge holobiont. A shift in the Firmicutes:Bacteroidota ratio was detected on macroalgae over summer with potential implications for polysaccharide degradation in macroalgal microbiomes. These results highlight that seasonal shifts in the dominant microbial taxa alter the functional repertoire of host-associated and seawater microbiomes, and highlight how environmental perturbation can affect microbially mediated processes in coral reef ecosystems.

Published

2020

4. A genomic view of the reef-building coral Porites lutea and its microbial symbionts.

Author

Robbins SJ, Singleton CM, Chan CX, Messer LF, Geers AU, Ying H, Baker A, Bell SC, Morrow KM, Ragan MA, Miller DJ, Forêt S, Voolstra CR, Tyson GW, and Bourne DG

Subjects

Animals, Anthozoa metabolism, Coral Reefs, Dinoflagellida genetics, Metagenomics, Microbiota, Anthozoa microbiology, Archaea genetics, Bacteria genetics, Genome, Symbiosis

Abstract

Corals and the reef ecosystems that they support are in global decline due to increasing anthropogenic pressures such as climate change 1 . However, effective reef conservation strategies are hampered by a limited mechanistic understanding of coral biology and the functional roles of the diverse microbial communities that underpin coral health 2,3 . Here, we present an integrated genomic characterization of the coral species Porites lutea and its microbial partners. High-quality genomes were recovered from P. lutea, as well as a metagenome-assembled Cladocopium C15 (the dinoflagellate symbiont) and 52 bacterial and archaeal populations. Comparative genomic analysis revealed that many of the bacterial and archaeal genomes encode motifs that may be involved in maintaining association with the coral host and in supplying fixed carbon, B-vitamins and amino acids to their eukaryotic partners. Furthermore, mechanisms for ammonia, urea, nitrate, dimethylsulfoniopropionate and taurine transformation were identified that interlink members of the holobiont and may be important for nutrient acquisition and retention in oligotrophic waters. Our findings demonstrate the critical and diverse roles that microorganisms play within the coral holobiont and underscore the need to consider all of the components of the holobiont if we are to effectively inform reef conservation strategies.

Published

2019

5. Characterization of coral-associated microbial aggregates (CAMAs) within tissues of the coral Acropora hyacinthus.

Author

Wada N, Ishimochi M, Matsui T, Pollock FJ, Tang SL, Ainsworth TD, Willis BL, Mano N, and Bourne DG

Subjects

Animals, Anthozoa physiology, Australia, Bacteria genetics, Coral Reefs, DNA, Bacterial isolation & purification, In Situ Hybridization, Fluorescence, Japan, Phylogeny, RNA, Ribosomal, 16S genetics, Sequence Analysis, DNA, Anthozoa microbiology, Bacteria isolation & purification, Microbiota genetics, Symbiosis

Abstract

Bacterial diversity associated with corals has been studied extensively, however, localization of bacterial associations within the holobiont is still poorly resolved. Here we provide novel insight into the localization of coral-associated microbial aggregates (CAMAs) within tissues of the coral Acropora hyacinthus. In total, 318 and 308 CAMAs were characterized via histological and fluorescent in situ hybridization (FISH) approaches respectively, and shown to be distributed extensively throughout coral tissues collected from five sites in Japan and Australia. The densities of CAMAs within the tissues were negatively correlated with the distance from the coastline (i.e. lowest densities at offshore sites). CAMAs were randomly distributed across the six coral tissue regions investigated. Within each CAMA, bacterial cells had similar morphological characteristics, but bacterial morphologies varied among CAMAs, with at least five distinct types identified. Identifying the location of microorganisms associated with the coral host is a prerequisite for understanding their contributions to fitness. Localization of tissue-specific communities housed within CAMAs is particularly important, as these communities are potentially important contributors to vital metabolic functions of the holobiont.

Published

2019

6. Diversity of deep-water coral-associated bacteria and comparison across depth gradients.

Author

Jensen S, Hovland M, Lynch MDJ, and Bourne DG

Subjects

Animals, Anthozoa classification, Bacteria classification, Bacteria genetics, Coral Reefs, Host Specificity, Microbiota genetics, Norway, RNA, Ribosomal, 16S genetics, Anthozoa microbiology, Bacteria isolation & purification, Biodiversity, Seawater microbiology

Abstract

Environmental conditions influence species composition, including the microbial communities that associate with benthic organisms such as corals. In this study we identified and compared bacteria that associate with three common deep-water corals, Lophelia pertusa, Madrepora oculata and Paragorgia arborea, from a reef habitat on the mid-Norwegian shelf. The 16S rRNA gene amplicon sequencing data obtained revealed that >50% of sequences were represented by only five operational taxonomic units. Three were host-specific and unclassified below class level, belonging to Alphaproteobacteria with affiliation to members of the Rhizobiales order (L. pertusa), Flavobacteria affiliated with members of the Elisabethkingia genus (M. oculata) and Mollicutes sequences affiliated with the Mycoplasma genus (P. arborea). In addition, gammaproteobacterial sequences within the genera Sulfitobacter and Oleispira were found across all three deep-water coral taxa. Although highly abundant in the coral microbiomes, these sequences accounted for <0.1% of the surrounding bacterioplankton, supporting specific relationships. We combined this information with previous studies, undertaking a meta-data analysis of 165 widespread samples across coral hosts and habitats. Patterns in bacterial diversity indicated enrichment of distinct uncultured species in coral microbiomes that differed among deep (>200 m), mesophotic (30-200 m) and shallow (<30 m) reefs., (© FEMS 2019.)

Published

2019

7. Coral-associated bacteria demonstrate phylosymbiosis and cophylogeny.

Author

Pollock FJ, McMinds R, Smith S, Bourne DG, Willis BL, Medina M, Thurber RV, and Zaneveld JR

Subjects

Animals, Anthozoa classification, Archaea classification, Australia, Bacteria classification, Coral Reefs, DNA, Mitochondrial genetics, Geography, Phylogeny, RNA, Ribosomal genetics, RNA, Ribosomal, 16S genetics, Sequence Analysis, DNA, Symbiosis, Anthozoa genetics, Anthozoa microbiology, Archaea genetics, Bacteria genetics, Microbiota genetics

Abstract

Scleractinian corals' microbial symbionts influence host health, yet how coral microbiomes assembled over evolution is not well understood. We survey bacterial and archaeal communities in phylogenetically diverse Australian corals representing more than 425 million years of diversification. We show that coral microbiomes are anatomically compartmentalized in both modern microbial ecology and evolutionary assembly. Coral mucus, tissue, and skeleton microbiomes differ in microbial community composition, richness, and response to host vs. environmental drivers. We also find evidence of coral-microbe phylosymbiosis, in which coral microbiome composition and richness reflect coral phylogeny. Surprisingly, the coral skeleton represents the most biodiverse coral microbiome, and also shows the strongest evidence of phylosymbiosis. Interactions between bacterial and coral phylogeny significantly influence the abundance of four groups of bacteria-including Endozoicomonas-like bacteria, which divide into host-generalist and host-specific subclades. Together these results trace microbial symbiosis across anatomy during the evolution of a basal animal lineage.

Published

2018

8. Crown-of-Thorns Sea Star Acanthaster cf. solaris Has Tissue-Characteristic Microbiomes with Potential Roles in Health and Reproduction.

Author

Høj L, Levy N, Baillie BK, Clode PL, Strohmaier RC, Siboni N, Webster NS, Uthicke S, and Bourne DG

Subjects

Animal Diseases, Animals, Australia, Coral Reefs, Dysbiosis, Male, Phylogeny, Seawater microbiology, Spiroplasma, Symbiosis, Tenericutes, Bacteria classification, Host Microbial Interactions physiology, Microbiota physiology, Reproduction, Starfish microbiology

Abstract

Outbreaks of coral-eating crown-of-thorns sea stars (CoTS; Acanthaster species complex) cause substantial coral loss; hence, there is considerable interest in developing prevention and control strategies. We characterized the microbiome of captive CoTS and assessed whether dysbiosis was evident in sea stars during a disease event. Most tissue types had a distinct microbiome. The exception was female gonads, in which the microbiomes were highly variable among individuals. Male gonads were dominated (>97% of reads) by a single Mollicutes -related operational taxonomic unit (OTU). Detailed phylogenetic and microscopy analysis demonstrated the presence of a novel Spiroplasma -related bacterium in the spermatogenic layer. Body wall samples had high relative abundance (43 to 64% of reads) of spirochetes, likely corresponding to subcuticular symbionts reported from many echinoderms. Tube feet were characterized by Hyphomonadaceae (24 to 55% of reads). Pyloric cecal microbiomes had high alpha diversity, comprising many taxa commonly found in gastrointestinal systems. The order Oceanospirillales (genera Endozoicomonas and Kistimonas ) was detected in all tissues. A microbiome shift occurred in diseased individuals although differences between tissue types were retained. The relative abundance of spirochetes was significantly reduced in diseased individuals. Kistimonas was present in all diseased individuals and significantly associated with diseased tube feet, but its role in disease causation is unknown. While Arcobacter was significantly associated with diseased tissues and Vibrionaceae increased in diversity, no single OTU was detected in all diseased individuals, suggesting opportunistic proliferation of these taxa in this case. This study shows that CoTS have tissue-characteristic bacterial communities and identifies taxa that could play a role in reproduction and host health. IMPORTANCE Coral-eating crown-of-thorns sea stars (CoTS; Acanthaster species complex) are native to the Indo-Pacific, but during periodic population outbreaks they can reach extreme densities (>1,000 starfish per hectare) and function as a pest species. On the Great Barrier Reef, Australia, CoTS have long been considered one of the major contributors to coral loss. There has been significant investment in a targeted control program using lethal injection, and there is interest in developing additional and complementary technologies that can increase culling efficiencies. The biology of CoTS has been studied extensively, but little is known about their associated microbiome. This cultivation-independent analysis of the CoTS microbiome provides a baseline for future analyses targeting the functional role of symbionts, the identification of pathogens, or the development of reproduction manipulators., (© Crown copyright 2018.)

Published

2018

9. Subcellular tracking reveals the location of dimethylsulfoniopropionate in microalgae and visualises its uptake by marine bacteria.

Author

Raina JB, Clode PL, Cheong S, Bougoure J, Kilburn MR, Reeder A, Forêt S, Stat M, Beltran V, Thomas-Hall P, Tapiolas D, Motti CM, Gong B, Pernice M, Marjo CE, Seymour JR, Willis BL, and Bourne DG

Subjects

Isotope Labeling, Spectrometry, Mass, Secondary Ion, Sulfur Isotopes analysis, Aquatic Organisms chemistry, Aquatic Organisms metabolism, Bacteria chemistry, Bacteria metabolism, Microalgae chemistry, Microalgae metabolism, Sulfonium Compounds analysis

Abstract

Phytoplankton-bacteria interactions drive the surface ocean sulfur cycle and local climatic processes through the production and exchange of a key compound: dimethylsulfoniopropionate (DMSP). Despite their large-scale implications, these interactions remain unquantified at the cellular-scale. Here we use secondary-ion mass spectrometry to provide the first visualization of DMSP at sub-cellular levels, tracking the fate of a stable sulfur isotope ( 34 S) from its incorporation by microalgae as inorganic sulfate to its biosynthesis and exudation as DMSP, and finally its uptake and degradation by bacteria. Our results identify for the first time the storage locations of DMSP in microalgae, with high enrichments present in vacuoles, cytoplasm and chloroplasts. In addition, we quantify DMSP incorporation at the single-cell level, with DMSP-degrading bacteria containing seven times more 34 S than the control strain. This study provides an unprecedented methodology to label, retain, and image small diffusible molecules, which can be transposable to other symbiotic systems.

Published

2017

10. Seagrass ecosystems reduce exposure to bacterial pathogens of humans, fishes, and invertebrates.

Author

Lamb JB, van de Water JA, Bourne DG, Altier C, Hein MY, Fiorenza EA, Abu N, Jompa J, and Harvell CD

Subjects

Animals, Bacteria classification, Bacteria genetics, Bacteria isolation & purification, Environmental Exposure, Health, Humans, Phylogeny, RNA, Ribosomal, 16S genetics, Sequence Analysis, DNA, Anthozoa microbiology, Bacteria pathogenicity, Biodiversity, Fish Diseases microbiology, Fishes microbiology, Seawater microbiology, Waterborne Diseases microbiology

Abstract

Plants are important in urban environments for removing pathogens and improving water quality. Seagrass meadows are the most widespread coastal ecosystem on the planet. Although these plants are known to be associated with natural biocide production, they have not been evaluated for their ability to remove microbiological contamination. Using amplicon sequencing of the 16 S ribosomal RNA gene, we found that when seagrass meadows are present, there was a 50% reduction in the relative abundance of potential bacterial pathogens capable of causing disease in humans and marine organisms. Moreover, field surveys of more than 8000 reef-building corals located adjacent to seagrass meadows showed twofold reductions in disease levels compared to corals at paired sites without adjacent seagrass meadows. These results highlight the importance of seagrass ecosystems to the health of humans and other organisms., (Copyright © 2017, American Association for the Advancement of Science.)

Published

2017

11. White Syndrome-Affected Corals Have a Distinct Microbiome at Disease Lesion Fronts.

Author

Pollock FJ, Wada N, Torda G, Willis BL, and Bourne DG

Subjects

Animals, Bacteria genetics, Coral Reefs, Queensland, Seasons, Anthozoa microbiology, Bacteria isolation & purification, Microbiota

Abstract

Coral tissue loss diseases, collectively known as white syndromes (WSs), induce significant mortality on reefs throughout the Indo-Pacific, yet definitive confirmation of WS etiologies remains elusive. In this study, we integrated ecological disease monitoring, bacterial community profiling, in situ visualization of microbe-host interactions, and cellular responses of the host coral through an 18-month repeated-sampling regime. We assert that the observed pathogenesis of WS lesions on acroporid corals at Lizard Island (Great Barrier Reef) is not the result of apoptosis or infection by Vibrio bacteria, ciliates, fungi, cyanobacteria, or helminths. Histological analyses detected helminths, ciliates, fungi, and cyanobacteria in fewer than 25% of WS samples, and helminths and fungi were also observed in 12% of visually healthy samples. The abundances of Vibrio-affiliated sequences (assessed using 16S rRNA amplicon sequencing) did not differ significantly between health states and never exceeded 3.3% of reads in any individual sample. In situ visualization detected Vibrio bacteria only in summer WS lesion samples and revealed no signs of these bacteria in winter disease samples (or any healthy tissue samples), despite continued disease progression year round. However, a 4-fold increase in Rhodobacteraceae-affiliated bacterial sequences at WS lesion fronts suggests that this group of bacteria could play a role in WS pathogenesis and/or serve as a diagnostic criterion for disease differentiation. While the causative agent(s) underlying WSs remains elusive, the microbial and cellular processes identified in this study will help to identify and differentiate visually similar but potentially distinct WS etiologies., Importance: Over the past decade, a virulent group of coral diseases known as white syndromes have impacted coral reefs throughout the Indian and Pacific Oceans. This article provides a detailed case study of white syndromes to combine disease ecology, high-throughput microbial community profiling, and cellular-scale host-microbe visualization over seasonal time scales. We provide novel insights into the etiology of this devastating disease and reveal new diagnostic criteria that could be used to differentiate visually similar but etiologically distinct forms of white syndrome., (Copyright © 2016 American Society for Microbiology.)

Published

2016

12. Insights into the Coral Microbiome: Underpinning the Health and Resilience of Reef Ecosystems.

Author

Bourne DG, Morrow KM, and Webster NS

Subjects

Animals, Anthozoa genetics, Bacteria classification, Bacteria genetics, Bacteria growth & development, Coral Reefs, Ecosystem, Fungi classification, Fungi genetics, Fungi growth & development, Anthozoa microbiology, Anthozoa physiology, Bacteria isolation & purification, Fungi isolation & purification, Microbiota

Abstract

Corals are fundamental ecosystem engineers, creating large, intricate reefs that support diverse and abundant marine life. At the core of a healthy coral animal is a dynamic relationship with microorganisms, including a mutually beneficial symbiosis with photosynthetic dinoflagellates (Symbiodinium spp.) and enduring partnerships with an array of bacterial, archaeal, fungal, protistan, and viral associates, collectively termed the coral holobiont. The combined genomes of this coral holobiont form a coral hologenome, and genomic interactions within the hologenome ultimately define the coral phenotype. Here we integrate contemporary scientific knowledge regarding the ecological, host-specific, and environmental forces shaping the diversity, specificity, and distribution of microbial symbionts within the coral holobiont, explore physiological pathways that contribute to holobiont fitness, and describe potential mechanisms for holobiont homeostasis. Understanding the role of the microbiome in coral resilience, acclimation, and environmental adaptation is a new frontier in reef science that will require large-scale collaborative research efforts.

Published

2016

13. The coral core microbiome identifies rare bacterial taxa as ubiquitous endosymbionts.

Author

D Ainsworth T, Krause L, Bridge T, Torda G, Raina JB, Zakrzewski M, Gates RD, Padilla-Gamiño JL, Spalding HL, Smith C, Woolsey ES, Bourne DG, Bongaerts P, Hoegh-Guldberg O, and Leggat W

Subjects

Animals, Bacteria genetics, DNA, Bacterial analysis, Dinoflagellida genetics, Phylogeny, Sequence Analysis, DNA, Symbiosis genetics, Anthozoa microbiology, Bacteria isolation & purification, Microbiota genetics

Abstract

Despite being one of the simplest metazoans, corals harbor some of the most highly diverse and abundant microbial communities. Differentiating core, symbiotic bacteria from this diverse host-associated consortium is essential for characterizing the functional contributions of bacteria but has not been possible yet. Here we characterize the coral core microbiome and demonstrate clear phylogenetic and functional divisions between the micro-scale, niche habitats within the coral host. In doing so, we discover seven distinct bacterial phylotypes that are universal to the core microbiome of coral species, separated by thousands of kilometres of oceans. The two most abundant phylotypes are co-localized specifically with the corals' endosymbiotic algae and symbiont-containing host cells. These bacterial symbioses likely facilitate the success of the dinoflagellate endosymbiosis with corals in diverse environmental regimes.

Published

2015

14. The coral immune response facilitates protection against microbes during tissue regeneration.

Author

van de Water JA, Ainsworth TD, Leggat W, Bourne DG, Willis BL, and van Oppen MJ

Subjects

Animals, Bacteria isolation & purification, Immunity, Innate, Nod Signaling Adaptor Proteins genetics, Signal Transduction, Toll-Like Receptors genetics, Anthozoa immunology, Anthozoa microbiology, Bacteria pathogenicity, Regeneration

Abstract

Increasing physical damage on coral reefs from predation, storms and anthropogenic disturbances highlights the need to understand the impact of injury on the coral immune system. In this study, we examined the regulation of the coral immune response over 10 days following physical trauma artificially inflicted on in situ colonies of the coral Acropora aspera, simultaneously with bacterial colonization of the lesions. Corals responded to injury by increasing the expression of immune system-related genes involved in the Toll-like and NOD-like receptor signalling pathways and the lectin-complement system in three phases (<2, 4 and 10 days post-injury). Phenoloxidase activity was also significantly upregulated in two phases (<3 and 10 days post-injury), as were levels of non-fluorescent chromoprotein. In addition, green fluorescent protein expression was upregulated in response to injury from 4 days post-injury, while cyan fluorescent protein expression was reduced. No shifts in the composition of coral-associated bacterial communities were evident following injury based on 16S rRNA gene amplicon pyrosequencing. Bacteria-specific fluorescence in situ hybridization also showed no evidence of bacterial colonization of the wound or regenerating tissues. Coral tissues showed near-complete regeneration of lesions within 10 days. This study demonstrates that corals exhibit immune responses that support rapid recovery following physical injury, maintain coral microbial homeostasis and prevent bacterial infestation that may compromise coral fitness., (© 2015 John Wiley & Sons Ltd.)

Published

2015

15. Natural volcanic CO2 seeps reveal future trajectories for host-microbial associations in corals and sponges.

Author

Morrow KM, Bourne DG, Humphrey C, Botté ES, Laffy P, Zaneveld J, Uthicke S, Fabricius KE, and Webster NS

Subjects

Animals, Anthozoa physiology, Bacteria classification, Bacteria genetics, Bacteria isolation & purification, Carbon Dioxide metabolism, Photosynthesis, Porifera physiology, Seawater chemistry, Symbiosis, Anthozoa microbiology, Bacteria metabolism, Carbon Dioxide analysis, Porifera microbiology, Seawater microbiology, Volcanic Eruptions analysis

Abstract

Atmospheric carbon dioxide (CO2) levels are rapidly rising causing an increase in the partial pressure of CO2 (pCO2) in the ocean and a reduction in pH known as ocean acidification (OA). Natural volcanic seeps in Papua New Guinea expel 99% pure CO2 and thereby offer a unique opportunity to explore the effects of OA in situ. The corals Acropora millepora and Porites cylindrica were less abundant and hosted significantly different microbial communities at the CO2 seep than at nearby control sites <500 m away. A primary driver of microbial differences in A. millepora was a 50% reduction of symbiotic Endozoicomonas. This loss of symbiotic taxa from corals at the CO2 seep highlights a potential hurdle for corals to overcome if they are to adapt to and survive OA. In contrast, the two sponges Coelocarteria singaporensis and Cinachyra sp. were ∼ 40-fold more abundant at the seep and hosted a significantly higher relative abundance of Synechococcus than sponges at control sites. The increase in photosynthetic microbes at the seep potentially provides these species with a nutritional benefit and enhanced scope for growth under future climate scenarios (thus, flexibility in symbiosis may lead to a larger niche breadth). The microbial community in the apparently pCO2-sensitive sponge species S. massa was not significantly different between sites. These data show that responses to elevated pCO2 are species-specific and that the stability and flexibility of microbial partnerships may have an important role in shaping and contributing to the fitness and success of some hosts.

Published

2015

16. Onset and establishment of diazotrophs and other bacterial associates in the early life history stages of the coral Acropora millepora.

Author

Lema KA, Bourne DG, and Willis BL

Subjects

Animals, Anthozoa growth & development, Bacteria genetics, Genes, Bacterial, Life Cycle Stages, Molecular Sequence Data, RNA, Ribosomal, 16S genetics, Sequence Analysis, DNA, Anthozoa microbiology, Bacteria classification, Phylogeny, Symbiosis

Abstract

Early establishment of coral-microbial symbioses is fundamental to the fitness of corals, but comparatively little is known about the onset and succession of bacterial communities in their early life history stages. In this study, bacterial associates of the coral Acropora millepora were characterized throughout the first year of life, from larvae and 1-week-old juveniles reared in laboratory conditions in the absence of the dinoflagellate endosymbiont Symbiodinium to field-outplanted juveniles with established Symbiodinium symbioses, and sampled at 2 weeks and at 3, 6 and 12 months. Using an amplicon pyrosequencing approach, the diversity of both nitrogen-fixing bacteria and of bacterial communities overall was assessed through analysis of nifH and 16S rRNA genes, respectively. The consistent presence of sequences affiliated with diazotrophs of the order Rhizobiales (23-58% of retrieved nifH sequences; 2-12% of 16S rRNA sequences), across all samples from larvae to 12-month-old coral juveniles, highlights the likely functional importance of this nitrogen-fixing order to the coral holobiont. Dominance of Roseobacter-affiliated sequences (>55% of retrieved 16S rRNA sequences) in larvae and 1-week-old juveniles, and the consistent presence of sequences related to Oceanospirillales and Altermonadales throughout all early life history stages, signifies their potential importance as coral associates. Increased diversity of bacterial communities once juveniles were transferred to the field, particularly of Cyanobacteria and Deltaproteobacteria, demonstrates horizontal (environmental) uptake of coral-associated bacterial communities. Although overall bacterial communities were dynamic, bacteria with likely important functional roles remain stable throughout early life stages of Acropora millepora., (© 2014 John Wiley & Sons Ltd.)

Published

2014

17. Amplicon pyrosequencing reveals spatial and temporal consistency in diazotroph assemblages of the Acropora millepora microbiome.

Author

Lema KA, Willis BL, and Bourne DG

Subjects

Animals, Bacteria genetics, Bacteria isolation & purification, Oxidoreductases genetics, Proteobacteria classification, Proteobacteria genetics, Proteobacteria isolation & purification, RNA, Ribosomal, 16S genetics, Sequence Analysis, DNA, Anthozoa microbiology, Bacteria classification, Microbiota genetics, Nitrogen Fixation genetics

Abstract

Diazotrophic bacteria potentially play an important functional role in supplying fixed nitrogen to the coral holobiont, but the value of such a partnership depends on the stability of the association. Here we evaluate the composition of diazotroph assemblages associated with the coral Acropora millepora throughout four seasons and at two reefs, an inshore and an offshore (mid-shelf) reef on the Great Barrier Reef, Australia. Amplicon pyrosequencing of the nifH gene revealed that diazotrophs are ubiquitous members of the bacterial community associated with A. millepora. Rhizobia (65% of the overall nifH sequences retrieved) and particularly Bradyrhizobia sp.-affiliated sequences (> 50% of rhizobia sequences) dominated diazotrophic assemblages across all coral samples from the two sites throughout the year. In contrast to this consistency in the spatial and temporal patterns of occurrence of diazotroph assemblages, the overall coral-associated bacterial community, assessed through amplicon sequencing of the general bacterial 16S ribosomal RNA gene, differed between inshore and mid-shelf reef locations. Sequences associated with the Oceanospirillales family, particularly with Endozoicomonas sp., dominated bacterial communities associated with inshore corals. Although rhizobia represented a variable and generally small fraction of the overall bacterial community associated with A. millepora, consistency in the structure of these diazotrophic assemblages suggests that they have a functional role in the coral holobiont., (© 2013 Society for Applied Microbiology and John Wiley & Sons Ltd.)

Published

2014

18. Sulfur-oxidizing bacterial populations within cyanobacterial dominated coral disease lesions.

Author

Bourne DG, van der Zee MJ, Botté ES, and Sato Y

Subjects

Animals, Bacteria genetics, Cluster Analysis, Genes, Bacterial, Molecular Sequence Data, Oxidation-Reduction, Phylogeny, Sequence Analysis, DNA, Anthozoa microbiology, Bacteria classification, Bacteria isolation & purification, Sulfur metabolism

Abstract

This study investigated the diversity and quantitative shifts of sulfur-oxidizing bacteria (SOB) during the onset of black band disease (BBD) in corals using quantitative PCR (qPCR) and cloning approaches targeting the soxB gene, involved in sulfur oxidation. Four Montipora sp. coral colonies identified with lesions previously termed cyanobacterial patches (CP) (comprising microbial communities different from those of BBD lesions), was monitored in situ as CP developed into BBD. The overall abundance of SOB in both CP and BBD lesions were very low and near the detection limit of the qPCR assay, although consistently indicated that SOB populations decreased as the lesions transitioned from CP to BBD. Phylogenetic assessment of retrieved soxB genes showed that SOB in both CP and BBD lesions were dominated by one sequence type, representing > 70% of all soxB gene sequences and affiliated with members of the Rhodobacteraceae within the α-Proteobacteria. This study represents the first assessment targeting SOB within BBD lesions and clearly shows that SOB are not highly diverse or abundant in this complex microbial mat. The lack of oxidation of reduced sulfur compounds by SOB likely aids the accumulation of high levels of sulfide at the base of the BBD mat, a compound contributing to the pathogenicity of BBD lesions., (© 2013 John Wiley & Sons Ltd and Society for Applied Microbiology.)

Published

2013

19. Intergenerational transfer of specific bacteria in corals and possible implications for offspring fitness.

Author

Ceh J, van Keulen M, and Bourne DG

Subjects

Animals, Anthozoa physiology, Bacteria genetics, Bacteria isolation & purification, Biodiversity, DNA, Bacterial genetics, Phylogeny, RNA, Ribosomal, 16S genetics, Sequence Analysis, DNA, Anthozoa microbiology, Bacteria classification, Germ Cells microbiology, Seawater microbiology

Abstract

Diverse and abundant bacterial populations play important functional roles in the multi-partite association of the coral holobiont. The specificity of coral-associated assemblages remains unclear, and little is known about the inheritance of specific bacteria from the parent colony to their offspring. This study investigated if broadcast spawning and brooding corals release specific and potentially beneficial bacteria with their offspring to secure maintenance across generations. Two coral species, Acropora tenuis and Pocillopora damicornis, were maintained in 0.2 μm filtered seawater during the release of their gametes and planulae, respectively. Water samples, excluding gametes and planulae, were subsequently collected, and bacterial diversity was assessed through a pyrosequencing approach amplifying a 470-bp region of the 16S rRNA gene including the variable regions 1-3. Compared to the high bacterial diversity harboured by corals, only a few taxa of bacteria were released by adult corals. Both A. tenuis and P. damicornis released similar bacteria, and the genera Alteromonas and Roseobacter were abundant in large proportions in the seawater of both species after reproduction. This study suggests that adult corals may release bacteria with their offspring to benefit the fitness in early coral life stages.

Published

2013

20. High diversity of microplankton surrounds deep-water coral reef in the Norwegian Sea.

Author

Jensen S, Bourne DG, Hovland M, and Murrell JC

Subjects

Archaea genetics, Archaea isolation & purification, Bacteria genetics, Bacteria isolation & purification, Dinoflagellida genetics, Dinoflagellida isolation & purification, Genes, rRNA, Norway, Oceans and Seas, Phylogeny, Plankton classification, Plankton genetics, Plankton isolation & purification, RNA, Ribosomal, 16S genetics, Archaea classification, Bacteria classification, Biodiversity, Coral Reefs, Dinoflagellida classification, Seawater microbiology

Abstract

Coral reefs that exist in the depths of the oceans are surrounded by Eukarya, Archaea and bacterial communities that may play an important role in the nutrition and health of the reef. The first interdomain community structure of planktonic organisms in seawater from a deep-water coral reef is described. Community profiling and analysis of ribosomal RNA gene sequences from a coral reef system at 350 m depth in the Norwegian Sea revealed a rich diversity of Eukarya and Bacteria and a moderate diversity of Archaea. Most sequences affiliated with marine microplankton from deep-sea to cold-surface regions, with many sequences being similar to those described in studies of mesopelagic and oxygen minimum zones. Dominant phylotypes belonged to the Alveolata (group I, II, dinoflagellates), Stramenopiles (silicoflagellates), Alphaproteobacteria (Pelagibacter ubique), Gammaproteobacteria (ARCTIC96BD-19), Bacteroidetes (Flavobacteria) and mesophilic Crenarchaeota (Nitrosopumilus maritimus). Several rare and novel members of the community fell into distinct phylogenetic groups. The inferred function of dominant community members suggested autotrophs that utilise light, ammonium or sulphide, and lifestyles based on host associations. The high diversity reflected a microplankton community structure, which is significantly different from that of microplankton collected at the same depth at a pelagic station away from reefs., (© 2012 Federation of European Microbiological Societies. Published by Blackwell Publishing Ltd. All rights reserved.)

Published

2012

21. Corals form characteristic associations with symbiotic nitrogen-fixing bacteria.

Author

Lema KA, Willis BL, and Bourne DG

Subjects

Animals, Anthozoa physiology, Australia, Bacteria genetics, Bacteria metabolism, Bacterial Physiological Phenomena, Cluster Analysis, DNA, Bacterial chemistry, DNA, Bacterial genetics, Molecular Sequence Data, Oxidoreductases genetics, Phylogeny, Sequence Analysis, DNA, Anthozoa microbiology, Bacteria classification, Bacteria isolation & purification, Biodiversity, Nitrogen Fixation, Symbiosis

Abstract

The complex symbiotic relationship between corals and their dinoflagellate partner Symbiodinium is believed to be sustained through close associations with mutualistic bacterial communities, though little is known about coral associations with bacterial groups able to fix nitrogen (diazotrophs). In this study, we investigated the diversity of diazotrophic bacterial communities associated with three common coral species (Acropora millepora, Acropora muricata, and Pocillopora damicormis) from three midshelf locations of the Great Barrier Reef (GBR) by profiling the conserved subunit of the nifH gene, which encodes the dinitrogenase iron protein. Comparisons of diazotrophic community diversity among coral tissue and mucus microenvironments and the surrounding seawater revealed that corals harbor diverse nifH phylotypes that differ between tissue and mucus microhabitats. Coral mucus nifH sequences displayed high heterogeneity, and many bacterial groups overlapped with those found in seawater. Moreover, coral mucus diazotrophs were specific neither to coral species nor to reef location, reflecting the ephemeral nature of coral mucus. In contrast, the dominant diazotrophic bacteria in tissue samples differed among coral species, with differences remaining consistent at all three reefs, indicating that coral-diazotroph associations are species specific. Notably, dominant diazotrophs for all coral species were closely related to the bacterial group rhizobia, which represented 71% of the total sequences retrieved from tissue samples. The species specificity of coral-diazotroph associations further supports the coral holobiont model that bacterial groups associated with corals are conserved. Our results suggest that, as in terrestrial plants, rhizobia have developed a mutualistic relationship with corals and may contribute fixed nitrogen to Symbiodinium.

Published

2012

22. Bacterial communities associated with healthy and Acropora white syndrome-affected corals from American Samoa.

Author

Wilson B, Aeby GS, Work TM, and Bourne DG

Subjects

American Samoa, Animals, Bacteria genetics, Bacteria isolation & purification, Base Sequence, Biodiversity, Coral Reefs, Molecular Sequence Data, Phylogeny, Seawater microbiology, Vibrio classification, Vibrio genetics, Vibrio physiology, Vibrionaceae classification, Vibrionaceae genetics, Vibrionaceae isolation & purification, Vibrionaceae physiology, Anthozoa microbiology, Bacteria classification

Abstract

Acropora white syndrome (AWS) is characterized by rapid tissue loss revealing the white underlying skeleton and affects corals worldwide; however, reports of causal agents are conflicting. Samples were collected from healthy and diseased corals and seawater around American Samoa and bacteria associated with AWS characterized using both culture-dependent and culture-independent methods, from coral mucus and tissue slurries, respectively. Bacterial 16S rRNA gene clone libraries derived from coral tissue were dominated by the Gammaproteobacteria, and Jaccard's distances calculated between the clone libraries showed that those from diseased corals were more similar to each other than to those from healthy corals. 16S rRNA genes from 78 culturable coral mucus isolates also revealed a distinct partitioning of bacterial genera into healthy and diseased corals. Isolates identified as Vibrionaceae were further characterized by multilocus sequence typing, revealing that whilst several Vibrio spp. were found to be associated with AWS lesions, a recently described species, Vibrio owensii, was prevalent amongst cultured Vibrio isolates. Unaffected tissues from corals with AWS had a different microbiota than normal Acropora as found by others. Determining whether a microbial shift occurs prior to disease outbreaks will be a useful avenue of pursuit and could be helpful in detecting prodromal signs of coral disease prior to manifestation of lesions., (© 2012 Federation of European Microbiological Societies. Published by Blackwell Publishing Ltd. All rights reserved.)

Published

2012

23. Coral-bacterial communities before and after a coral mass spawning event on Ningaloo Reef.

Author

Ceh J, Raina JB, Soo RM, van Keulen M, and Bourne DG

Subjects

Animals, Biodiversity, Coral Reefs, RNA, Ribosomal, 16S genetics, Western Australia, Anthozoa microbiology, Bacteria genetics, DNA, Bacterial genetics

Abstract

Bacteria associated with three coral species, Acropora tenuis, Pocillopora damicornis and Tubastrea faulkneri, were assessed before and after coral mass spawning on Ningaloo Reef in Western Australia. Two colonies of each species were sampled before and after the mass spawning event and two additional samples were collected for P. damicornis after planulation. A variable 470 bp region of the 16 S rRNA gene was selected for pyrosequencing to provide an understanding of potential variations in coral-associated bacterial diversity and community structure. Bacterial diversity increased for all coral species after spawning as assessed by Chao1 diversity indicators. Minimal changes in community structure were observed at the class level and data at the taxonomical level of genus incorporated into a PCA analysis indicated that despite bacterial diversity increasing after spawning, coral-associated community structure did not shift greatly with samples grouped according to species. However, interesting changes could be detected from the dataset; for example, α-Proteobacteria increased in relative abundance after coral spawning and particularly the Roseobacter clade was found to be prominent in all coral species, indicating that this group may be important in coral reproduction.

Published

2012

24. Coral-associated bacterial communities on Ningaloo Reef, Western Australia.

Author

Ceh J, Van Keulen M, and Bourne DG

Subjects

Animals, Bacteria classification, Bacteria growth & development, Biodiversity, DNA, Bacterial genetics, Gene Library, Genes, rRNA, Geography, Phylogeny, Principal Component Analysis, RNA, Ribosomal, 16S genetics, Seasons, Seawater microbiology, Sequence Analysis, DNA, Western Australia, Anthozoa microbiology, Bacteria genetics

Abstract

Coral-associated microbial communities from three coral species (Pocillopora damicornis, Acropora tenuis and Favites abdita) were examined every 3 months (January, March, June, October) over a period of 1 year on Ningaloo Reef, Western Australia. Tissue from corals was collected throughout the year and additional sampling of coral mucus and seawater samples was performed in January. Tissue samples were also obtained in October from P. damicornis coral colonies on Rottnest Island off Perth, 1200 km south of Ningaloo Reef, to provide comparisons between coral-microbial associates in different locations. The community structures of the coral-associated microorganisms were analysed using phylogenetic analysis of 16S rRNA gene clone libraries, which demonstrated highly diverse microbial profiles among all the coral species sampled. Principal component analysis revealed that samples grouped according to time and not species, indicating that coral-microbial associations may be a result of environmental drivers such as oceanographic characteristics, benthic community structure and temperature. Tissue samples from P. damicornis at Rottnest Island revealed similarities in bacteria to the samples at Ningaloo Reef. This study highlights that coral-associated microbial communities are highly diverse; however, the complex interactions that determine the stability of these associations are not necessarily dependent on coral host specificity., (© 2010 Federation of European Microbiological Societies. Published by Blackwell Publishing Ltd. All rights reserved.)

Published

2011

25. Do the organic sulfur compounds DMSP and DMS drive coral microbial associations?

Author

Raina JB, Dinsdale EA, Willis BL, and Bourne DG

Subjects

Animals, Biodiversity, Metagenome, Viruses genetics, Anthozoa metabolism, Anthozoa microbiology, Bacteria growth & development, Bacteria metabolism, Ecosystem, Sulfides metabolism, Sulfonium Compounds metabolism

Abstract

Dimethylsulfoniopropionate (DMSP) and dimethylsulfide (DMS) are key compounds in the global sulfur cycle. Moreover, DMS is particularly important in climate regulation owing to its role in cloud formation. Reef building corals are major contributors to the production of these two compounds and also form diverse and complex associations with bacteria, which are known to play a crucial role in the degradation of DMSP and DMS. Here, we highlight an extensive overlap between bacterial species implicated in DMSP/DMS degradation and those associated with corals, leading to the hypothesis that these two compounds play a major role in structuring coral-associated bacterial communities, with important consequences for coral health and the resilience of coral reefs. We also explore the publically available metagenome databases and show that genes implicated in DMSP metabolism are abundant in the viral component of coral-reef-derived metagenomes, indicating that viruses can act as a reservoir for such genes.

Published

2010

26. Successional changes in bacterial communities during the development of black band disease on the reef coral, Montipora hispida.

Author

Sato Y, Willis BL, and Bourne DG

Subjects

Animals, Australia, Bacteria genetics, Bacteria isolation & purification, Cyanobacteria classification, Cyanobacteria genetics, Cyanobacteria isolation & purification, DNA, Bacterial genetics, DNA, Ribosomal genetics, Ecosystem, Phylogeny, RNA, Ribosomal, 16S genetics, Seawater microbiology, Anthozoa microbiology, Bacteria classification

Abstract

Black band disease (BBD) consists of a mat-forming microbial consortium that migrates across coral colonies causing rapid tissue loss. Although BBD-associated microbial communities have been well characterized, little is known regarding how these complex bacterial consortia develop. This study analyzed successional changes in microbial communities leading to the development of BBD. Long-term monitoring of tagged corals throughout outbreaks of BBD in the central Great Barrier Reef documented cyanobacterium-infected lesions, herein termed cyanobacterial patch(es) (CP), which were macroscopically distinct from BBD and preceded the onset of BBD in 19% of the cases. Dominant cyanobacteria within CP lesions were morphologically distinct from ones dominating BBD lesions. Clone libraries and terminal restriction fragment length polymorphism analysis confirmed shifts within cyanobacterial assemblages, from Blennothrix sp.-affiliated sequences dominating CP lesions, to Oscillatoria sp.-affiliated sequences, similar to those retrieved from other BBD samples worldwide, dominating BBD lesions. Bacterial 16S ribosomal RNA clone libraries also showed shifts in bacterial ribotypes during transitions from CP to BBD, with Alphaproteobacteria-affiliated sequences dominant in CP libraries, whereas gammaproteobacterial and cyanobacterial ribotypes were more abundant in BBD clone libraries. Sequences affiliated with organisms identified in sulfur cycling were commonly retrieved from lesions showing characteristic field signs of BBD. As high sulfide concentrations have been implicated in BBD-mediated coral tissue degradation, proliferation of a microbial community actively involved in sulfur cycling potentially contributes to the higher progression rates found for BBD compared with CP lesions. Results show how microbial colonization of indistinct lesions may facilitate a common coral disease with proven ecological effects on coral populations.

Published

2010

27. Coral-associated bacteria and their role in the biogeochemical cycling of sulfur.

Author

Raina JB, Tapiolas D, Willis BL, and Bourne DG

Subjects

Animals, Bacteria genetics, Bacteria metabolism, Bacterial Proteins genetics, Cluster Analysis, DNA, Bacterial chemistry, DNA, Bacterial genetics, DNA, Ribosomal chemistry, DNA, Ribosomal genetics, Molecular Sequence Data, Phylogeny, RNA, Ribosomal, 16S genetics, Sequence Analysis, DNA, Sequence Homology, Nucleic Acid, Sulfides metabolism, Sulfonium Compounds metabolism, Anthozoa microbiology, Bacteria classification, Bacteria isolation & purification, Biodiversity, Sulfur metabolism

Abstract

Marine bacteria play a central role in the degradation of dimethylsulfoniopropionate (DMSP) to dimethyl sulfide (DMS) and acrylic acid, DMS being critical to cloud formation and thereby cooling effects on the climate. High concentrations of DMSP and DMS have been reported in scleractinian coral tissues although, to date, there have been no investigations into the influence of these organic sulfur compounds on coral-associated bacteria. Two coral species, Montipora aequituberculata and Acropora millepora, were sampled and their bacterial communities were characterized by both culture-dependent and molecular techniques. Four genera, Roseobacter, Spongiobacter, Vibrio, and Alteromonas, which were isolated on media with either DMSP or DMS as the sole carbon source, comprised the majority of clones retrieved from coral mucus and tissue 16S rRNA gene clone libraries. Clones affiliated with Roseobacter sp. constituted 28% of the M. aequituberculata tissue libraries, while 59% of the clones from the A. millepora libraries were affiliated with sequences related to the Spongiobacter genus. Vibrio spp. were commonly isolated from DMS and acrylic acid enrichments and were also present in 16S rRNA gene libraries from coral mucus, suggesting that under "normal" environmental conditions, they are a natural component of coral-associated communities. Genes homologous to dddD, and dddL, previously implicated in DMSP degradation, were also characterized from isolated strains, confirming that bacteria associated with corals have the potential to metabolize this sulfur compound when present in coral tissues. Our results demonstrate that DMSP, DMS, and acrylic acid potentially act as nutrient sources for coral-associated bacteria and that these sulfur compounds are likely to play a role in structuring bacterial communities in corals, with important consequences for the health of both corals and coral reef ecosystems.

Published

2009

28. Diversities of coral-associated bacteria differ with location, but not species, for three acroporid corals on the Great Barrier Reef.

Author

Littman RA, Willis BL, Pfeffer C, and Bourne DG

Subjects

Animals, Australia, Bacteria classification, Biodiversity, Ecosystem, Phylogeny, Polymorphism, Restriction Fragment Length, RNA, Bacterial genetics, RNA, Ribosomal, 16S genetics, Ribotyping, Sequence Analysis, DNA, Species Specificity, Anthozoa microbiology, Bacteria genetics, Symbiosis

Abstract

Patterns in the diversity of bacterial communities associated with three species of Acropora (Acropora millepora, Acropora tenuis and Acropora valida) were compared at two locations (Magnetic Island and Orpheus Island) on the Great Barrier Reef to better understand the nature and specificity of coral-microbial symbioses. Three culture-independent techniques demonstrated consistent bacterial communities among replicate samples of each coral species, confirming that corals associate with specific microbiota. Profiles were also conserved among all three species of Acropora within each location, suggesting that closely related corals of the same genus harbor similar bacterial types. Bacterial community profiles of A. millepora at Orpheus Island were consistent in samples collected throughout the year, indicating a stable community despite temporal changes. However, DGGE and T-RFLP profiles differed on corals from different reefs. Nonmetric multidimensional scaling of T-RFLP profiles showed that samples grouped according to location rather than coral species. Although similar sequences were retrieved from clone libraries of corals at both Magnetic and Orpheus Island, differences in the relative dominant bacterial ribotypes within the libraries drive bacterial community structure at different geographical locations. These results indicate certain bacterial groups associated specifically with corals, but the dominant bacterial genera differ between geographically-spaced corals.

Published

2009

29. Microbial diversity within early-stage cultured Panulirus ornatus phyllosomas.

Author

Payne MS, Hall MR, Sly L, and Bourne DG

Subjects

Animals, Bacteria genetics, Bacteria ultrastructure, Base Sequence, Biodiversity, DNA Fingerprinting, DNA, Bacterial chemistry, DNA, Bacterial genetics, Gene Library, In Situ Hybridization, Fluorescence, Larva microbiology, Microscopy, Electron, Scanning, Molecular Sequence Data, Sequence Analysis, DNA, Bacteria classification, Bacteria isolation & purification, Palinuridae microbiology

Abstract

A thorough understanding of the microorganisms and pathogens associated with the larval stage of the tropical ornate rock lobster, Panulirus ornatus, is required to overcome disease outbreaks that currently block aquaculture attempts. This study used microscopy in addition to culture and molecularly based microbiological techniques to characterize the bacterial community associated with cultured, developmental stage PI to PII P. ornatus phyllosomas. Scanning electron microscopy demonstrated colonization of phyllosomas by filamentous, rod-shaped, and coccus-shaped bacteria. A clone library constructed from dead phyllosomas sampled from the larval rearing tank on day 10 was dominated by Thiothrix-affiliated sequences (56% of clones). A comparable library from live phyllosomas also contained Thiothrix-affiliated sequences, though these only represented 19% of clones within the library. Fluorescent in situ hybridization (FISH) confirmed identification of the filamentous bacteria as Thiothrix sp., being present on dead phyllosomas. FISH also identified Leucothrix sp. and Vibrio sp., as well as a range of other rod- and coccus-shaped bacteria, colonizing both live and dead phyllosomas. The development of the microbial community associated with phyllosomas was monitored through a standard larval rearing run using denaturing gradient gel electrophoresis (DGGE). Vibrio sp.-affiliated bands dominated the profiles of live animals through the rearing period and dead phyllosomas sampled on selected days. The population of Vibrio sp. associated with phyllosomas was monitored with culture-based analysis on selective media and demonstrated to increase significantly on day 7, coinciding with the beginning of the larval molt. An isolated Vibrio harveyi strain demonstrated an identical 16S rRNA sequence with retrieved DGGE and clone library sequences. Colonization of phyllosomas with filamentous bacterial species potentially hinders the ability of the animals to molt and, combined with the added stress of the molt process, likely results in reduced immune function, allowing opportunistic pathogenic Vibrio sp. to cause larval mortalities.

Published

2007

30. Reduced diversity and stability of coral-associated bacterial communities and suppressed immune function precedes disease onset in corals.

Author

Pollock, F Joseph, Lamb, Joleah B, van de Water, Jeroen AJM, Smith, Hillary A, Schaffelke, Britta, Willis, Bette L, and Bourne, David G

Subjects

bacteria, coral microbes, disease, immunity, marine infrastructure, white syndrome

Abstract

Disease is an emerging threat to coral reef ecosystems worldwide, highlighting the need to understand how environmental conditions interact with coral immune function and associated microbial communities to affect holobiont health. Increased coral disease incidence on reefs adjacent to permanently moored platforms on Australia's Great Barrier Reef provided a unique case study to investigate environment-host-microbe interactions in situ. Here, we evaluate coral-associated bacterial community (16S rRNA amplicon sequencing), immune function (protein-based prophenoloxidase-activating system), and water quality parameters before, during and after a disease event. Over the course of the study, 31% of tagged colonies adjacent to platforms developed signs of white syndrome (WS), while all control colonies on a platform-free reef remained visually healthy. Corals adjacent to platforms experienced significant reductions in coral immune function. Additionally, the corals at platform sites that remained visually healthy throughout the study had reduced bacterial diversity compared to healthy colonies at the platform-free site. Interestingly, prior to the observation of macroscopic disease, corals that would develop WS had reduced bacterial diversity and significantly greater community heterogeneity between colonies compared to healthy corals at the same location. These results suggest that activities associated with offshore marine infrastructure impacts coral immunocompetence and associated bacterial community, which affects the susceptibility of corals to disease.

Published

2019

31. Visualization of coral host–pathogen interactions using a stable GFP-labeled Vibrio coralliilyticus strain

Author

Pollock, F. Joseph, Krediet, Cory J., Garren, Melissa, Stocker, Roman, Winn, Karina, Wilson, Bryan, Huete-Stauffer, Carla, Willis, Bette L., and Bourne, David G.

Published

2015

32. Bacterial communities of juvenile corals infected with different Symbiodinium (dinoflagellate) clades

Author

Littman, Raechel A., Willis, Bette L., and Bourne, David G.

Published

2009

33. Spatial dynamics of virus-like particles and heterotrophic bacteria within a shallow coral reef system

Author

Seymour, Justin R., Patten, Nicole, Bourne, David G., and Mitchell, James G.

Published

2005

34. Testing cophylogeny between coral reef invertebrates and their bacterial and archaeal symbionts.

Author

O'Brien, Paul A., Andreakis, Nikos, Tan, Shangjin, Miller, David J., Webster, Nicole S., Zhang, Guojie, and Bourne, David G.

Subjects

CORALS, MARINE invertebrates, INVERTEBRATES, COMMENSALISM, CORAL reefs & islands, OCTOCORALLIA, MICROBIAL communities, MICROBIAL genes

Abstract

Marine invertebrates harbour a complex suite of bacterial and archaeal symbionts, a subset of which are probably linked to host health and homeostasis. Within a complex microbiome it can be difficult to tease apart beneficial or parasitic symbionts from nonessential commensal or transient microorganisms; however, one approach is to detect strong cophylogenetic patterns between microbial lineages and their respective hosts. We employed the Procrustean approach to cophylogeny (PACo) on 16S rRNA gene derived microbial community profiles paired with COI, 18S rRNA and ITS1 host phylogenies. Second, we undertook a network analysis to identify groups of microbes that were co‐occurring within our host species. Across 12 coral, 10 octocoral and five sponge species, each host group and their core microbiota (50% prevalence within host species replicates) had a significant fit to the cophylogenetic model. Independent assessment of each microbial genus and family found that bacteria and archaea affiliated to Endozoicomonadaceae, Spirochaetaceae and Nitrosopumilaceae have the strongest cophylogenetic signals. Further, local Moran's I measure of spatial autocorrelation identified 14 ASVs, including Endozoicomonadaceae and Spirochaetaceae, whose distributions were significantly clustered by host phylogeny. Four co‐occurring subnetworks were identified, each of which was dominant in a different host group. Endozoicomonadaceae and Spirochaetaceae ASVs were abundant among the subnetworks, particularly one subnetwork that was exclusively comprised of these two bacterial families and dominated the octocoral microbiota. Our results disentangle key microbial interactions that occur within complex microbiomes and reveal long‐standing, essential microbial symbioses in coral reef invertebrates. [ABSTRACT FROM AUTHOR]

Published

2021

35. Antimicrobial and stress responses to increased temperature and bacterial pathogen challenge in the holobiont of a reef‐building coral.

Author

van de Water, Jeroen A. J. M., Chaib De Mares, Maryam, Dixon, Groves B., Raina, Jean‐Baptiste, Willis, Bette L., Bourne, David G., and van Oppen, Madeleine J. H.

Subjects

SYMBIODINIUM, CLIMATE change, IMMUNE response, SYMBIOSIS, CORALS

Abstract

Abstract: Global increases in coral disease prevalence have been linked to ocean warming through changes in coral‐associated bacterial communities, pathogen virulence and immune system function. However, the interactive effects of temperature and pathogens on the coral holobiont are poorly understood. Here, we assessed three compartments of the holobiont (host, Symbiodinium and bacterial community) of the coral Montipora aequituberculata challenged with the pathogen Vibrio coralliilyticus and the commensal bacterium Oceanospirillales sp. under ambient (27°C) and elevated (29.5 and 32°C) seawater temperatures. Few visual signs of bleaching and disease development were apparent in any of the treatments, but responses were detected in the holobiont compartments. V. coralliilyticus acted synergistically and negatively impacted the photochemical efficiency of Symbiodinium at 32°C, while Oceanospirillales had no significant effect on photosynthetic efficiency. The coral, however, exhibited a minor response to the bacterial challenges, with the response towards V. coralliilyticus being significantly more pronounced, and involving the prophenoloxidase‐activating system and multiple immune system‐related genes. Elevated seawater temperatures did not induce shifts in the coral‐associated bacterial community, but caused significant gene expression modulation in both Symbiodinium and the coral host. While Symbiodinium exhibited an antiviral response and upregulated stress response genes, M. aequituberculata showed regulation of genes involved in stress and innate immune response processes, including immune and cytokine receptor signalling, the complement system, immune cell activation and phagocytosis, as well as molecular chaperones. These observations show that M. aequituberculata is capable of maintaining a stable bacterial community under elevated seawater temperatures and thereby contributes to preventing disease development. [ABSTRACT FROM AUTHOR]

Published

2018

36. The coral immune response facilitates protection against microbes during tissue regeneration.

Author

Water, Jeroen A. J. M., Ainsworth, Tracy D., Leggat, William, Bourne, David G., Willis, Bette L., and Oppen, Madeleine J. H.

Subjects

CORAL physiology, IMMUNE response, REGENERATION (Biology), BACTERIAL colonies, CELLULAR signal transduction

Abstract

Increasing physical damage on coral reefs from predation, storms and anthropogenic disturbances highlights the need to understand the impact of injury on the coral immune system. In this study, we examined the regulation of the coral immune response over 10 days following physical trauma artificially inflicted on in situ colonies of the coral Acropora aspera, simultaneously with bacterial colonization of the lesions. Corals responded to injury by increasing the expression of immune system-related genes involved in the Toll-like and NOD-like receptor signalling pathways and the lectin-complement system in three phases (<2, 4 and 10 days post-injury). Phenoloxidase activity was also significantly upregulated in two phases (<3 and 10 days post-injury), as were levels of non-fluorescent chromoprotein. In addition, green fluorescent protein expression was upregulated in response to injury from 4 days post-injury, while cyan fluorescent protein expression was reduced. No shifts in the composition of coral-associated bacterial communities were evident following injury based on 16S rRNA gene amplicon pyrosequencing. Bacteria-specific fluorescence in situ hybridization also showed no evidence of bacterial colonization of the wound or regenerating tissues. Coral tissues showed near-complete regeneration of lesions within 10 days. This study demonstrates that corals exhibit immune responses that support rapid recovery following physical injury, maintain coral microbial homeostasis and prevent bacterial infestation that may compromise coral fitness. [ABSTRACT FROM AUTHOR]

Published

2015

37. Responses of coral-associated bacterial communities to heat stress differ with Symbiodinium type on the same coral host.

Author

Littman, Raechel A., Bourne, David G., and Willis, Bette L.

Subjects

*PHYSIOLOGICAL effects of heat, *BACTERIA, *CORAL diseases, *ACROPORA, *SYMBIOSIS, *TEMPERATURE control, *VIBRIO, *DINOFLAGELLATES, *ENDOSYMBIOSIS, *MARINE microbial ecology

Abstract

This study compared the effect of heat stress on coral-associated bacterial communities among juveniles of the coral, Acropora tenuis, hosting different Symbiodinium types. In comparison to a control temperature treatment (28 °C), we documented dramatic changes in bacterial associates on juvenile corals harbouring ITS 1 type D Symbiodinium when placed in a high (32 °C) temperature treatment. In particular, there was a marked increase in the number of retrieved Vibrio affiliated sequences, which coincided with a 44% decline in the photochemical efficiency of the D-juveniles. Interestingly, these Vibrio sequences affiliated most closely with the coral pathogen, Vibrio coralliilyticus, which has been implicated in some coral disease outbreaks. In contrast, A. tenuis hosting ITS 1 type C1 Symbiodinium did not exhibit major bacterial shifts in the elevated temperature treatment, indicating a more stable bacterial community during thermal stress; concomitantly a decline (10%) in photochemical efficiency was minimal for this group. D juveniles that had been exposed to moderately elevated sea temperatures (30 °C) in the field before being placed in the control temperature treatment displayed a decrease in the number of Vibrio affiliated sequences and bacterial profiles shifted to become more similar to profiles of corals harbouring type C1 Symbiodinium. In combination, these results demonstrate that thermal stress can result in shifts in coral-associated bacterial communities, which may lead to deteriorating coral health. The lower resilience of A. tenuis to thermal stress when harbouring Symbiodinium D highlights the importance of inter-kingdom interactions among the coral host, dinoflagellate endosymbiont and bacterial associates for coral health and resilience. [ABSTRACT FROM AUTHOR]

Published

2010

38. Successional changes in bacterial communities during the development of black band disease on the reef coral, Montipora hispida.

Author

Yui Sato, Willis, Bette L., and Bourne, David G.

Subjects

CORAL reef ecology, BACTERIA, CYANOBACTERIA, POLYMORPHISM (Zoology), OSCILLATORIA

Abstract

Black band disease (BBD) consists of a mat-forming microbial consortium that migrates across coral colonies causing rapid tissue loss. Although BBD-associated microbial communities have been well characterized, little is known regarding how these complex bacterial consortia develop. This study analyzed successional changes in microbial communities leading to the development of BBD. Long-term monitoring of tagged corals throughout outbreaks of BBD in the central Great Barrier Reef documented cyanobacterium-infected lesions, herein termed cyanobacterial patch(es) (CP), which were macroscopically distinct from BBD and preceded the onset of BBD in 19% of the cases. Dominant cyanobacteria within CP lesions were morphologically distinct from ones dominating BBD lesions. Clone libraries and terminal restriction fragment length polymorphism analysis confirmed shifts within cyanobacterial assemblages, from Blennothrix sp.-affiliated sequences dominating CP lesions, to Oscillatoria sp.-affiliated sequences, similar to those retrieved from other BBD samples worldwide, dominating BBD lesions. Bacterial 16S ribosomal RNA clone libraries also showed shifts in bacterial ribotypes during transitions from CP to BBD, with Alphaproteobacteria-affiliated sequences dominant in CP libraries, whereas gammaproteobacterial and cyanobacterial ribotypes were more abundant in BBD clone libraries. Sequences affiliated with organisms identified in sulfur cycling were commonly retrieved from lesions showing characteristic field signs of BBD. As high sulfide concentrations have been implicated in BBD-mediated coral tissue degradation, proliferation of a microbial community actively involved in sulfur cycling potentially contributes to the higher progression rates found for BBD compared with CP lesions. Results show how microbial colonization of indistinct lesions may facilitate a common coral disease with proven ecological effects on coral populations. [ABSTRACT FROM AUTHOR]

Published

2010

39. Changes in coral-associated microbial communities during a bleaching event.

Author

Bourne, David, Iida, Yuki, Uthicke, Sven, and Smith-Keune, Carolyn

Subjects

*CORAL bleaching, *WATER temperature, *ELECTROPHORESIS, *VIBRIONACEAE, *CORALS, *OLIGONUCLEOTIDES

Abstract

Environmental stressors such as increased sea surface temperatures are well-known for contributing to coral bleaching; however, the effect of increased temperatures and subsequent bleaching on coral-associated microbial communities is poorly understood. Colonies of the hard coral Acropora millepora were tagged on a reef flat off Magnetic Island (Great Barrier Reef) and surveyed over 2.5 years, which included a severe bleaching event in January/February 2002. Daily average water temperatures exceeded the previous 10-year average by more than 1 °C for extended periods with field-based visual surveys recording all tagged colonies displaying signs of bleaching. During the bleaching period, direct counts of coral zooxanthellae densities decreased by ∼64%, before recovery to pre-bleaching levels after the thermal stress event. A subset of three tagged coral colonies were sampled through the bleaching event and changes in the microbial community elucidated. Denaturing gradient gel electrophoresis (DGGE) analysis demonstrated conserved bacterial banding profiles between the three coral colonies, confirming previous studies highlighting specific microbial associations. As coral colonies bleached, the microbial community shifted and redundancy analysis (RDA) of DGGE banding patterns revealed a correlation of increasing temperature with the appearance of Vibrio-affiliated sequences. Interestingly, this shift to a Vibrio-dominated community commenced prior to visual signs of bleaching. Clone libraries hybridized with Vibrio-specific oligonucleotide probes confirmed an increase in the fraction of Vibrio-affiliated clones during the bleaching period. Post bleaching, the coral microbial associations again shifted, returning to a profile similar to the fingerprints prior to bleaching. This provided further evidence for corals selecting and shaping their microbial partners. For non-bleached samples, a close association with Spongiobacter-related sequences were revealed by both clone libraries and DGGE profiling. Despite Vibrio species being previously implicated in bleaching of specific coral species, it is unsure if the relative increase in retrieved Vibrio sequences is due to bacterial infection or an opportunistic response to compromised health and changing environmental parameters of the coral host. This study provides the first molecular-based study demonstrating changes in coral-associated bacterial assemblages during a bleaching event on a natural reef system.The ISME Journal (2008) 2, 350–363; doi:10.1038/ismej.2007.112; published online 6 December 2007 [ABSTRACT FROM AUTHOR]

Published

2008

40. Bacterial community structure associated with the Antarctic soft coral, Alcyonium antarcticum.

Author

Webster, Nicole S. and Bourne, David

Subjects

*ALCYONIUM, *ALCYONACEA, *MARINE bacteria, *BACTERIAL diversity, *BACTERIA

Abstract

The structure and composition of microbial communities inhabiting the soft coral Alcyonium antarcticum were investigated across three differentially contaminated sites within McMurdo Sound, Antarctica. Diverse microbial communities were revealed at all sites using culture-based analysis, denaturing gradient gel electrophoresis (DGGE), 16S rRNA gene clone-library analysis, and FISH. Phylogenetic analysis of isolates and retrieved sequences demonstrated close affiliation with known psychrophiles from the Antarctic environment and high similarity to Gammaproteobacteria clades of sponge-associated microorganisms. The majority of bacteria detected with all techniques reside within the Gammaproteobacteria, although other phylogenetic groups including Alpha- and Betaproteobacteria, Bacteroidetes, Firmicutes, Actinomycetales, Planctomycetes, and Chlorobi and bacteria from the functional group of sulfate-reducing bacteria were also present. Multivariate (nMDS) analysis of DGGE banding patterns and principal component analysis of quantitative FISH data revealed no distinct differences in community composition between differentially contaminated sites. Rather, conserved coral-associated bacterial groups were observed within and between sites, providing evidence to support specific coral–microbial interactions. This is the first investigation of microbial communities associated with Antarctic soft corals, and the results suggest that spatially stable microbial associations exist across an environmental impact gradient. [ABSTRACT FROM AUTHOR]

Published

2007

41. Microbial community dynamics in a larval aquaculture system of the tropical rock lobster, Panulirus ornatus

Author

Bourne, David G., Young, Neil, Webster, Nicole, Payne, Matthew, Salmon, Matthew, Demel, Sabine, and Hall, Mike

Subjects

*AQUACULTURE, *SPINY lobsters, *HISTOPATHOLOGY, *BACTERIA

Abstract

Abstract: Commercial scale rearing of the tropical rock lobster (Panulirus ornatus) has been unsuccessful to date, with attempts characterised by periodic mass mortalities of early stage hatchery-reared larvae. Here, we investigate the microbiological and histopathological factors affecting early stage phyllosomas. Histopathology identified microbial infestation of phyllosomas, including proliferation of bacteria in the hepatopancreas and heavy external fouling of appendages and cuticle with filamentous bacteria and sessile protozoa. Scanning electron microscopy confirmed fouling by filamentous bacteria of at least two morphological types and also fouling by rod-shaped bacteria, indicative of a diverse epibiont community. Culture- and molecular-based microbial community analysis was performed on the water column, tank biofilm and whole phyllosomas of standard larval-rearing environments. No correlation between bacterial numbers (measured as colony-forming units [CFU] mL−1) and phyllosoma mortalities was established. Culture-based studies using selective media indicated that Vibrionaceae-related organisms were a dominant part of the microbial community and Vibrio parahaemolyticus was the most commonly isolated organism from each environment investigated. Limited microbial phylogenetic diversity was observed for culture-based studies when compared against molecular-based denaturing gradient gel electrophoresis (DGGE) results. DGGE profiles of water, biofilm and phyllosoma environments differed, indicative of unique microbial niches sustaining different microbial populations. These microbial populations appeared dynamic since DGGE profiles changed within each environment over the course of the experiment. Few Vibrio-affiliated sequences were retrieved from DGGE profiles highlighting differences between the two methods for assessing microbial diversity within the larval-rearing system. [Copyright &y& Elsevier]

Published

2004

42. Degradation of the cyanobacterial hepatotoxin microcystin by aquaticbacteria

Author

Bourne, David G., Blakeley, Robert L., Doelle, Horst, and Jones, Gary J.

Subjects

BACTERIA, BIODEGRADATION

Published

1994

43. Detection and Quantification of the Coral Pathogen Vibrio coralliilyticus by Real-Time PCR with TaqMan Fluorescent Probes.

Author

Pollock, Joseph F., Morris, Pamela J., Willis, Bette L., and Bourne, David G.

Subjects

*VIBRIO, *CORAL diseases, *HEAT shock proteins, *MICROBIOLOGICAL assay, *POLYMERASE chain reaction, *PATHOGENIC microorganisms, *DNA, *BACTERIA, *SEAWATER

Abstract

A real-time quantitative PCR-based detection assay targeting the dnaJ gene (encoding heat shock protein 40) of the coral pathogen Vibrio coralliilyticus was developed. The assay is sensitive, detecting as little as 1 CFU per ml in seawater and 104 CFU per cm2 of coral tissue. Moreover, inhibition by DNA and cells derived from bacteria other than V. coralliilyticus was minimal. This assay represents a novel approach to coral disease diagnosis that will advance the field of coral disease research. [ABSTRACT FROM AUTHOR]

Published

2010