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2. Biodiversity, environmental drivers, and sustainability of the global deep-sea sponge microbiome

Author

Busch, Kathrin, Slaby, Beate M., Bach, Wolfgang, Boetius, Antje, Clefsen, Ina, Colaço, Ana, Creemers, Marie, Cristobo, Javier, Federwisch, Luisa, Franke, Andre, Gavriilidou, Asimenia, Hethke, Andrea, Kenchington, Ellen, Mienis, Furu, Mills, Sadie, Riesgo, Ana, Ríos, Pilar, Roberts, Emyr Martyn, Sipkema, Detmer, Pita, Lucía, Schupp, Peter J., Xavier, Joana, Rapp, Hans Tore, and Hentschel, Ute

Published
2022
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3. Publisher Correction: Biodiversity, environmental drivers, and sustainability of the global deep-sea sponge microbiome

Author

Busch, Kathrin, Slaby, Beate M., Bach, Wolfgang, Boetius, Antje, Clefsen, Ina, Colaço, Ana, Creemers, Marie, Cristobo, Javier, Federwisch, Luisa, Franke, Andre, Gavriilidou, Asimenia, Hethke, Andrea, Kenchington, Ellen, Mienis, Furu, Mills, Sadie, Riesgo, Ana, Ríos, Pilar, Roberts, Emyr Martyn, Sipkema, Detmer, Pita, Lucía, Schupp, Peter J., Xavier, Joana, Rapp, Hans Tore, and Hentschel, Ute

Published
2022
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6. Lifestyle Evolution in Cyanobacterial Symbionts of Sponges

Author

Burgsdorf, Ilia, Slaby, Beate M, Handley, Kim M, Haber, Markus, Blom, Jochen, Marshall, Christopher W, Gilbert, Jack A, Hentschel, Ute, and Steindler, Laura

Subjects
Microbiology, Biological Sciences, Ecology, Genetics, Human Genome, Animals, Bacteriophages, Evolution, Molecular, Genome, Bacterial, Methionine, O Antigens, Photosystem II Protein Complex, Phylogeny, Porifera, RNA, Ribosomal, 16S, Sequence Alignment, Sequence Analysis, DNA, Symbiosis, Synechococcus, Biochemistry and cell biology, Medical microbiology
Abstract

UNLABELLED:The "Candidatus Synechococcus spongiarum" group includes different clades of cyanobacteria with high 16S rRNA sequence identity (~99%) and is the most abundant and widespread cyanobacterial symbiont of marine sponges. The first draft genome of a "Ca. Synechococcus spongiarum" group member was recently published, providing evidence of genome reduction by loss of genes involved in several nonessential functions. However, "Ca. Synechococcus spongiarum" includes a variety of clades that may differ widely in genomic repertoire and consequently in physiology and symbiotic function. Here, we present three additional draft genomes of "Ca. Synechococcus spongiarum," each from a different clade. By comparing all four symbiont genomes to those of free-living cyanobacteria, we revealed general adaptations to life inside sponges and specific adaptations of each phylotype. Symbiont genomes shared about half of their total number of coding genes. Common traits of "Ca. Synechococcus spongiarum" members were a high abundance of DNA modification and recombination genes and a reduction in genes involved in inorganic ion transport and metabolism, cell wall biogenesis, and signal transduction mechanisms. Moreover, these symbionts were characterized by a reduced number of antioxidant enzymes and low-weight peptides of photosystem II compared to their free-living relatives. Variability within the "Ca. Synechococcus spongiarum" group was mostly related to immune system features, potential for siderophore-mediated iron transport, and dependency on methionine from external sources. The common absence of genes involved in synthesis of residues, typical of the O antigen of free-living Synechococcus species, suggests a novel mechanism utilized by these symbionts to avoid sponge predation and phage attack. IMPORTANCE:While the Synechococcus/Prochlorococcus-type cyanobacteria are widely distributed in the world's oceans, a subgroup has established its niche within marine sponge tissues. Recently, the first genome of sponge-associated cyanobacteria, "Candidatus Synechococcus spongiarum," was described. The sequencing of three representatives of different clades within this cyanobacterial group has enabled us to investigate intraspecies diversity, as well as to give a more comprehensive understanding of the common symbiotic features that adapt "Ca. Synechococcus spongiarum" to its life within the sponge host.

Published
2015

7. Genomics of "Candidatus Synechococcus spongiarium", a Cyanobacterial Sponge Symbiont

Author

Slaby, Beate M., Copeland, Alex, Woyke, Tanja, and Hentschel, Ute

Subjects
free-living ecotypes, CA.S.spongiarum, phylogenetic data Synechococcus spp.
Abstract

Marine sponges (Porifera): ancient metazoans of ecological importance, that produce bioactive secondary metabolites and interact with various microorganisms including cyanobacteria1:Marine Synechococcus spp.: cyanobacteria,important contributors to the global carbon cycle andmajor primary producers in the oceans2Ca. S. spongiarum: an ecotype of this genus,widespread and abundant symbiont of various marinesponges around the world3, e.g. Aplysina aerophoba

Published
2014

10. Giant sponge grounds of Central Arctic seamounts are associated with extinct seep life

Author

Morganti, Teresa M., Slaby, Beate M., de Kluijver, Anna, Busch, K, Hentschel, U., Middelburg, J. J., Mollenhauer, Gesine, Dannheim, Jennifer, Rapp, H. T., Purser, Autun, Boetius, Antje, Morganti, Teresa M., Slaby, Beate M., de Kluijver, Anna, Busch, K, Hentschel, U., Middelburg, J. J., Mollenhauer, Gesine, Dannheim, Jennifer, Rapp, H. T., Purser, Autun, and Boetius, Antje

Abstract

The Central Arctic Ocean is one of the most oligotrophic oceans on Earth because of its sea- ice cover and short productive season. Nonetheless, across the peaks of extinct volcanic seamounts of the Langseth Ridge (87°N, 61°E), we observe a surprisingly dense benthic biomass. Bacteriosponges are the most abundant fauna within this community, with a mass of 460 g C m−2 and an estimated carbon demand of around 110 g C m−2 yr−1, despite export fluxes from regional primary productivity only sufficient to provide <1% of this required carbon. Observed sponge distribution, bulk and compound-specific isotope data of fatty acids suggest that the sponge microbiome taps into refractory dissolved and particulate organic matter, including remnants of an extinct seep community. The metabolic profile of bacter- iosponge fatty acids and expressed genes indicate that autotrophic symbionts contribute significantly to carbon assimilation. We suggest that this hotspot ecosystem is unique to the Central Arctic and associated with extinct seep biota, once fueled by degassing of the volcanic mounts.

Published
2022

12. Lineage-specific energy and carbon metabolism of sponge symbionts and contributions to the host carbon pool

Author

Burgsdorf, I., Sizikov, S., Squatrito, V., Britstein, M., Slaby, Beate M., Cerrano, C., Handley, K. M., Steindler, L., Burgsdorf, I., Sizikov, S., Squatrito, V., Britstein, M., Slaby, Beate M., Cerrano, C., Handley, K. M., and Steindler, L.

Abstract

Marine sponges host a wide diversity of microorganisms, which have versatile modes of carbon and energy metabolism. In this study we describe the major lithoheterotrophic and autotrophic processes in 21 microbial sponge-associated phyla using novel and existing genomic and transcriptomic datasets. We show that the main microbial carbon fixation pathways in sponges are the Calvin–Benson–Bassham cycle (energized by light in Cyanobacteria, by sulfur compounds in two orders of Gammaproteobacteria, and by a wide range of compounds in filamentous Tectomicrobia), the reductive tricarboxylic acid cycle (used by Nitrospirota), and the 3-hydroxypropionate/4-hydroxybutyrate cycle (active in Thaumarchaeota). Further, we observed that some sponge symbionts, in particular Acidobacteria, are capable of assimilating carbon through anaplerotic processes. The lithoheterotrophic lifestyle was widespread and CO oxidation is the main energy source for sponge lithoheterotrophs. We also suggest that the molybdenum-binding subunit of dehydrogenase (encoded by coxL) likely evolved to benefit also organoheterotrophs that utilize various organic substrates. Genomic potential does not necessarily inform on actual contribution of autotrophs to light and dark carbon budgets. Radioisotope assays highlight variability in the relative contributions of photo- and chemoautotrophs to the total carbon pool across different sponge species, emphasizing the importance of validating genomic potential with physiology experimentation.

Published
2022
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13. Giant sponge grounds of Central Arctic seamounts are associated with extinct seep life

Author

Morganti, Teresa M, Slaby, Beate M, de Kluijver, Anna, Busch, K, Hentschel, U, Middelburg, JJ, Mollenhauer, Gesine, Dannheim, Jennifer, Rapp, HT, Purser, Autun, Boetius, Antje, Morganti, Teresa M, Slaby, Beate M, de Kluijver, Anna, Busch, K, Hentschel, U, Middelburg, JJ, Mollenhauer, Gesine, Dannheim, Jennifer, Rapp, HT, Purser, Autun, and Boetius, Antje

Abstract

The Central Arctic Ocean is one of the most oligotrophic oceans on Earth because of its sea- ice cover and short productive season. Nonetheless, across the peaks of extinct volcanic seamounts of the Langseth Ridge (87°N, 61°E), we observe a surprisingly dense benthic biomass. Bacteriosponges are the most abundant fauna within this community, with a mass of 460 g C m−2 and an estimated carbon demand of around 110 g C m−2 yr−1, despite export fluxes from regional primary productivity only sufficient to provide <1% of this required carbon. Observed sponge distribution, bulk and compound-specific isotope data of fatty acids suggest that the sponge microbiome taps into refractory dissolved and particulate organic matter, including remnants of an extinct seep community. The metabolic profile of bacter- iosponge fatty acids and expressed genes indicate that autotrophic symbionts contribute significantly to carbon assimilation. We suggest that this hotspot ecosystem is unique to the Central Arctic and associated with extinct seep biota, once fueled by degassing of the volcanic mounts.

Published
2022

14. Large-scale biodiversity patterns of deep-sea microbes: Environmental drivers and sustainability of the global deep-sea sponge microbiome

Author

Busch, Kathrin, Slaby, Beate M., Bach, W., Boetius, Antje, Clefsen, Ina, Colaco, A., Creemers, M., Cristobo, J., Federwisch, L., Franke, Andrea, Gavriilidou, A., Hethke, Andrea, Kenchington, E., Mienis, F., Mills, S., Riesgo, A., Rios, P., Roberts, E. M., Sipkema, D., Pita, Lucia, Schupp, P. J., Xavier, J., Rapp, H. T., Hentschel, Ute, Busch, Kathrin, Slaby, Beate M., Bach, W., Boetius, Antje, Clefsen, Ina, Colaco, A., Creemers, M., Cristobo, J., Federwisch, L., Franke, Andrea, Gavriilidou, A., Hethke, Andrea, Kenchington, E., Mienis, F., Mills, S., Riesgo, A., Rios, P., Roberts, E. M., Sipkema, D., Pita, Lucia, Schupp, P. J., Xavier, J., Rapp, H. T., and Hentschel, Ute

Published
2022

15. The Deep-sea Sponge Microbiome Project: Biodiversity, environmental drivers and sustainability of the global deep-sea sponge microbiome

Author

Busch, Kathrin, Slaby, Beate M., Bach, W., Boetius, Antje, Clefsen, Ina, Colaco, A., Creemers, M., Cristobo, J., Federwisch, L., Franke, A., Gavriilidou, A., Hethke, Andrea, Kenchington, E., Mienis, F., Mills, S., Riesgo, A., Rios, P., Roberts, E. M., Sipkema, D., Pita, Lucia, Schupp, P. J., Xavier, J., Rapp, H. T., Hentschel, Ute, Busch, Kathrin, Slaby, Beate M., Bach, W., Boetius, Antje, Clefsen, Ina, Colaco, A., Creemers, M., Cristobo, J., Federwisch, L., Franke, A., Gavriilidou, A., Hethke, Andrea, Kenchington, E., Mienis, F., Mills, S., Riesgo, A., Rios, P., Roberts, E. M., Sipkema, D., Pita, Lucia, Schupp, P. J., Xavier, J., Rapp, H. T., and Hentschel, Ute

Published
2022

16. Biodiversity, environmental drivers, and sustainability of the global deep-sea sponge microbiome

Author

European Commission, German Research Foundation, Foundation for Science and Technology, Helmholtz Association, Agencia Estatal de Investigación (España), Bush, Kathrin, Slaby, Beate M., Bach, Wolfgang, Boetius, Antje, Clefsen, Ina, Colaço, Ana, Creemers, Marie, Cristobo, Javier, Federwisch, Luisa, Franke, Andre, Gavriilidou, Asimenia, Hethke, Andrea, Kenchington, Ellen, Mienis, Furu, Mills, Sadie, Riesgo Gil, Ana, Ríos, Pilar, Roberts, Emyr Martyn, Sipkema, Detmer, Pita, Lucía, Schupp, Peter J., Xavier, Joana R., Rapp, Hans Tore, Henstchel, Ute, European Commission, German Research Foundation, Foundation for Science and Technology, Helmholtz Association, Agencia Estatal de Investigación (España), Bush, Kathrin, Slaby, Beate M., Bach, Wolfgang, Boetius, Antje, Clefsen, Ina, Colaço, Ana, Creemers, Marie, Cristobo, Javier, Federwisch, Luisa, Franke, Andre, Gavriilidou, Asimenia, Hethke, Andrea, Kenchington, Ellen, Mienis, Furu, Mills, Sadie, Riesgo Gil, Ana, Ríos, Pilar, Roberts, Emyr Martyn, Sipkema, Detmer, Pita, Lucía, Schupp, Peter J., Xavier, Joana R., Rapp, Hans Tore, and Henstchel, Ute

Abstract

In the deep ocean symbioses between microbes and invertebrates are emerging as key drivers of ecosystem health and services. We present a large-scale analysis of microbial diversity in deep-sea sponges (Porifera) from scales of sponge individuals to ocean basins, covering 52 locations, 1077 host individuals translating into 169 sponge species (including understudied glass sponges), and 469 reference samples, collected anew during 21 ship-based expeditions. We demonstrate the impacts of the sponge microbial abundance status, geographic distance, sponge phylogeny, and the physicalbiogeochemical environment as drivers of microbiome composition, in descending order of relevance. Our study further discloses that fundamental concepts of sponge microbiology apply robustly to sponges from the deep-sea across distances of >10,000 km. Deep-sea sponge microbiomes are less complex, yet more heterogeneous, than their shallow-water counterparts. Our analysis underscores the uniqueness of each deep-sea sponge ground based on which we provide critical knowledge for conservation of these vulnerable ecosystems.

Published
2022

19. Bacterial precursors and unsaturated long-chain fatty acids are biomarkers of North-Atlantic deep-sea demosponges

Author

de Kluijver, Anna, Nierop, Klaas G J, Morganti, Teresa M, Bart, Martijn C, Slaby, Beate M, Hanz, Ulrike, de Goeij, Jasper M, Mienis, Furu, Middelburg, Jack J, Geochemistry, GeoLab Algemeen, Bio-, hydro-, and environmental geochemistry, Geochemistry, GeoLab Algemeen, Bio-, hydro-, and environmental geochemistry, and Freshwater and Marine Ecology (IBED, FNWI)

Subjects
0106 biological sciences, Composite Particles, Aquatic Organisms, 01 natural sciences, Biochemistry, Isomers, Isotopes, Abundance (ecology), Stereochemistry, Geodia, 0303 health sciences, Multidisciplinary, δ13C, biology, Agricultural and Biological Sciences(all), Chemistry, Physics, Fatty Acids, Eukaryota, Lipids, Porifera, Sponges, Physical Sciences, Fatty Acids, Unsaturated, Medicine, Research Article, Chemical Elements, Atoms, Science, Geodia barretti, 03 medical and health sciences, Isomerism, Stelletta, Animals, Hexanes, 14. Life underwater, Particle Physics, General, 030304 developmental biology, Degree of unsaturation, Bacteria, Biochemistry, Genetics and Molecular Biology(all), 010604 marine biology & hydrobiology, Organisms, Chemical Compounds, Biology and Life Sciences, biology.organism_classification, Invertebrates, Hydrocarbons, Sponge, Zoology, Sulfur, Genetics and Molecular Biology(all)
Abstract

Sponges produce distinct fatty acids (FAs) that (potentially) can be used as chemotaxonomic and ecological biomarkers to study endosymbiont-host interactions and the functional ecology of sponges. Here, we present FA profiles of five common habitat-building deep-sea sponges (class Demospongiae, order Tetractinellida), which are classified as high microbial abundance (HMA) species. Geodia hentscheli, G. parva, G. atlantica, G. barretti, and Stelletta rhaphidiophora were collected from boreal and Arctic sponge grounds in the North-Atlantic Ocean. Bacterial FAs dominated in all five species and particularly isomeric mixtures of mid-chain branched FAs (MBFAs, 8- and 9-Me-C16:0 and 10- and 11-Me-C18:0) were found in high abundance (together ≥ 20% of total FAs) aside more common bacterial markers. In addition, the sponges produced long-chain linear, mid- and a(i)-branched unsaturated FAs (LCFAs) with a chain length of 24‒28 C atoms and had predominantly the typical Δ5,9 unsaturation, although the Δ9,19 and (yet undescribed) Δ11,21 unsaturations were also identified. G. parva and S. rhaphidiophora each produced distinct LCFAs, while G. atlantica, G. barretti, and G. hentscheli produced similar LCFAs, but in different ratios. The different bacterial precursors varied in carbon isotopic composition (δ13C), with MBFAs being more enriched compared to other bacterial (linear and a(i)-branched) FAs. We propose biosynthetic pathways for different LCFAs from their bacterial precursors, that are consistent with small isotopic differences found in LCFAs. Indeed, FA profiles of deep-sea sponges can serve as chemotaxonomic markers and support the concept that sponges acquire building blocks from their endosymbiotic bacteria.

Published
2021

20. Lineage-specific energy and carbon metabolism of sponge symbionts and contributions to the host carbon pool

Author

Burgsdorf, I., Sizikov, S., Squatrito, V., Britstein, M., Slaby, Beate M., Cerrano, C., Handley, K. M., Steindler, L., Burgsdorf, I., Sizikov, S., Squatrito, V., Britstein, M., Slaby, Beate M., Cerrano, C., Handley, K. M., and Steindler, L.

Abstract

Marine sponges host a wide diversity of microorganisms, which have versatile modes of carbon and energy metabolism. In this study we describe the major lithoheterotrophic and autotrophic processes in 21 microbial sponge-associated phyla using novel and existing genomic and transcriptomic datasets. We show that the main microbial carbon fixation pathways in sponges are the Calvin–Benson–Bassham cycle (energized by light in Cyanobacteria, by sulfur compounds in two orders of Gammaproteobacteria, and by a wide range of compounds in filamentous Tectomicrobia), the reductive tricarboxylic acid cycle (used by Nitrospirota), and the 3-hydroxypropionate/4-hydroxybutyrate cycle (active in Thaumarchaeota). Further, we observed that some sponge symbionts, in particular Acidobacteria, are capable of assimilating carbon through anaplerotic processes. The lithoheterotrophic lifestyle was widespread and CO oxidation is the main energy source for sponge lithoheterotrophs. We also suggest that the molybdenum-binding subunit of dehydrogenase (encoded by coxL) likely evolved to benefit also organoheterotrophs that utilize various organic substrates. Genomic potential does not necessarily inform on actual contribution of autotrophs to light and dark carbon budgets. Radioisotope assays highlight variability in the relative contributions of photo- and chemoautotrophs to the total carbon pool across different sponge species, emphasizing the importance of validating genomic potential with physiology experimentation.

Published
2021

21. Bacterial precursors and unsaturated long-chain fatty acids are biomarkers of North-Atlantic deep-sea demosponges

Author

Rodrigues, Clara F., de Kluijver, Anna, Nierop, Klaas G. J., Morganti, Teresa M., Bart, Martijn C., Slaby, Beate M., Hanz, Ulrike, de Goeij, Jasper M., Mienis, Furu, Middelburg, Jack J., Rodrigues, Clara F., de Kluijver, Anna, Nierop, Klaas G. J., Morganti, Teresa M., Bart, Martijn C., Slaby, Beate M., Hanz, Ulrike, de Goeij, Jasper M., Mienis, Furu, and Middelburg, Jack J.

Abstract

Sponges produce distinct fatty acids (FAs) that (potentially) can be used as chemotaxonomic and ecological biomarkers to study endosymbiont-host interactions and the functional ecology of sponges. Here, we present FA profiles of five common habitat-building deep-sea sponges (class Demospongiae, order Tetractinellida), which are classified as high microbial abundance (HMA) species. Geodia hentscheli, G. parva, G. atlantica, G. barretti, and Stelletta rhaphidiophora were collected from boreal and Arctic sponge grounds in the North-Atlantic Ocean. Bacterial FAs dominated in all five species and particularly isomeric mixtures of mid-chain branched FAs (MBFAs, 8- and 9-Me-C16:0 and 10- and 11-Me-C18:0) were found in high abundance (together ≥ 20% of total FAs) aside more common bacterial markers. In addition, the sponges produced long-chain linear, mid- and a(i)-branched unsaturated FAs (LCFAs) with a chain length of 24‒28 C atoms and had predominantly the typical Δ5,9 unsaturation, although the Δ9,19 and (yet undescribed) Δ11,21 unsaturations were also identified. G. parva and S. rhaphidiophora each produced distinct LCFAs, while G. atlantica, G. barretti, and G. hentscheli produced similar LCFAs, but in different ratios. The different bacterial precursors varied in carbon isotopic composition (δ13C), with MBFAs being more enriched compared to other bacterial (linear and a(i)-branched) FAs. We propose biosynthetic pathways for different LCFAs from their bacterial precursors, that are consistent with small isotopic differences found in LCFAs. Indeed, FA profiles of deep-sea sponges can serve as chemotaxonomic markers and support the concept that sponges acquire building blocks from their endosymbiotic bacteria.

Published
2021

22. Bacterial precursors and unsaturated long-chain fatty acids are biomarkers of North-Atlantic deep-sea demosponges

Author

Geochemistry, GeoLab Algemeen, Bio-, hydro-, and environmental geochemistry, de Kluijver, Anna, Nierop, Klaas G J, Morganti, Teresa M, Bart, Martijn C, Slaby, Beate M, Hanz, Ulrike, de Goeij, Jasper M, Mienis, Furu, Middelburg, Jack J, Geochemistry, GeoLab Algemeen, Bio-, hydro-, and environmental geochemistry, de Kluijver, Anna, Nierop, Klaas G J, Morganti, Teresa M, Bart, Martijn C, Slaby, Beate M, Hanz, Ulrike, de Goeij, Jasper M, Mienis, Furu, and Middelburg, Jack J

Published
2021

23. Microbial strategies for survival in the glass sponge Vazella pourtalesii

Author

Bayer, Kristina, Busch, Kathrin, Kenchington, E., Beazley, L., Maldonado, M, Franzenburg, S., Michels, J., Hentschel, Ute, Slaby, Beate M., Bayer, Kristina, Busch, Kathrin, Kenchington, E., Beazley, L., Maldonado, M, Franzenburg, S., Michels, J., Hentschel, Ute, and Slaby, Beate M.

Published
2021

24. A Microbial Nitrogen Engine Modulated by Bacteriosyncytia in Hexactinellid Sponges: Ecological Implications for Deep-Sea Communities

Author

Maldonado, Manuel, López-Acosta, María, Busch, Kathrin, Slaby, Beate M., Bayer, Kristina, Beazley, Lindsay, Hentschel, Ute, Kenchington, Ellen, Rapp, Hans Tore, Maldonado, Manuel, López-Acosta, María, Busch, Kathrin, Slaby, Beate M., Bayer, Kristina, Beazley, Lindsay, Hentschel, Ute, Kenchington, Ellen, and Rapp, Hans Tore

Abstract

Hexactinellid sponges are common in the deep sea, but their functional integration into those ecosystems remains poorly understood. The phylogenetically related species Schaudinnia rosea and Vazella pourtalesii were herein incubated for nitrogen and phosphorous, returning markedly different nutrient fluxes. Transmission electron microscopy (TEM) revealed S. rosea to host a low abundance of extracellular microbes, while Vazella pourtalesii showed higher microbial abundance and hosted most microbes within bacteriosyncytia, a novel feature for Hexactinellida. Amplicon sequences of the microbiome corroborated large between-species differences, also between the sponges and the seawater of their habitats. Metagenome-assembled genome of the V. pourtalesii microbiota revealed genes coding for enzymes operating in nitrification, denitrification, dissimilatory nitrate reduction to ammonium, nitrogen fixation, and ammonia/ammonium assimilation. In the nitrification and denitrification pathways some enzymes were missing, but alternative bridging routes allow the microbiota to close a N cycle in the holobiont. Interconnections between aerobic and anaerobic pathways may facilitate the sponges to withstand the low-oxygen conditions of deep-sea habitats. Importantly, various N pathways coupled to generate ammonium, which, through assimilation, fosters the growth of the sponge microbiota. TEM showed that the farmed microbiota is digested by the sponge cells, becoming an internal food source. This microbial farming demands more ammonium that can be provided internally by the host sponges and some 2.6 million kg of ammonium from the seawater become annually consumed by the aggregations of V. pourtalesii. Such ammonium removal is likely impairing the development of the free-living bacterioplankton and the survival chances of other sponge species that feed on bacterioplankton. Such nutritional competitive exclusion would favor the monospecific character of the V. pourtalesii aggregation

Published
2021
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25. A genomic view of the microbiome of coral reef demosponges

Author

Robbins, S. J., Song, W., Engelberts, J. P., Glasl, B., Slaby, Beate M., Boyd, J., Marangon, E., Botté, E. S., Laffy, P., Thomas, T., Webster, N. S., Robbins, S. J., Song, W., Engelberts, J. P., Glasl, B., Slaby, Beate M., Boyd, J., Marangon, E., Botté, E. S., Laffy, P., Thomas, T., and Webster, N. S.

Abstract

Sponges underpin the productivity of coral reefs, yet few of their microbial symbionts have been functionally characterised. Here we present an analysis of ~1200 metagenome-assembled genomes (MAGs) spanning seven sponge species and 25 microbial phyla. Compared to MAGs derived from reef seawater, sponge-associated MAGs were enriched in glycosyl hydrolases targeting components of sponge tissue, coral mucus and macroalgae, revealing a critical role for sponge symbionts in cycling reef organic matter. Further, visualisation of the distribution of these genes amongst symbiont taxa uncovered functional guilds for reef organic matter degradation. Genes for the utilisation of sialic acids and glycosaminoglycans present in sponge tissue were found in specific microbial lineages that also encoded genes for attachment to sponge-derived fibronectins and cadherins, suggesting these lineages can utilise specific structural elements of sponge tissue. Further, genes encoding CRISPR and restriction-modification systems used in defence against mobile genetic elements were enriched in sponge symbionts, along with eukaryote-like gene motifs thought to be involved in maintaining host association. Finally, we provide evidence that many of these sponge-enriched genes are laterally transferred between microbial taxa, suggesting they confer a selective advantage within the sponge niche and therefore play a critical role in host ecology and evolution.

Published
2021
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26. Deciphering a Marine Bone-Degrading Microbiome Reveals a Complex Community Effort

Author

Borchert, Erik, García-Moyano, Antonio, Sanchez-Carrillo, Sergio, Dahlgren, Thomas G., Slaby, Beate M., Bjerga, Gro Elin Kjæreng, Ferrer, Manuel, Franzenburg, Sören, Hentschel, Ute, Borchert, Erik, García-Moyano, Antonio, Sanchez-Carrillo, Sergio, Dahlgren, Thomas G., Slaby, Beate M., Bjerga, Gro Elin Kjæreng, Ferrer, Manuel, Franzenburg, Sören, and Hentschel, Ute

Abstract

The marine bone biome is a complex assemblage of macro- and microorganisms; however, the enzymatic repertoire to access bone-derived nutrients remains unknown. The bone matrix is a composite material made up mainly of organic collagen and inorganic hydroxyapatite. We conducted field experiments to study microbial assemblages that can use organic bone components as nutrient source. Bovine and turkey bones were deposited at 69 m depth in a Norwegian fjord (Byfjorden, Bergen). Metagenomic sequence analysis was used to assess the functional potential of microbial assemblages from bone surface and the bone-eating worm Osedax mucofloris, which is a frequent colonizer of whale falls and known to degrade bone. The bone microbiome displayed a surprising taxonomic diversity revealed by the examination of 59 high-quality metagenome-assembled genomes from at least 23 bacterial families. Over 700 genes encoding enzymes from 12 relevant enzymatic families pertaining to collagenases, peptidases, and glycosidases putatively involved in bone degradation were identified. Metagenome-assembled genomes (MAGs) of the class Bacteroidia contained the most diverse gene repertoires. We postulate that demineralization of inorganic bone components is achieved by a timely succession of a closed sulfur biogeochemical cycle between sulfur-oxidizing and sulfur-reducing bacteria, causing a drop in pH and subsequent enzymatic processing of organic components in the bone surface communities. An unusually large and novel collagen utilization gene cluster was retrieved from one genome belonging to the gammaproteobacterial genus Colwellia.

Published
2021
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27. Deciphering a marine bone-degrading microbiome reveals a complex community effort

Author

European Commission, Federal Ministry of Education and Research (Germany), Norwegian Research Council, Agencia Estatal de Investigación (España), Ministerio de Economía y Competitividad (España), Ministerio de Ciencia e Innovación (España), Borchert, Erik, García-Moyano, Antonio, Sánchez-Carrillo, Sergio, Dahlgren, Thomas G., Slaby, Beate M., Bjerga, Gro Elin Kjæreng, Ferrer, Manuel, Franzenburg, Soeren, Hentschel, Ute, European Commission, Federal Ministry of Education and Research (Germany), Norwegian Research Council, Agencia Estatal de Investigación (España), Ministerio de Economía y Competitividad (España), Ministerio de Ciencia e Innovación (España), Borchert, Erik, García-Moyano, Antonio, Sánchez-Carrillo, Sergio, Dahlgren, Thomas G., Slaby, Beate M., Bjerga, Gro Elin Kjæreng, Ferrer, Manuel, Franzenburg, Soeren, and Hentschel, Ute

Abstract

[EN] The marine bone biome is a complex assemblage of macro- and microorganisms; however, the enzymatic repertoire to access bone-derived nutrients remains unknown. The bone matrix is a composite material made up mainly of organic collagen and inorganic hydroxyapatite. We conducted field experiments to study microbial assemblages that can use organic bone components as nutrient source. Bovine and Turkey bones were deposited at 69 m depth in a Norwegian fjord (Byfjorden, Bergen). Metagenomic sequence analysis was used to assess the functional potential of microbial assemblages from bone surface and the bone-eating worm Osedax mucofloris, which is a frequent colonizer of whale falls and known to degrade bone. The bone microbiome displayed a surprising taxonomic diversity revealed by the examination of 59 high-quality metagenome-assembled genomes from at least 23 bacterial families. Over 700 genes encoding enzymes from 12 relevant enzymatic families pertaining to collagenases, peptidases, and glycosidases putatively involved in bone degradation were identified. Metagenome-assembled genomes (MAGs) of the class Bacteroidia contained the most diverse gene repertoires. We postulate that demineralization of inorganic bone components is achieved by a timely succession of a closed sulfur biogeochemical cycle between sulfur-oxidizing and sulfur-reducing bacteria, causing a drop in pH and subsequent enzymatic processing of organic components in the bone surface communities. An unusually large and novel collagen utilization gene cluster was retrieved from one genome belonging to the gammaproteobacterial genus Colwellia. IMPORTANCE Bones are an underexploited, yet potentially profitable feedstock for biotechnological advances and value chains, due to the sheer amounts of residues produced by the modern meat and poultry processing industry. In this metagenomic study, we decipher the microbial pathways and enzymes that we postulate to be involved in bone degradation in the marine e

Published
2021

28. Microbial Nitrogen Engine Modulated by Bacteriosyncytia in Hexactinellid Sponges: Ecological Implications for Deep-Sea Communities

Author

Maldonado, Manuel, López-Acosta, María, Busch, Kathrin, Slaby, Beate M., Bayer, Kristina, Beazley. L., Hentschel, Ute, Kenchington, Ellen L. R., Rapp, H.T., Maldonado, Manuel, López-Acosta, María, Busch, Kathrin, Slaby, Beate M., Bayer, Kristina, Beazley. L., Hentschel, Ute, Kenchington, Ellen L. R., and Rapp, H.T.

Abstract

Hexactinellid sponges are common in the deep sea, but their functional integration into those ecosystems remains poorly understood. The phylogenetically related species Schaudinnia rosea and Vazella pourtalesii were herein incubated for nitrogen and phosphorous, returning markedly different nutrient fluxes. Transmission electron microscopy (TEM) revealed S. rosea to host a low abundance of extracellular microbes, while Vazella pourtalesii showed higher microbial abundance and hosted most microbes within bacteriosyncytia, a novel feature for Hexactinellida. Amplicon sequences of the microbiome corroborated large between-species differences, also between the sponges and the seawater of their habitats. Metagenome-assembled genome of the V. pourtalesii microbiota revealed genes coding for enzymes operating in nitrification, denitrification, dissimilatory nitrate reduction to ammonium, nitrogen fixation, and ammonia/ammonium assimilation. In the nitrification and denitrification pathways some enzymes were missing, but alternative bridging routes allow the microbiota to close a N cycle in the holobiont. Interconnections between aerobic and anaerobic pathways may facilitate the sponges to withstand the low-oxygen conditions of deep-sea habitats. Importantly, various N pathways coupled to generate ammonium, which, through assimilation, fosters the growth of the sponge microbiota. TEM showed that the farmed microbiota is digested by the sponge cells, becoming an internal food source. This microbial farming demands more ammonium that can be provided internally by the host sponges and some 2.6 million kg of ammonium from the seawater become annually consumed by the aggregations of V. pourtalesii. Such ammonium removal is likely impairing the development of the free-living bacterioplankton and the survival chances of other sponge species that feed on bacterioplankton. Such nutritional competitive exclusion would favor the monospecific character of the V. pourtalesii aggregation

Published
2021

29. Microbial strategies for survival in the glass sponge Vazella pourtalesii

Author

Bayer, Kristina, Busch, Kathrin, Kenchington, Ellen, Beazley, Lindsay, Franzenburg, Sören, Michels, Jan, Hentschel, Ute, Slaby, Beate M., Bayer, Kristina, Busch, Kathrin, Kenchington, Ellen, Beazley, Lindsay, Franzenburg, Sören, Michels, Jan, Hentschel, Ute, and Slaby, Beate M.

Abstract

Few studies have thus far explored the microbiomes of glass sponges (Hexactinellida). The present study seeks to elucidate the composition of the microbiota associated with the glass sponge Vazella pourtalesii and the functional strategies of the main symbionts. We combined microscopic approaches with metagenome-guided microbial genome reconstruction and amplicon community profiling towards this goal. Microscopic imaging revealed that the host and microbial cells appeared within dense biomass patches that are presumably syncytial tissue aggregates. Based on abundances in amplicon libraries and metagenomic data, SAR324 bacteria, Crenarchaeota, Patescibacteria and Nanoarchaeota were identified as abundant members of the V. pourtalesii microbiome and their genomic potentials were thus analyzed in detail. A general pattern emerged in that the V. pourtalesii symbionts had very small genome sizes in the range of 0.5-2.2 Mb and low GC contents, even below those of seawater relatives. Based on functional analyses of metagenome-assembled genomes (MAGs), we propose two major microbial strategies: the “givers”, namely Crenarchaeota and SAR324, heterotrophs and facultative anaerobes, produce and partly secrete all required amino acids and vitamins. The “takers”, Nanoarchaeota and Patescibacteria, are anaerobes with reduced genomes that tap into the microbial community for resources, e.g., lipids and DNA, likely using pili-like structures. We posit that the existence of microbial cells in sponge syncytia together with the low-oxygen conditions in the seawater environment are factors that shape the unique compositional and functional properties of the microbial community associated with V. pourtalesii . Importance: We investigated the microbial community of V. pourtalesii that forms globally unique, monospecific sponge grounds under low-oxygen conditions on the Scotian Shelf, where it plays a key role for its vulnerable ecosystem. The microbial community was found to be concentra

Published
2020
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37. Marine Sponge Holobionts in Health and Disease

Author

Li, Zhiyong, Slaby, Beate M., Franke, Andrea, Rix, Laura, Pita, Lucia, Bayer, Kristina, Jahn, Martin T., Hentschel, Ute, Li, Zhiyong, Slaby, Beate M., Franke, Andrea, Rix, Laura, Pita, Lucia, Bayer, Kristina, Jahn, Martin T., and Hentschel, Ute

Abstract

Sponges—like all multicellular organisms—are holobionts, complex ecosystems comprising the host and its microbiota. The symbiosis of sponges with their microbial communities is a highly complex system, requiring interaction mechanisms and adaptation on both sides. The microbiome seems to rely on eukaryotic-like protein domains, such as ankyrins, modifications of the lipopolysaccharide structure, CRISPR-Cas, toxin-antitoxin, and restriction-modification systems, as well as secondary metabolism to communicate with the host and within the microbial community, evade phagocytosis, and defend itself against foreign DNA. Secondary metabolites produced by certain symbionts may even defend the entire holobiont against predators. On the other hand, the immune system of the sponge itself has evolved to discriminate not only between self and nonself but also between its associated microbiota and foreign microbes, such as food bacteria. Sponge holobionts are inextricably dependent on the surrounding environmental conditions due to their sessile nature. Thus, we discuss the link between environmental stress and sponge disease and dysbiosis, with a particular focus on the holobiont’s response to ongoing global change. While some species may be the “winners of climate change,” other species are adversely affected, e.g., by metabolic and immune suppression, as well as microbiome shifts resulting in loss of symbiotic functions. Hence, a much better understanding of sponge holobionts and the underlying molecular mechanisms of host-microbe interaction is required before the fate of sponge holobionts in a changing ocean can finally be validated.

Published
2019
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38. Phylogeny and genomics of SAUL, an enigmatic bacterial lineage frequently associated with marine sponges

Author

Astudillo-García, Carmen, Slaby, Beate M., Waite, David W., Bayer, Kristina, Hentschel, Ute, and Taylor, Michael W.

Abstract

Many marine sponges contain dense and diverse communities of associated microorganisms. Members of the “sponge-associated unclassified lineage” (SAUL) are frequently recorded from sponges, yet little is known about these bacteria. Here we investigated the distribution and phylogenetic status of SAUL. A meta-analysis of the available literature revealed the widespread distribution of this clade and its association with taxonomically varied sponge hosts. Phylogenetic analyses, conducted using both 16S rRNA gene-based phylogeny and concatenated marker protein sequences, revealed that SAUL is a sister clade of the candidate phylum “Latescibacteria”. Furthermore, we conducted a comprehensive analysis of two draft genomes assembled from sponge metagenomes, revealing novel insights into the physiology of this symbiont. Metabolic reconstruction suggested that SAUL members are aerobic bacteria with facultative anaerobic metabolism, with the capacity to degrade multiple sponge- and algae-derived carbohydrates. We described for the first time in a sponge symbiont the putative genomic capacity to transport phosphate into the cell and to produce and store polyphosphate granules, presumably constituting a phosphate reservoir for the sponge host in deprivation periods. Our findings suggest that the lifestyle of SAUL is symbiotic with the host sponge, and identify symbiont factors which may facilitate the establishment and maintenance of this relationship.

Published
2018

39. Marine Sponges as Chloroflexi Hot Spots: Genomic Insights and High-Resolution Visualization of an Abundant and Diverse Symbiotic Clade

Author

Bayer, Kristina, Jahn, Martin T., Slaby, Beate M., Moitinho-Silva, Lucas, and Hentschel, Ute

Subjects
sponge symbiosis, Horizon 2020, animal structures, single-cell genomics, Deep-sea Sponge Grounds Ecosystems of the North Atlantic: an integrated approach towards their preservation and sustainable exploitation, fungi, FISH-CLEM, lcsh:QR1-502, Grant Agreement No 679849, Chloroflexi, biochemical phenomena, metabolism, and nutrition, DOM degradation, Microbiology, lcsh:Microbiology, QR1-502, Host-Microbe Biology, SponGES, metagenomic binning, bacteria, European Union (EU), metabolism, Research Article
Abstract

Chloroflexi represent a widespread, yet enigmatic bacterial phylum with few cultivated members. We used metagenomic and single-cell genomic approaches to characterize the functional gene repertoire of Chloroflexi symbionts in marine sponges. The results of this study suggest clade-specific metabolic specialization and that Chloroflexi symbionts have the genomic potential for dissolved organic matter (DOM) degradation from seawater. Considering the abundance and dominance of sponges in many benthic environments, we predict that the role of sponge symbionts in biogeochemical cycles is larger than previously thought., Members of the widespread bacterial phylum Chloroflexi can dominate high-microbial-abundance (HMA) sponge microbiomes. In the Sponge Microbiome Project, Chloroflexi sequences amounted to 20 to 30% of the total microbiome of certain HMA sponge genera with the classes/clades SAR202, Caldilineae, and Anaerolineae being the most prominent. We performed metagenomic and single-cell genomic analyses to elucidate the functional gene repertoire of Chloroflexi symbionts of Aplysina aerophoba. Eighteen draft genomes were reconstructed and placed into phylogenetic context of which six were investigated in detail. Common genomic features of Chloroflexi sponge symbionts were related to central energy and carbon converting pathways, amino acid and fatty acid metabolism, and respiration. Clade-specific metabolic features included a massively expanded genomic repertoire for carbohydrate degradation in Anaerolineae and Caldilineae genomes, but only amino acid utilization by SAR202. While Anaerolineae and Caldilineae import cofactors and vitamins, SAR202 genomes harbor genes encoding components involved in cofactor biosynthesis. A number of features relevant to symbiosis were further identified, including CRISPR-Cas systems, eukaryote-like repeat proteins, and secondary metabolite gene clusters. Chloroflexi symbionts were visualized in the sponge extracellular matrix at ultrastructural resolution by the fluorescence in situ hybridization-correlative light and electron microscopy (FISH-CLEM) method. Carbohydrate degradation potential was reported previously for “Candidatus Poribacteria” and SAUL, typical symbionts of HMA sponges, and we propose here that HMA sponge symbionts collectively engage in degradation of dissolved organic matter, both labile and recalcitrant. Thus, sponge microbes may not only provide nutrients to the sponge host, but they may also contribute to dissolved organic matter (DOM) recycling and primary productivity in reef ecosystems via a pathway termed the sponge loop. IMPORTANCE Chloroflexi represent a widespread, yet enigmatic bacterial phylum with few cultivated members. We used metagenomic and single-cell genomic approaches to characterize the functional gene repertoire of Chloroflexi symbionts in marine sponges. The results of this study suggest clade-specific metabolic specialization and that Chloroflexi symbionts have the genomic potential for dissolved organic matter (DOM) degradation from seawater. Considering the abundance and dominance of sponges in many benthic environments, we predict that the role of sponge symbionts in biogeochemical cycles is larger than previously thought.

Published
2018
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40. Metagenomic binning reveals versatile nutrient cycling and distinct adaptive features in alphaproteobacterial symbionts of marine sponges

Author

Karimi, Elham, Slaby, Beate M., Soares, André R, Blom, Jochen, Hentschel, Ute, Costa, Rodrigo, Karimi, Elham, Slaby, Beate M., Soares, André R, Blom, Jochen, Hentschel, Ute, and Costa, Rodrigo

Abstract

Marine sponges are early-branched metazoans known to harbor dense and diverse microbial communities. Yet the role of the so far uncultivable alphaproteobacterial lineages that populate these sessile invertebrates remains unclear. We applied a sequence composition-dependent binning approach to assemble one Rhodospirillaceae genome from the Spongia officinalis microbial metagenome and contrast its functional features with those of closely related sponge-associated and free-living genomes. Both symbiotic and free-living Rhodospirillaceae shared a suite of common features, possessing versatile carbon, nitrogen, sulfur and phosphorus metabolisms. Symbiotic genomes could be distinguished from their free-living counterparts by the lack of chemotaxis and motility traits, enrichment of genes required for the uptake and utilization of organic sulfur compounds—particularly taurine—, higher diversity and abundance of ABC transporters, and a distinct repertoire of genes involved in natural product biosynthesis, plasmid stability, cell detoxification and oxidative stress remediation. These sessile symbionts may more effectively contribute to host fitness via nutrient exchange, and also host detoxification and chemical defense. Considering the worldwide occurrence and high diversity of sponge-associated Rhodospirillaceae verified here using a tailored in silico approach, we suggest that these organisms are not only relevant to holobiont homeostasis but also to nutrient cycling in benthic ecosystems.

Published
2018
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41. The sponge holobiont in a changing ocean: from microbes to ecosystems

Author

Pita, Lucia, Rix, Laura, Slaby, Beate M., Franke, Andrea, Hentschel, Ute, Pita, Lucia, Rix, Laura, Slaby, Beate M., Franke, Andrea, and Hentschel, Ute

Abstract

The recognition that all macroorganisms live in symbiotic association with microbial communities has opened up a new field in biology. Animals, plants, and algae are now considered holobionts, complex ecosystems consisting of the host, the microbiota, and the interactions among them. Accordingly, ecological concepts can be applied to understand the host-derived and microbial processes that govern the dynamics of the interactive networks within the holobiont. In marine systems, holobionts are further integrated into larger and more complex communities and ecosystems, a concept referred to as “nested ecosystems.” In this review, we discuss the concept of holobionts as dynamic ecosystems that interact at multiple scales and respond to environmental change. We focus on the symbiosis of sponges with their microbial communities—a symbiosis that has resulted in one of the most diverse and complex holobionts in the marine environment. In recent years, the field of sponge microbiology has remarkably advanced in terms of curated databases, standardized protocols, and information on the functions of the microbiota. Like a Russian doll, these microbial processes are translated into sponge holobiont functions that impact the surrounding ecosystem. For example, the sponge-associated microbial metabolisms, fueled by the high filtering capacity of the sponge host, substantially affect the biogeochemical cycling of key nutrients like carbon, nitrogen, and phosphorous. Since sponge holobionts are increasingly threatened by anthropogenic stressors that jeopardize the stability of the holobiont ecosystem, we discuss the link between environmental perturbations, dysbiosis, and sponge diseases. Experimental studies suggest that the microbial community composition is tightly linked to holobiont health, but whether dysbiosis is a cause or a consequence of holobiont collapse remains unresolved. Moreover, the potential role of the microbiome in mediating the capacity for holobionts to acclim

Published
2018
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43. Draft Genome Sequences of 'Candidatus Synechococcus spongiarum,' Cyanobacterial Symbionts of the Mediterranean Sponge Aplysina aerophoba

Author

Slaby, Beate M. and Hentschel, Ute

Abstract

We report here four draft genome sequences belonging to clade F of the cyanobacterium “Candidatus Synechococcus spongiarum” of the marine sponge Aplysina aerophoba, which were collected from two nearby locations in the northern Adriatic Sea. The sequences provide the basis for within-clade comparisons between members of this widespread group of cyanobacterial sponge symbionts.

Published
2017

44. Exploring the microbiome of the Mediterranean sponge Aplysina aerophoba by single-cell and metagenomics

Author

Slaby, Beate M.

Abstract

Sponges (phylum Porifera) are evolutionary ancient, sessile filter-feeders that harbor a largely diverse microbial community within their internal mesohyl matrix. Throughout this thesis project, I aimed at exploring the adaptations of these symbionts to life within their sponge host by sequencing and analyzing the genomes of a variety of bacteria from the microbiome of the Mediterranean sponge Aplysina aerophoba. Employed methods were fluorescence-activated cell sorting with subsequent multiple displacement amplification and single-cell / ‘mini-metagenome’ sequencing, and metagenomic sequencing followed by differential coverage binning. These two main approaches both aimed at obtaining genome sequences of bacterial symbionts of A. aerophoba, that were then compared to each other and to references from other environments, to gain information on adaptations to the host sponge environment and on possible interactions with the host and within the microbial community. Cyanobacteria are frequent members of the sponge microbial community. My ‘mini-metagenome’ sequencing project delivered three draft genomes of “Candidatus Synechococcus spongiarum,” the cyanobacterial symbiont of A. aerophoba and many more sponges inhabiting the photic zone. The most complete of these genomes was compared to other clades of this symbiont and to closely related free-living cyanobacterial references in a collaborative project published in Burgsdorf I*, Slaby BM* et al. (2015; *shared first authorship). Although the four clades of “Ca. Synechococcus spongiarum” from the four sponge species A. aerophoba, Ircinia variabilis, Theonella swinhoei, and Carteriospongia foliascens were approximately 99% identical on the level of 16S rRNA gene sequences, they greatly differed on the genomic level. Not only the genome sizes were different from clade to clade, but also the gene content and a number of features including proteins containing the eukaryotic-type domains leucine-rich repeats or tetratricopeptide repeats. On the other hand, the four clades shared a number of features such as ankyrin repeat domain-containing proteins that seemed to be conserved also among other microbial phyla in different sponge hosts and from different geographic locations. A possible novel mechanism for host phagocytosis evasion and phage resistance by means of an altered O antigen of the lipopolysaccharide was identified. To test previous hypotheses on adaptations of sponge-associated bacteria on a broader spectrum of the microbiome of A. aerophoba while also taking a step forward in methodology, I developed a bioinformatic pipeline to combine metagenomic Illumina short-read sequencing data with PacBio long-read data. At the beginning of this project, no pipelines to combine short-read and long-read data for metagenomics were published, and at time of writing, there are still no projects published with a comparable aim of un-targeted assembly, binning and analysis of a metagenome. I tried a variety of assembly programs and settings on a simulated test dataset reflecting the properties of the real metagenomic data. The developed assembly pipeline improved not only the overall assembly statistics, but also the quality of the binned genomes, which was evaluated by comparison to the originally published genome assemblies. The microbiome of A. aerophoba was studied from various angles in the recent years, but only genomes of the candidate phylum Poribacteria and the cyanobacterial sequences from my above-described project have been published to date. By applying my newly developed assembly pipeline to a metagenomic dataset of A. aerophoba consisting of a PacBio long-read dataset and six Illumina short-read datasets optimized for subsequent differential coverage binning, I aimed at sequencing a larger number and greater diversity of symbionts. The results of this project are currently in review by The ISME Journal. The complementation of Illumina short-read with PacBio long-read sequencing data for binning of this highly complex metagenome greatly improved the overall assembly statistics and improved the quality of the binned genomes. Thirty-seven genomes from 13 bacterial phyla and candidate phyla were binned representing the most prominent members of the microbiome of A. aerophoba. A statistical comparison revealed an enrichment of genes involved in restriction modification and toxin-antitoxin systems in most symbiont genomes over selected reference genomes. Both are defense features against incoming foreign DNA, which may be important for sponge symbionts due to the sponge’s filtration and phagocytosis activity that exposes the symbionts to high levels of free DNA. Also host colonization and matrix utilization features were significantly enriched. Due to the diversity of the binned symbiont genomes, a within-symbionts genome comparison was possible, that revealed three guilds of symbionts characterized by i) nutritional specialization on the metabolization of carnitine, ii) specialization on sulfated polysaccharides, and iii) apparent nutritional generalism. Both carnitine and sulfated polysaccharides are abundant in the sponge extracellular matrix and therefore available to the sponge symbionts as substrates. In summary, the genomes of the diverse community of symbionts in A. aerophoba were united in their defense features, but specialized regarding their nutritional preferences.

Published
2017

46. Metagenomic binning of a marine sponge microbiome reveals unity in defense but metabolic specialization

Author

Slaby, Beate M., Hackl, Thomas, Horn, Hannes, Bayer, Kristina, Hentschel, Ute, Slaby, Beate M., Hackl, Thomas, Horn, Hannes, Bayer, Kristina, and Hentschel, Ute

Abstract

Marine sponges are ancient metazoans that are populated by distinct and highly diverse microbial communities. In order to obtain deeper insights into the functional gene repertoire of the Mediterranean sponge Aplysina aerophoba, we combined Illumina short-read and PacBio long-read sequencing followed by un-targeted metagenomic binning. We identified a total of 37 high-quality bins representing 11 bacterial phyla and two candidate phyla. Statistical comparison of symbiont genomes with selected reference genomes revealed a significant enrichment of genes related to bacterial defense (restriction-modification systems, toxin-antitoxin systems) as well as genes involved in host colonization and extracellular matrix utilization in sponge symbionts. A within-symbionts genome comparison revealed a nutritional specialization of at least two symbiont guilds, where one appears to metabolize carnitine and the other sulfated polysaccharides, both of which are abundant molecules in the sponge extracellular matrix. A third guild of symbionts may be viewed as nutritional generalists that perform largely the same metabolic pathways but lack such extraordinary numbers of the relevant genes. This study characterizes the genomic repertoire of sponge symbionts at an unprecedented resolution and it provides greater insights into the molecular mechanisms underlying microbial-sponge symbiosis.

Published
2017
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50. An Enrichment of CRISPR and Other Defense-Related Features in Marine Sponge-Associated Microbial Metagenomes

Author

Horn, Hannes, Slaby, Beate M., Jahn, Martin T., Bayer, Kristina, Moitinho-Silva, Lucas, Förster, Frank, Abdelmohsen, Usama R., Hentschel, Ute, Horn, Hannes, Slaby, Beate M., Jahn, Martin T., Bayer, Kristina, Moitinho-Silva, Lucas, Förster, Frank, Abdelmohsen, Usama R., and Hentschel, Ute

Abstract

Many marine sponges are populated by dense and taxonomically diverse microbial consortia. We employed a metagenomics approach to unravel the differences in the functional gene repertoire among three Mediterranean sponge species, Petrosia ficiformis, Sarcotragus foetidus, Aplysina aerophoba and seawater. Different signatures were observed between sponge and seawater metagenomes with regard to microbial community composition, GC content, and estimated bacterial genome size. Our analysis showed further a pronounced repertoire for defense systems in sponge metagenomes. Specifically, clustered regularly interspaced short palindromic repeats, restriction modification, DNA phosphorothioation and phage growth limitation systems were enriched in sponge metagenomes. These data suggest that defense is an important functional trait for an existence within sponges that requires mechanisms to defend against foreign DNA from microorganisms and viruses. This study contributes to an understanding of the evolutionary arms race between viruses/phages and bacterial genomes and it sheds light on the bacterial defenses that have evolved in the context of the sponge holobiont.

Published
2016
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