Your search keyword '"Stephanie Markert"' showing total 65 results

1. Differential regulation of degradation and immune pathways underlies adaptation of the ectosymbiotic nematode Laxus oneistus to oxic-anoxic interfaces

Author

Gabriela F. Paredes, Tobias Viehboeck, Stephanie Markert, Michaela A. Mausz, Yui Sato, Manuel Liebeke, Lena König, and Silvia Bulgheresi

Subjects

Medicine, Science

Abstract

Abstract Eukaryotes may experience oxygen deprivation under both physiological and pathological conditions. Because oxygen shortage leads to a reduction in cellular energy production, all eukaryotes studied so far conserve energy by suppressing their metabolism. However, the molecular physiology of animals that naturally and repeatedly experience anoxia is underexplored. One such animal is the marine nematode Laxus oneistus. It thrives, invariably coated by its sulfur-oxidizing symbiont Candidatus Thiosymbion oneisti, in anoxic sulfidic or hypoxic sand. Here, transcriptomics and proteomics showed that, whether in anoxia or not, L. oneistus mostly expressed genes involved in ubiquitination, energy generation, oxidative stress response, immune response, development, and translation. Importantly, ubiquitination genes were also highly expressed when the nematode was subjected to anoxic sulfidic conditions, together with genes involved in autophagy, detoxification and ribosome biogenesis. We hypothesize that these degradation pathways were induced to recycle damaged cellular components (mitochondria) and misfolded proteins into nutrients. Remarkably, when L. oneistus was subjected to anoxic sulfidic conditions, lectin and mucin genes were also upregulated, potentially to promote the attachment of its thiotrophic symbiont. Furthermore, the nematode appeared to survive oxygen deprivation by using an alternative electron carrier (rhodoquinone) and acceptor (fumarate), to rewire the electron transfer chain. On the other hand, under hypoxia, genes involved in costly processes (e.g., amino acid biosynthesis, development, feeding, mating) were upregulated, together with the worm’s Toll-like innate immunity pathway and several immune effectors (e.g., bactericidal/permeability-increasing proteins, fungicides). In conclusion, we hypothesize that, in anoxic sulfidic sand, L. oneistus upregulates degradation processes, rewires the oxidative phosphorylation and reinforces its coat of bacterial sulfur-oxidizers. In upper sand layers, instead, it appears to produce broad-range antimicrobials and to exploit oxygen for biosynthesis and development.

Published

2022

2. Intrinsic Mechanisms Underlying Hypoxia-Tolerant Mitochondrial Phenotype During Hypoxia-Reoxygenation Stress in a Marine Facultative Anaerobe, the Blue Mussel Mytilus edulis

Author

Eugene P. Sokolov, Linda Adzigbli, Stephanie Markert, Amanda Bundgaard, Angela Fago, Dörte Becher, Claudia Hirschfeld, and Inna M. Sokolova

Subjects

bioenergetics, mitochondria, respiration, oxidative stress, proteomics, posttranslational modification (PTM), Science, General. Including nature conservation, geographical distribution, QH1-199.5

Abstract

Hypoxia is common in marine environments and a major stressor for marine organisms inhabiting benthic and intertidal zones. Several studies have explored the responses of these organisms to hypoxic stress at the whole organism level with a focus on energy metabolism and mitochondrial response, but the instrinsic mitochondrial responses that support the organelle’s function under hypoxia and reoxygenation (H/R) stress are not well understood. We studied the effects of acute H/R stress (10 min anoxia followed by 15 min reoxygenation) on mitochondrial respiration, production of reactive oxygen species (ROS) and posttranslational modifications (PTM) of the proteome in a marine facultative anaerobe, the blue mussel Mytilus edulis. The mussels’ mitochondria showed increased OXPHOS respiration and suppressed proton leak resulting in a higher coupling efficiency after H/R stress. ROS production decreased in both the resting (LEAK) and phosphorylating (OXPHOS) state indicating that M. edulis was able to prevent oxidative stress and mitochondrial damage during reoxygenation. Hypoxia did not lead to rearrangement of the mitochondrial supercomplexes but impacted the mitochondrial phosphoproteome including the proteins involved in OXPHOS, amino acid- and fatty acid catabolism, and protein quality control. This study indicates that mussels’ mitochondria possess intrinsic mechanisms (including regulation via reversible protein phosphorylation) that ensure high respiratory flux and mitigate oxidative damage during H/R stress and contribute to the hypoxia-tolerant mitochondrial phenotype of this metabolically plastic species.

Published

2021

3. Anaerobic Sulfur Oxidation Underlies Adaptation of a Chemosynthetic Symbiont to Oxic-Anoxic Interfaces

Author

Gabriela F. Paredes, Tobias Viehboeck, Raymond Lee, Marton Palatinszky, Michaela A. Mausz, Siegfried Reipert, Arno Schintlmeister, Andreas Maier, Jean-Marie Volland, Claudia Hirschfeld, Michael Wagner, David Berry, Stephanie Markert, Silvia Bulgheresi, and Lena König

Subjects

Microbiology, QR1-502

Abstract

Chemoautotrophic endosymbionts are famous for exploiting sulfur oxidization to feed marine organisms with fixed carbon. However, the physiology of thiotrophic bacteria thriving on the surface of animals (ectosymbionts) is less understood.

Published

2021

4. Bacterial symbiont subpopulations have different roles in a deep-sea symbiosis

Author

Tjorven Hinzke, Manuel Kleiner, Mareike Meister, Rabea Schlüter, Christian Hentschker, Jan Pané-Farré, Petra Hildebrandt, Horst Felbeck, Stefan M Sievert, Florian Bonn, Uwe Völker, Dörte Becher, Thomas Schweder, and Stephanie Markert

Subjects

symbiosis, cell differentiation, host-microbe interaction, Riftia pachyptila, sulfur-oxidizing symbiont, cell heterogeneity, Medicine, Science, Biology (General), QH301-705.5

Abstract

The hydrothermal vent tubeworm Riftia pachyptila hosts a single 16S rRNA phylotype of intracellular sulfur-oxidizing symbionts, which vary considerably in cell morphology and exhibit a remarkable degree of physiological diversity and redundancy, even in the same host. To elucidate whether multiple metabolic routes are employed in the same cells or rather in distinct symbiont subpopulations, we enriched symbionts according to cell size by density gradient centrifugation. Metaproteomic analysis, microscopy, and flow cytometry strongly suggest that Riftia symbiont cells of different sizes represent metabolically dissimilar stages of a physiological differentiation process: While small symbionts actively divide and may establish cellular symbiont-host interaction, large symbionts apparently do not divide, but still replicate DNA, leading to DNA endoreduplication. Moreover, in large symbionts, carbon fixation and biomass production seem to be metabolic priorities. We propose that this division of labor between smaller and larger symbionts benefits the productivity of the symbiosis as a whole.

Published

2021

5. Genome sequence of the sulfur-oxidizing Bathymodiolus thermophilus gill endosymbiont

Author

Ruby Ponnudurai, Lizbeth Sayavedra, Manuel Kleiner, Stefan E. Heiden, Andrea Thürmer, Horst Felbeck, Rabea Schlüter, Stefan M. Sievert, Rolf Daniel, Thomas Schweder, and Stephanie Markert

Subjects

Uncultured endosymbiont, Hydrothermal vents, Marine invertebrate symbiosis, Thiotrophy, Autotrophy, Genetics, QH426-470

Abstract

Abstract Bathymodiolus thermophilus, a mytilid mussel inhabiting the deep-sea hydrothermal vents of the East Pacific Rise, lives in symbiosis with chemosynthetic Gammaproteobacteria within its gills. The intracellular symbiont population synthesizes nutrients for the bivalve host using the reduced sulfur compounds emanating from the vents as energy source. As the symbiont is uncultured, comprehensive and detailed insights into its metabolism and its interactions with the host can only be obtained from culture-independent approaches such as genomics and proteomics. In this study, we report the first draft genome sequence of the sulfur-oxidizing symbiont of B. thermophilus, here tentatively named Candidatus Thioglobus thermophilus. The draft genome (3.1 Mb) harbors 3045 protein-coding genes. It revealed pathways for the use of sulfide and thiosulfate as energy sources and encodes the Calvin-Benson-Bassham cycle for CO2 fixation. Enzymes required for the synthesis of the tricarboxylic acid cycle intermediates oxaloacetate and succinate were absent, suggesting that these intermediates may be substituted by metabolites from external sources. We also detected a repertoire of genes associated with cell surface adhesion, bacteriotoxicity and phage immunity, which may perform symbiosis-specific roles in the B. thermophilus symbiosis.

Published

2017

6. Host-Microbe Interactions in the Chemosynthetic Riftia pachyptila Symbiosis

Author

Tjorven Hinzke, Manuel Kleiner, Corinna Breusing, Horst Felbeck, Robert Häsler, Stefan M. Sievert, Rabea Schlüter, Philip Rosenstiel, Thorsten B. H. Reusch, Thomas Schweder, and Stephanie Markert

Subjects

host-microbe interactions, symbiosis, holobiont, chemosynthesis, hydrothermal vents, metaproteomics, Microbiology, QR1-502

Abstract

ABSTRACT The deep-sea tubeworm Riftia pachyptila lacks a digestive system but completely relies on bacterial endosymbionts for nutrition. Although the symbiont has been studied in detail on the molecular level, such analyses were unavailable for the animal host, because sequence information was lacking. To identify host-symbiont interaction mechanisms, we therefore sequenced the Riftia transcriptome, which served as a basis for comparative metaproteomic analyses of symbiont-containing versus symbiont-free tissues, both under energy-rich and energy-limited conditions. Our results suggest that metabolic interactions include nutrient allocation from symbiont to host by symbiont digestion and substrate transfer to the symbiont by abundant host proteins. We furthermore propose that Riftia maintains its symbiont by protecting the bacteria from oxidative damage while also exerting symbiont population control. Eukaryote-like symbiont proteins might facilitate intracellular symbiont persistence. Energy limitation apparently leads to reduced symbiont biomass and increased symbiont digestion. Our study provides unprecedented insights into host-microbe interactions that shape this highly efficient symbiosis. IMPORTANCE All animals are associated with microorganisms; hence, host-microbe interactions are of fundamental importance for life on earth. However, we know little about the molecular basis of these interactions. Therefore, we studied the deep-sea Riftia pachyptila symbiosis, a model association in which the tubeworm host is associated with only one phylotype of endosymbiotic bacteria and completely depends on this sulfur-oxidizing symbiont for nutrition. Using a metaproteomics approach, we identified both metabolic interaction processes, such as substrate transfer between the two partners, and interactions that serve to maintain the symbiotic balance, e.g., host efforts to control the symbiont population or symbiont strategies to modulate these host efforts. We suggest that these interactions are essential principles of mutualistic animal-microbe associations.

Published

2019

7. Metaproteogenomic Profiling of Microbial Communities Colonizing Actively Venting Hydrothermal Chimneys

Author

Petra Pjevac, Dimitri V. Meier, Stephanie Markert, Christian Hentschker, Thomas Schweder, Dörte Becher, Harald R. Gruber-Vodicka, Michael Richter, Wolfgang Bach, Rudolf Amann, and Anke Meyerdierks

Subjects

hydrothermal vent, metagenome, metaproteome, sulfur cycling, Epsilonproteobacteria, Microbiology, QR1-502

Abstract

At hydrothermal vent sites, chimneys consisting of sulfides, sulfates, and oxides are formed upon contact of reduced hydrothermal fluids with oxygenated seawater. The walls and surfaces of these chimneys are an important habitat for vent-associated microorganisms. We used community proteogenomics to investigate and compare the composition, metabolic potential and relative in situ protein abundance of microbial communities colonizing two actively venting hydrothermal chimneys from the Manus Basin back-arc spreading center (Papua New Guinea). We identified overlaps in the in situ functional profiles of both chimneys, despite differences in microbial community composition and venting regime. Carbon fixation on both chimneys seems to have been primarily mediated through the reverse tricarboxylic acid cycle and fueled by sulfur-oxidation, while the abundant metabolic potential for hydrogen oxidation and carbon fixation via the Calvin–Benson–Bassham cycle was hardly utilized. Notably, the highly diverse microbial community colonizing the analyzed black smoker chimney had a highly redundant metabolic potential. In contrast, the considerably less diverse community colonizing the diffusely venting chimney displayed a higher metabolic versatility. An increased diversity on the phylogenetic level is thus not directly linked to an increased metabolic diversity in microbial communities that colonize hydrothermal chimneys.

Published

2018

8. Insight into the evolution of microbial metabolism from the deep-branching bacterium, Thermovibrio ammonificans

Author

Donato Giovannelli, Stefan M Sievert, Michael Hügler, Stephanie Markert, Dörte Becher, Thomas Schweder, and Costantino Vetriani

Subjects

deep-sea vents, metabolism, evolution, thermophiles, Thermovibrio ammonificans, chemolithoautotrophy, Medicine, Science, Biology (General), QH301-705.5

Abstract

Anaerobic thermophiles inhabit relic environments that resemble the early Earth. However, the lineage of these modern organisms co-evolved with our planet. Hence, these organisms carry both ancestral and acquired genes and serve as models to reconstruct early metabolism. Based on comparative genomic and proteomic analyses, we identified two distinct groups of genes in Thermovibrio ammonificans: the first codes for enzymes that do not require oxygen and use substrates of geothermal origin; the second appears to be a more recent acquisition, and may reflect adaptations to cope with the rise of oxygen on Earth. We propose that the ancestor of the Aquificae was originally a hydrogen oxidizing, sulfur reducing bacterium that used a hybrid pathway for CO2 fixation. With the gradual rise of oxygen in the atmosphere, more efficient terminal electron acceptors became available and this lineage acquired genes that increased its metabolic flexibility while retaining ancestral metabolic traits.

Published

2017

9. Anaerobic Degradation of Bicyclic Monoterpenes in Castellaniella defragrans

Author

Edinson Puentes-Cala, Manuel Liebeke, Stephanie Markert, and Jens Harder

Subjects

monoterpene, anaerobic metabolism, ring-opening reactions, carbon–carbon lyase, isoprenoid degradation, Microbiology, QR1-502

Abstract

The microbial degradation pathways of bicyclic monoterpenes contain unknown enzymes for carbon–carbon cleavages. Such enzymes may also be present in the betaproteobacterium Castellaniella defragrans, a model organism to study the anaerobic monoterpene degradation. In this study, a deletion mutant strain missing the first enzyme of the monocyclic monoterpene pathway transformed cometabolically the bicyclics sabinene, 3-carene and α-pinene into several monocyclic monoterpenes and traces of cyclic monoterpene alcohols. Proteomes of cells grown on bicyclic monoterpenes resembled the proteomes of cells grown on monocyclic monoterpenes. Many transposon mutants unable to grow on bicyclic monoterpenes contained inactivated genes of the monocyclic monoterpene pathway. These observations suggest that the monocyclic degradation pathway is used to metabolize bicyclic monoterpenes. The initial step in the degradation is a decyclization (ring-opening) reaction yielding monocyclic monoterpenes, which can be considered as a reverse reaction of the olefin cyclization of polyenes.

Published

2018

10. Abundant toxin-related genes in the genomes of beneficial symbionts from deep-sea hydrothermal vent mussels

Author

Lizbeth Sayavedra, Manuel Kleiner, Ruby Ponnudurai, Silke Wetzel, Eric Pelletier, Valerie Barbe, Nori Satoh, Eiichi Shoguchi, Dennis Fink, Corinna Breusing, Thorsten BH Reusch, Philip Rosenstiel, Markus B Schilhabel, Dörte Becher, Thomas Schweder, Stephanie Markert, Nicole Dubilier, and Jillian M Petersen

Subjects

symbiosis, sulfur oxidizer, toxins, Bathymodiolus, Medicine, Science, Biology (General), QH301-705.5

Abstract

Bathymodiolus mussels live in symbiosis with intracellular sulfur-oxidizing (SOX) bacteria that provide them with nutrition. We sequenced the SOX symbiont genomes from two Bathymodiolus species. Comparison of these symbiont genomes with those of their closest relatives revealed that the symbionts have undergone genome rearrangements, and up to 35% of their genes may have been acquired by horizontal gene transfer. Many of the genes specific to the symbionts were homologs of virulence genes. We discovered an abundant and diverse array of genes similar to insecticidal toxins of nematode and aphid symbionts, and toxins of pathogens such as Yersinia and Vibrio. Transcriptomics and proteomics revealed that the SOX symbionts express the toxin-related genes (TRGs) in their hosts. We hypothesize that the symbionts use these TRGs in beneficial interactions with their host, including protection against parasites. This would explain why a mutualistic symbiont would contain such a remarkable ‘arsenal’ of TRGs.

Published

2015

11. The genome of the obligate intracellular parasite Trachipleistophora hominis: new insights into microsporidian genome dynamics and reductive evolution.

Author

Eva Heinz, Tom A Williams, Sirintra Nakjang, Christophe J Noël, Daniel C Swan, Alina V Goldberg, Simon R Harris, Thomas Weinmaier, Stephanie Markert, Dörte Becher, Jörg Bernhardt, Tal Dagan, Christian Hacker, John M Lucocq, Thomas Schweder, Thomas Rattei, Neil Hall, Robert P Hirt, and T Martin Embley

Subjects

Immunologic diseases. Allergy, RC581-607, Biology (General), QH301-705.5

Abstract

The dynamics of reductive genome evolution for eukaryotes living inside other eukaryotic cells are poorly understood compared to well-studied model systems involving obligate intracellular bacteria. Here we present 8.5 Mb of sequence from the genome of the microsporidian Trachipleistophora hominis, isolated from an HIV/AIDS patient, which is an outgroup to the smaller compacted-genome species that primarily inform ideas of evolutionary mode for these enormously successful obligate intracellular parasites. Our data provide detailed information on the gene content, genome architecture and intergenic regions of a larger microsporidian genome, while comparative analyses allowed us to infer genomic features and metabolism of the common ancestor of the species investigated. Gene length reduction and massive loss of metabolic capacity in the common ancestor was accompanied by the evolution of novel microsporidian-specific protein families, whose conservation among microsporidians, against a background of reductive evolution, suggests they may have important functions in their parasitic lifestyle. The ancestor had already lost many metabolic pathways but retained glycolysis and the pentose phosphate pathway to provide cytosolic ATP and reduced coenzymes, and it had a minimal mitochondrion (mitosome) making Fe-S clusters but not ATP. It possessed bacterial-like nucleotide transport proteins as a key innovation for stealing host-generated ATP, the machinery for RNAi, key elements of the early secretory pathway, canonical eukaryotic as well as microsporidian-specific regulatory elements, a diversity of repetitive and transposable elements, and relatively low average gene density. Microsporidian genome evolution thus appears to have proceeded in at least two major steps: an ancestral remodelling of the proteome upon transition to intracellular parasitism that involved reduction but also selective expansion, followed by a secondary compaction of genome architecture in some, but not all, lineages.

Published

2012

12. Mikrobieller Plastikabbau im Meer: die Suche nach dem Unwahrscheinlichen

Author

Matthias Labrenz, Stephanie Markert, and Sonja Oberbeckmann

Subjects

0303 health sciences, 03 medical and health sciences, Microplastics, 030306 microbiology, Chemistry, Environmental chemistry, Pharmacology toxicology, Biodegradation, Molecular Biology, 030304 developmental biology, Biotechnology, Bioavailability

Abstract

Microplastic particles have been found in all the world’s oceans. Since their surfaces are microbially colonised, research is currently determining whether microbes are able to degrade the synthetic polymers. We show that their contribution to the biodegradation of plastics seems to be extremely limited. Also, it is unlikely that microbes specialise in plastic degradation through evolutionary adaptation. This is not only due to the great diversity and simultaneous very low bioavailability of microplastics in the oceans, but also because it is energetically disadvantageous.

Published

2021

13. Methanosaeta and ' Candidatus Velamenicoccus archaeovorus'

Author

Jana Kizina, Sebastian F. A. Jordan, Gerrit Alexander Martens, Almud Lonsing, Christina Probian, Androniki Kolovou, Rachel Santarella-Mellwig, Erhard Rhiel, Sten Littmann, Stephanie Markert, Kurt Stüber, Michael Richter, Thomas Schweder, and Jens Harder

Subjects

Ecology, Environmental Microbiology, Applied Microbiology and Biotechnology, Food Science, Biotechnology

Abstract

The phylum “Candidatus Omnitrophica” (candidate division OP3) is ubiquitous in anaerobic habitats but is currently characterized only by draft genomes from metagenomes and single cells. We had visualized cells of the phylotype OP3 LiM in methanogenic cultures on limonene as small epibiotic cells. In this study, we enriched OP3 cells by double density gradient centrifugation and obtained the first closed genome of an apparently clonal OP3 cell population by applying metagenomics and PCR for gap closure. Filaments of acetoclastic Methanosaeta, the largest morphotype in the culture community, contained empty cells, cells devoid of rRNA or of both rRNA and DNA, and dead cells according to transmission electron microscopy (TEM), thin-section TEM, scanning electron microscopy (SEM), catalyzed reporter deposition-fluorescence in situ hybridization (CARD-FISH), and LIVE/DEAD imaging. OP3 LiM cells were ultramicrobacteria (200 to 300 nm in diameter) and showed two physiological stages in CARD-FISH fluorescence signals: strong signals of OP3 LiM cells attached to Bacteria and to Archaea indicated many rRNA molecules and an active metabolism, whereas free-living OP3 cells had weak signals. Metaproteomics revealed that OP3 LiM lives with highly expressed secreted proteins involved in depolymerization and uptake of macromolecules and an active glycolysis and energy conservation by the utilization of pyruvate via a pyruvate:ferredoxin oxidoreductase and an Rnf complex (ferredoxin:NAD oxidoreductase). Besides sugar fermentation, a nucleotidyl transferase may contribute to energy conservation by phosphorolysis, the phosphate-dependent depolymerization of nucleic acids. Thin-section TEM showed distinctive structures of predation. Our study demonstrated a predatory metabolism for OP3 LiM cells, and therefore, we propose the name “Candidatus Velamenicoccus archaeovorus” gen. nov., sp. nov., for OP3 LiM. IMPORTANCE Epibiotic bacteria are known to live on and off bacterial cells. Here, we describe the ultramicrobacterial anaerobic epibiont OP3 LiM living on Archaea and Bacteria. We detected sick and dead cells of the filamentous archaeon Methanosaeta in slowly growing methanogenic cultures. OP3 LiM lives as a sugar fermenter, likely on polysaccharides from outer membranes, and has the genomic potential to live as a syntroph. The predatory lifestyle of OP3 LiM was supported by its genome, the first closed genome for the phylum “Candidatus Omnitrophica,” and by images of cell-to-cell contact with prey cells. We propose naming OP3 LiM “Candidatus Velamenicoccus archaeovorus.” Its metabolic versatility explains the ubiquitous presence of “Candidatus Omnitrophica” 3 in anoxic habitats and gives ultramicrobacterial epibionts an important role in the recycling and remineralization of microbial biomass. The removal of polysaccharides from outer membranes by ultramicrobacteria may also influence biological interactions between pro- and eukaryotes.

Published

2022

14. Verrucomicrobia use hundreds of enzymes to digest the algal polysaccharide fucoidan

Author

Manuel Liebeke, Frank Unfried, Stephanie Markert, Doerte Becher, Andreas Sichert, Matthew S. Schechter, Thomas Schweder, Christopher H. Corzett, Antonio Fernandez-Guerra, Jan-Hendrik Hehemann, and Martin F. Polz

Subjects

Microbiology (medical), chemistry.chemical_classification, 0303 health sciences, biology, 030306 microbiology, Chemistry, Fucoidan, Microorganism, Immunology, Verrucomicrobia, Cell Biology, biology.organism_classification, Polysaccharide, Applied Microbiology and Biotechnology, Microbiology, Fucose, Cell wall, Brown algae, 03 medical and health sciences, chemistry.chemical_compound, Biochemistry, Genetics, Glycoside hydrolase, 030304 developmental biology

Abstract

Brown algae are important players in the global carbon cycle by fixing carbon dioxide into 1 Gt of biomass annually, yet the fate of fucoidan—their major cell wall polysaccharide—remains poorly understood. Microbial degradation of fucoidans is slower than that of other polysaccharides, suggesting that fucoidans are more recalcitrant and may sequester carbon in the ocean. This may be due to the complex, branched and highly sulfated structure of fucoidans, which also varies among species of brown algae. Here, we show that ‘Lentimonas’ sp. CC4, belonging to the Verrucomicrobia, acquired a remarkably complex machinery for the degradation of six different fucoidans. The strain accumulated 284 putative fucoidanases, including glycoside hydrolases, sulfatases and carbohydrate esterases, which are primarily located on a 0.89-megabase pair plasmid. Proteomics reveals that these enzymes assemble into substrate-specific pathways requiring about 100 enzymes per fucoidan from different species of brown algae. These enzymes depolymerize fucoidan into fucose, which is metabolized in a proteome-costly bacterial microcompartment that spatially constrains the metabolism of the toxic intermediate lactaldehyde. Marine metagenomes and microbial genomes show that Verrucomicrobia including ‘Lentimonas’ are abundant and highly specialized degraders of fucoidans and other complex polysaccharides. Overall, the complexity of the pathways underscores why fucoidans are probably recalcitrant and more slowly degraded, since only highly specialized organisms can effectively degrade them in the ocean. ‘Lentimonas’—a marine microorganism from the Verrucomicrobia phylum—has >200 different glycoside hydrolase and sulfatase enzymes enabling digestion of the algal polysaccharide fucoidan, which was thought to be a recalcitrant source of carbon in our oceans.

Published

2020

15. Diverse events have transferred genes for edible seaweed digestion from marine to human gut bacteria

Author

Nicholas A. Pudlo, Gabriel Vasconcelos Pereira, Jaagni Parnami, Melissa Cid, Stephanie Markert, Jeffrey P. Tingley, Frank Unfried, Ahmed Ali, Neha J. Varghese, Kwi S. Kim, Austin Campbell, Karthik Urs, Yao Xiao, Ryan Adams, Duña Martin, David N. Bolam, Dörte Becher, Emiley A. Eloe-Fadrosh, Thomas M. Schmidt, D. Wade Abbott, Thomas Schweder, Jan Hendrik Hehemann, and Eric C. Martens

Subjects

human gut microbiome, Bacteria, Immunology, Seaweed, lateral gene transfer, Microbiology, Article, Gastrointestinal Microbiome, Polysaccharides, Medical Microbiology, Virology, Humans, Bacteroides, Parasitology, Digestion, polysaccharide metabolism, Life Below Water, Nutrition

Abstract

Humans harbor numerous species of colonic bacteria that digest fiber polysaccharides in commonly consumed terrestrial plants. More recently in history, regional populations have consumed edible macroalgae seaweeds containing unique polysaccharides. It remains unclear how extensively gut bacteria have adapted to digest these nutrients. Here, we show that the ability of gut bacteria to digest seaweed polysaccharides is more pervasive than previously appreciated. Enrichment-cultured Bacteroides harbor previously discovered genes for seaweed degradation, which have mobilized into several members of this genus. Additionally, other examples of marine bacteria-derived genes, and their mobile DNA elements, are involved in gut microbial degradation of seaweed polysaccharides, including genes in gut-resident Firmicutes. Collectively, these results uncover multiple separate events that have mobilized the genes encoding seaweed degrading-enzymes into gut bacteria. This work further underscores the metabolic plasticity of the human gut microbiome and global exchange of genes in the context of dietary selective pressures.

Published

2022

16. Three Microbial Musketeers of the Seas: Shewanella baltica, Aliivibrio fischeri and Vibrio harveyi, and Their Adaptation to Different Salinity Probed by a Proteomic Approach

Author

Anna Kloska, Grzegorz M. Cech, Dariusz Nowicki, Monika Maciąg-Dorszyńska, Aleksandra E. Bogucka, Stephanie Markert, Dörte Becher, Katarzyna Potrykus, Paulina Czaplewska, and Agnieszka Szalewska-Pałasz

Subjects

Proteomics, Osmosis, Salinity, Shewanella, Proteome, Transcription, Genetic, QH301-705.5, Oceans and Seas, Shewanella baltica, Catalysis, Article, Inorganic Chemistry, osmotic stress, proteomic analysis, marine bacteria, Vibrio harveyi, Aliivibrio fischeri, Bacterial Proteins, Osmotic Pressure, Nucleic Acids, Physical and Theoretical Chemistry, Biology (General), Molecular Biology, QD1-999, Spectroscopy, Vibrio, Organic Chemistry, Osmolar Concentration, General Medicine, Gene Expression Regulation, Bacterial, Adaptation, Physiological, Computer Science Applications, Chemistry, Gene Ontology, Molecular Chaperones, Protein Binding

Abstract

Osmotic changes are common challenges for marine microorganisms. Bacteria have developed numerous ways of dealing with this stress, including reprogramming of global cellular processes. However, specific molecular adaptation mechanisms to osmotic stress have mainly been investigated in terrestrial model bacteria. In this work, we aimed to elucidate the basis of adjustment to prolonged salinity challenges at the proteome level in marine bacteria. The objects of our studies were three representatives of bacteria inhabiting various marine environments, Shewanella baltica, Vibrio harveyi and Aliivibrio fischeri. The proteomic studies were performed with bacteria cultivated in increased and decreased salinity, followed by proteolytic digestion of samples which were then subjected to liquid chromatography with tandem mass spectrometry analysis. We show that bacteria adjust at all levels of their biological processes, from DNA topology through gene expression regulation and proteasome assembly, to transport and cellular metabolism. The finding that many similar adaptation strategies were observed for both low- and high-salinity conditions is particularly striking. The results show that adaptation to salinity challenge involves the accumulation of DNA-binding proteins and increased polyamine uptake. We hypothesize that their function is to coat and protect the nucleoid to counteract adverse changes in DNA topology due to ionic shifts.

Published

2022

17. Differential Regulation of Degradation and Immune Pathways Underlies Adaptation of the Ectosymbiotic Nematode Laxus Oneistus to Oxic-Anoxic Interfaces

Author

Silvia Bulgheresi, Lena König, Yui Sato, Gabriela F. Paredes, Michaela A. Mausz, Stephanie Markert, Manuel Liebeke, and Tobias Viehboeck

Subjects

Chromadorea, Multidisciplinary, Innate immune system, Nematoda, Bacteria, Chemistry, Autophagy, Ribosome biogenesis, Translation (biology), Antimicrobial responses, Metabolism, Oxidative phosphorylation, Sulfides, Mitochondrion, Chromatiaceae, Anoxic waters, Cell biology, Oxygen, QH301, Sand, Animals, Hypoxia, Sulfur

Abstract

Eukaryotes may experience oxygen deprivation under both physiological and pathological conditions. Because oxygen shortage leads to a reduction in cellular energy production, all eukaryotes studied so far conserve energy by suppressing their metabolism. However, the molecular physiology of animals that naturally and repeatedly experience anoxia is underexplored. One such animal is the marine nematode Laxus oneistus. It thrives, invariably coated by its sulfur-oxidizing symbiont Candidatus Thiosymbion oneisti, in anoxic sulfidic or hypoxic sand. Here, transcriptomics and proteomics showed that, whether in anoxia or not, L. oneistus mostly expressed genes involved in ubiquitination, energy generation, oxidative stress response, immune response, development, and translation. Importantly, ubiquitination genes were also highly expressed when the nematode was subjected to anoxic sulfidic conditions, together with genes involved in autophagy, detoxification and ribosome biogenesis. We hypothesize that these degradation pathways were induced to recycle damaged cellular components (mitochondria) and misfolded proteins into nutrients. Remarkably, when L. oneistus was subjected to anoxic sulfidic conditions, lectin and mucin genes were also upregulated, potentially to promote the attachment of its thiotrophic symbiont. Furthermore, the nematode appeared to survive oxygen deprivation by using an alternative electron carrier (rhodoquinone) and acceptor (fumarate), to rewire the electron transfer chain. On the other hand, under hypoxia, genes involved in costly processes (e.g., amino acid biosynthesis, development, feeding, mating) were upregulated, together with the worm’s Toll-like innate immunity pathway and several immune effectors (e.g., Bacterial Permeability Increasing proteins, fungicides). In conclusion, we hypothesize that, in anoxic sulfidic sand, L. oneistus upregulates degradation processes, rewires oxidative phosphorylation and by reinforces its coat of bacterial sulfur-oxidizers. In upper sand layers, instead, it appears to produce broad-range antimicrobials and to exploit oxygen for biosynthesis and development.

Published

2021

18. Comparative proteomics of related symbiotic mussel species reveals high variability of host–symbiont interactions

Author

Horst Felbeck, Tjorven Hinzke, Christian Hentschker, Manuel Kleiner, Rabea Schlüter, Ruby Ponnudurai, Dörte Becher, Thomas Schweder, Stefan E. Heiden, Lizbeth Sayavedra, Stefan M. Sievert, and Stephanie Markert

Subjects

Gills, Proteomics, Water microbiology, Chemoautotrophic Growth, animal structures, Methanotroph, Bathymodiolus, Microbial metabolism, Brief Communication, Bacterial physiology, Microbiology, Bacterial genetics, Microbial ecology, 03 medical and health sciences, Symbiosis, Animals, 14. Life underwater, Amino Acids, Ecology, Evolution, Behavior and Systematics, Carbonic Anhydrases, 030304 developmental biology, 0303 health sciences, Bacteria, Host Microbial Interactions, biology, 030306 microbiology, Host (biology), fungi, food and beverages, biochemical phenomena, metabolism, and nutrition, biology.organism_classification, Evolutionary biology, bacteria, Mytilidae, Genome, Bacterial

Abstract

Deep-sea Bathymodiolus mussels and their chemoautotrophic symbionts are well-studied representatives of mutualistic host–microbe associations. However, how host–symbiont interactions vary on the molecular level between related host and symbiont species remains unclear. Therefore, we compared the host and symbiont metaproteomes of Pacific B. thermophilus, hosting a thiotrophic symbiont, and Atlantic B. azoricus, containing two symbionts, a thiotroph and a methanotroph. We identified common strategies of metabolic support between hosts and symbionts, such as the oxidation of sulfide by the host, which provides a thiosulfate reservoir for the thiotrophic symbionts, and a cycling mechanism that could supply the host with symbiont-derived amino acids. However, expression levels of these processes differed substantially between both symbioses. Backed up by genomic comparisons, our results furthermore revealed an exceptionally large repertoire of attachment-related proteins in the B. thermophilus symbiont. These findings imply that host–microbe interactions can be quite variable, even between closely related systems.

Published

2019

19. Effects of hypoxia-reoxygenation stress on mitochondrial proteome and bioenergetics of the hypoxia-tolerant marine bivalve Crassostrea gigas

Author

Eugene P. Sokolov, Siriluck Ponsuksili, Stephanie Markert, Inna M. Sokolova, Dörte Becher, Claudia Hirschfeld, and Tjorven Hinzke

Subjects

0301 basic medicine, Proteome, Bioenergetics, Biophysics, Oxidative phosphorylation, Mitochondrion, Biochemistry, Mitochondrial Proteins, 03 medical and health sciences, Animals, Crassostrea, Hypoxia, chemistry.chemical_classification, Reactive oxygen species, 030102 biochemistry & molecular biology, biology, biology.organism_classification, Electron transport chain, Mitochondria, Cell biology, 030104 developmental biology, chemistry, Phosphorylation, Reactive Oxygen Species, Oxidation-Reduction

Abstract

Mitochondria are key intracellular targets of hypoxia-reoxygenation (H/R) stress due to their central role in generation of ATP and reactive oxygen species (ROS). Intertidal oysters Crassostrea gigas are adapted to frequent H/R cycles and maintain aerobic function despite frequent oxygen fluctuations. To gain insight into the molecular mechanisms of H/R tolerance, we assessed changes in mitochondrial respiration and (phospho)proteome of C. gigas during hypoxia and recovery. Oyster mitochondria maintained OXPHOS capacity despite a decline in cytochrome c oxidase activity during H/R stress. Rearrangements of the mitochondrial proteome during H/R stress involved upregulation of mitochondrial electron transport system and iron-binding proteins, and suppression of the pathways that channel electrons to ubiquinone, possibly as a mechanism to limit ROS production. H/R stress led to upregulation of a mitophagic activator PGAM5 and dephosphorylation of metalloendopeptidase OMA1, indicating stimulation of mitochondrial quality control mechanisms. Changes in abundance and phosphorylation levels of key proteins involved in mitochondrial protein homeostasis indicate suppression of protein synthesis during hypoxia, likely as an energy-saving mechanism, and its subsequent reactivation during reoxygenation. Thus, shifts in the mitochondrial (phospho-)proteome might play an important role in H/R stress resistance of oysters ensuring mitochondrial integrity and function during oxygen fluctuations. SIGNIFICANCE: Hypoxia-reoxygenation (H/R) stress elicits shifts in proteome and phosphoproteome of mitochondria in a hypoxia-tolerant model bivalve, oyster Crassostrea gigas, upregulating electron transport system, limiting electron flow to ubiquinone and activating mitochondrial quality control and protein homeostasis mechanisms. These findings provide insights into the potential role of proteomic shifts in adaptive response to H/R stress and serve as an important benchmark to understand the mechanisms of mitochondrial sensitivity to hypoxia and reoxygenation.

Published

2019

20. Microbial metal-sulfide oxidation in inactive hydrothermal vent chimneys suggested by metagenomic and metaproteomic analyses

Author

Dimitri V. Meier, Anke Meyerdierks, Rudolf Amann, Sven Petersen, Stephanie Markert, Petra Pjevac, Wolfgang Bach, John Jamieson, and Thomas Schweder

Subjects

chemistry.chemical_classification, 0303 health sciences, biology, Sulfide, 030306 microbiology, fungi, biology.organism_classification, Microbiology, Nitrospirae, 03 medical and health sciences, chemistry, 13. Climate action, Benthic zone, Environmental chemistry, Gammaproteobacteria, Chimney, 14. Life underwater, Autotroph, Energy source, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Hydrothermal vent

Abstract

Metal-sulfides are wide-spread in marine benthic habitats. At deep-sea hydrothermal vents, they occur as massive sulfide chimneys formed by mineral precipitation upon mixing of reduced vent fluids with cold oxygenated sea water. Although microorganisms inhabiting actively venting chimneys and utilizing compounds supplied by the venting fluids are well studied, only little is known about microorganisms inhabiting inactive chimneys. In this study, we combined 16S rRNA gene-based community profiling of sulfide chimneys from the Manus Basin (SW Pacific) with radiometric dating, metagenome (n = 4) and metaproteome (n = 1) analyses. Our results shed light on potential lifestyles of yet poorly characterized bacterial clades colonizing inactive chimneys. These include sulfate-reducing Nitrospirae and sulfide-oxidizing Gammaproteobacteria dominating most of the inactive chimney communities. Our phylogenetic analysis attributed the gammaproteobacterial clades to the recently described Woeseiaceae family and the SSr-clade found in marine sediments around the world. Metaproteomic data identified these Gammaproteobacteria as autotrophic sulfide-oxidizers potentially facilitating metal-sulfide dissolution via extracellular electron transfer. Considering the wide distribution of these gammaproteobacterial clades in marine environments such as hydrothermal vents and sediments, microbially accelerated neutrophilic mineral oxidation might be a globally relevant process in benthic element cycling and a considerable energy source for carbon fixation in marine benthic habitats.

Published

2019

21. Anaerobic Sulfur Oxidation Underlies Adaptation of a Chemosynthetic Symbiont to Oxic-Anoxic Interfaces

Author

Michael Wagner, Lena König, Silvia Bulgheresi, Michaela A. Mausz, Raymond W. Lee, Stephanie Markert, David Berry, Siegfried Reipert, Claudia Hirschfeld, Andreas Maier, Arno Schintlmeister, Jean-Marie Volland, Tobias Viehboeck, Márton Palatinszky, and Gabriela F. Paredes

Subjects

Denitrification, Physiology, Nitrogen assimilation, chemistry.chemical_element, Biochemistry, Oxygen, Microbiology, Sulfur oxidation, chemosynthesis, 03 medical and health sciences, Anoxia, Genetics, thiotrophic bacteria, Symbiosis, Molecular Biology, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Chemosynthesis, Thiotrophic bacteria, 0303 health sciences, 030306 microbiology, Carbon fixation, anoxia, sulfur oxidation, Thiosymbion, Vitamin biosynthesis, Sulfur, Anoxic waters, symbiosis, QR1-502, Computer Science Applications, chemistry, Modeling and Simulation, Environmental chemistry, Gammaproteobacteria, Research Article

Abstract

Chemosynthetic symbioses occur worldwide in marine habitats, but comprehensive physiological studies of chemoautotrophic bacteria thriving on animals are scarce. Stilbonematinae are coated by thiotrophic Gammaproteobacteria. As these nematodes migrate through the redox zone, their ectosymbionts experience varying oxygen concentrations. However, nothing is known about how these variations affect their physiology. Here, by applying omics, Raman microspectroscopy, and stable isotope labeling, we investigated the effect of oxygen on “Candidatus Thiosymbion oneisti.” Unexpectedly, sulfur oxidation genes were upregulated in anoxic relative to oxic conditions, but carbon fixation genes and incorporation of 13C-labeled bicarbonate were not. Instead, several genes involved in carbon fixation were upregulated under oxic conditions, together with genes involved in organic carbon assimilation, polyhydroxyalkanoate (PHA) biosynthesis, nitrogen fixation, and urea utilization. Furthermore, in the presence of oxygen, stress-related genes were upregulated together with vitamin biosynthesis genes likely necessary to withstand oxidative stress, and the symbiont appeared to proliferate less. Based on its physiological response to oxygen, we propose that “Ca. T. oneisti” may exploit anaerobic sulfur oxidation coupled to denitrification to proliferate in anoxic sand. However, the ectosymbiont would still profit from the oxygen available in superficial sand, as the energy-efficient aerobic respiration would facilitate carbon and nitrogen assimilation. IMPORTANCE Chemoautotrophic endosymbionts are famous for exploiting sulfur oxidization to feed marine organisms with fixed carbon. However, the physiology of thiotrophic bacteria thriving on the surface of animals (ectosymbionts) is less understood. One longstanding hypothesis posits that attachment to animals that migrate between reduced and oxic environments would boost sulfur oxidation, as the ectosymbionts would alternatively access sulfide and oxygen, the most favorable electron acceptor. Here, we investigated the effect of oxygen on the physiology of “Candidatus Thiosymbion oneisti,” a gammaproteobacterium which lives attached to marine nematodes inhabiting shallow-water sand. Surprisingly, sulfur oxidation genes were upregulated under anoxic relative to oxic conditions. Furthermore, under anoxia, the ectosymbiont appeared to be less stressed and to proliferate more. We propose that animal-mediated access to oxygen, rather than enhancing sulfur oxidation, would facilitate assimilation of carbon and nitrogen by the ectosymbiont.

Published

2021

22. Genomic and proteomic profiles of biofilms on microplastics are decoupled from artificial surface properties

Author

Stefan E. Heiden, Jörn Kalinowski, Johannes Werner, Matthias Labrenz, Thomas Schweder, Stephanie Markert, Claudia Hirschfeld, Daniel Wibberg, Daniel Bartosik, Sixing Huang, Dörte Becher, Boyke Bunk, Jörg Overmann, and Sonja Oberbeckmann

Subjects

Proteomics, 0303 health sciences, Microplastics, Phototroph, 030306 microbiology, Ecology, Surface Properties, Microorganism, Biofilm, Biodegradation, Biology, Microbiology, 03 medical and health sciences, Metagenomics, Biofilms, Metaproteomics, Marine ecosystem, Plastics, Ecology, Evolution, Behavior and Systematics, Ecosystem, Water Pollutants, Chemical, 030304 developmental biology

Abstract

Microplastics in marine ecosystems are colonized by diverse prokaryotic and eukaryotic communities. How these communities and their functional profiles are shaped by the artificial surfaces remains broadly unknown. In order to close this knowledge gap, we set up an in situ experiment with pellets of the polyolefin polymer polyethylene (PE), the aromatic hydrocarbon polymer polystyrene (PS), and wooden beads along a coastal to estuarine gradient in the Baltic Sea, Germany. We used an integrated metagenomics/metaproteomics approach to evaluate the genomic potential as well as protein expression levels of aquatic plastic biofilms. Our results suggest that material properties had a minor influence on the plastic-associated assemblages, as genomic and proteomic profiles of communities associated with the structurally different polymers PE and PS were highly similar, hence polymer-unspecific. Instead, it seemed that these communities were shaped by biogeographic factors. Wood, on the other hand, induced the formation of substrate-specific biofilms and served as nutrient source itself. Our study indicates that, while PE and PS microplastics may be relevant in the photic zone as opportunistic colonization grounds for phototrophic microorganisms, they appear not to be subject to biodegradation or serve as vectors for pathogenic microorganisms in marine habitats. This article is protected by copyright. All rights reserved. This article is protected by copyright. All rights reserved.

Published

2021

23. Bacterial symbiont subpopulations have different roles in a deep-sea symbiosis

Author

Mareike Meister, Horst Felbeck, Uwe Völker, Stefan M. Sievert, Rabea Schlüter, Dörte Becher, Thomas Schweder, Stephanie Markert, Petra Hildebrandt, Manuel Kleiner, Jan Pané-Farré, Florian Bonn, Tjorven Hinzke, and Christian Hentschker

Subjects

0301 basic medicine, animal structures, host-microbe interaction, QH301-705.5, cell heterogeneity, Science, Cellular differentiation, 030106 microbiology, Biology, Bacterial Physiological Phenomena, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, chemistry.chemical_compound, Hydrothermal Vents, Symbiosis, Animals, Biology (General), Phylotype, Differential centrifugation, Microbiology and Infectious Disease, Bacteria, General Immunology and Microbiology, Host (biology), General Neuroscience, fungi, food and beverages, Polychaeta, sulfur-oxidizing symbiont, General Medicine, biochemical phenomena, metabolism, and nutrition, symbiosis, cell differentiation, 030104 developmental biology, Riftia pachyptila, chemistry, DNA endoreduplication, Evolutionary biology, Medicine, bacteria, Other, Intracellular, DNA, Research Article

Abstract

The hydrothermal vent tubewormRiftia pachyptilahosts a single 16S rRNA phylotype of intracellular sulfur-oxidizing symbionts, which vary considerably in cell morphology and exhibit a remarkable degree of physiological diversity and redundancy, even in the same host. To elucidate whether multiple metabolic routes are employed in the same cells or rather in distinct symbiont subpopulations, we enriched symbionts according to cell size by density gradient centrifugation. Metaproteomic analysis, microscopy, and flow cytometry strongly suggest thatRiftiasymbiont cells of different sizes represent metabolically dissimilar stages of a physiological differentiation process: While small symbionts actively divide and may establish cellular symbiont-host interaction, large symbionts apparently do not divide, but still replicate DNA, leading to DNA endoreduplication. Moreover, in large symbionts, carbon fixation and biomass production seem to be metabolic priorities. We propose that this division of labor between smaller and larger symbionts benefits the productivity of the symbiosis as a whole.

Published

2021

24. Author response: Bacterial symbiont subpopulations have different roles in a deep-sea symbiosis

Author

Florian Bonn, Uwe Völker, Jan Pané-Farré, Rabea Schlüter, Stefan M. Sievert, Petra Hildebrandt, Mareike Meister, Dörte Becher, Horst Felbeck, Manuel Kleiner, Stephanie Markert, Tjorven Hinzke, Christian Hentschker, and Thomas Schweder

Subjects

Symbiosis, Ecology, Biology, Deep sea

Published

2020

25. Changing expression patterns of TonB-dependent transporters suggest shifts in polysaccharide consumption over the course of a spring phytoplankton bloom

Author

Thomas Schweder, Hanno Teeling, Bernhard M. Fuchs, T. Ben Francis, Jan-Hendrik Hehemann, Rudolf Amann, Daniel Bartosik, Stephanie Markert, Thomas Sura, Dörte Becher, and Andreas Sichert

Subjects

Water microbiology, Proteomics, Heterotroph, Biology, Microbiology, Algal bloom, Article, 03 medical and health sciences, Laminarin, chemistry.chemical_compound, Gammaproteobacteria, Seawater, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, 0303 health sciences, 030306 microbiology, fungi, Polysaccharides, Bacterial, Bacterial polysaccharide, Bacteroidetes, Bacterioplankton, biochemical phenomena, metabolism, and nutrition, Eutrophication, biology.organism_classification, Biochemistry, chemistry, Phytoplankton, North Sea, Molecular ecology, Bloom

Abstract

Algal blooms produce large quantities of organic matter that is subsequently remineralised by bacterial heterotrophs. Polysaccharide is a primary component of algal biomass. It has been hypothesised that individual bacterial heterotrophic niches during algal blooms are in part determined by the available polysaccharide substrates present. Measurement of the expression of TonB-dependent transporters, often specific for polysaccharide uptake, might serve as a proxy for assessing bacterial polysaccharide consumption over time. To investigate this, we present here high-resolution metaproteomic and metagenomic datasets from bacterioplankton of the 2016 spring phytoplankton bloom at Helgoland island in the southern North Sea, and expression profiles of TonB-dependent transporters during the bloom, which demonstrate the importance of both the Gammaproteobacteria and the Bacteroidetes as degraders of algal polysaccharide. TonB-dependent transporters were the most highly expressed protein class, split approximately evenly between the Gammaproteobacteria and Bacteroidetes, and totalling on average 16.7% of all detected proteins during the bloom. About 93% of these were predicted to take up organic matter, and for about 12% of the TonB-dependent transporters, we predicted a specific target polysaccharide class. Most significantly, we observed a change in substrate specificities of the expressed transporters over time, which was not reflected in the corresponding metagenomic data. From this, we conclude that algal cell wall-related compounds containing fucose, mannose, and xylose were mostly utilised in later bloom stages, whereas glucose-based algal and bacterial storage molecules including laminarin, glycogen, and starch were used throughout. Quantification of transporters could therefore be key for understanding marine carbon cycling.

Published

2020

26. Metabolic differences between symbiont subpopulations in the deep-sea tubeworm Riftia pachyptila

Author

Mareike Meister, Horst Felbeck, Florian Bonn, Stephanie Markert, Tjorven Hinzke, Manuel Kleiner, Christian Hentschker, Thomas Schweder, Stefan M. Sievert, Jan Pané-Farré, Petra Hildebrandt, Uwe Völker, Dörte Becher, and Rabea Schlüter

Subjects

0303 health sciences, education.field_of_study, animal structures, biology, Cell division, 030306 microbiology, Host (biology), fungi, Population, food and beverages, biochemical phenomena, metabolism, and nutrition, biology.organism_classification, 03 medical and health sciences, Symbiosis, Evolutionary biology, Gammaproteobacteria, biology.protein, bacteria, Energy source, education, FtsZ, Bacteria, 030304 developmental biology

Abstract

The hydrothermal vent tube worm Riftia pachyptila lives in intimate symbiosis with intracellular sulfur-oxidizing gammaproteobacteria. Although the symbiont population consists of a single 16S rRNA phylotype, bacteria in the same host animal exhibit a remarkable degree of metabolic diversity: They simultaneously utilize two carbon fixation pathways and various energy sources and electron acceptors. Whether these multiple metabolic routes are employed in the same symbiont cells, or rather in distinct symbiont subpopulations, was unclear. As Riftia symbionts vary considerably in cell size and shape, we enriched individual symbiont cell sizes by density gradient centrifugation in order to test whether symbiont cells of different sizes show different metabolic profiles. Metaproteomic analysis and statistical evaluation using clustering and random forests, supported by microscopy and flow cytometry, strongly suggest that Riftia symbiont cells of different sizes represent metabolically dissimilar stages of a physiological differentiation process: Small symbionts actively divide and may establish cellular symbiont-host interaction, as indicated by highest abundance of the cell division key protein FtsZ and highly abundant chaperones and porins in this initial phase. Large symbionts, on the other hand, apparently do not divide, but still replicate DNA, leading to DNA endoreduplication. Highest abundance of enzymes for CO2 fixation, carbon storage and biosynthesis in large symbionts indicates that in this late differentiation stage the symbiont’s metabolism is efficiently geared towards the production of organic material. We propose that this division of labor between smaller and larger symbionts benefits the productivity of the symbiosis as a whole.

Published

2020

27. Anaerobic sulfur oxidation underlies adaptation of a chemosynthetic symbiont to oxic-anoxic interfaces

Author

Tobias Viehboeck, Stephanie Markert, David Berry, Claudia Hirschfeld, Lena König, Sigfried Reipert, Michaela A. Mausz, Michael Wagner, Gabriela F. Paredes, Silvia Bulgheresi, Márton Palatinszky, Jean-Marie Volland, Arno Schintlmeister, and Raymond W. Lee

Subjects

Denitrification, biology, chemistry, Biochemistry, Nitrogen assimilation, Gammaproteobacteria, Carbon fixation, Nitrogen fixation, chemistry.chemical_element, Vitamin biosynthesis, biology.organism_classification, Anoxic waters, Sulfur

Abstract

Chemosynthetic symbioses occur worldwide in marine habitats, but comprehensive physiological studies of chemoautotrophic bacteria thriving on animals are scarce. Stilbonematinae are coated by monocultures of thiotrophic Gammaproteobacteria. As these nematodes migrate through the redox zone, their ectosymbionts experience varying oxygen concentrations. However, nothing is known about how these variations affect their physiology or metabolism. Here, by applying omics, Raman microspectroscopy and stable isotope labelling, we investigated the effect of oxygen on Candidatus Thiosymbion oneisti. Unexpectedly, sulfur oxidation genes were upregulated in anoxic relative to oxic conditions, but carbon fixation genes and incorporation of 13C-labeled bicarbonate were not. Instead, several genes involved in carbon fixation were upregulated in oxic conditions, together with genes involved in organic carbon assimilation, polyhydroxyalkanoate (PHA) biosynthesis, nitrogen fixation and urea utilization. Furthermore, in the presence of oxygen, stress-related genes were upregulated together with vitamin biosynthesis genes likely necessary to withstand its deleterious effects, and the symbiont appeared to proliferate less. Based on its physiological response to oxygen, we propose that Ca. T. oneisti may exploit anaerobic sulfur oxidation coupled to denitrification to proliferate in anoxic sand. However, the ectosymbiont would still profit from the oxygen available in superficial sand, as the energy-efficient aerobic respiration would facilitate carbon and nitrogen assimilation by the ectosymbiont.IMPORTANCEChemoautotrophic endosymbionts are famous for exploiting sulfur oxidization to feed marine organisms with fixed carbon. However, the physiology of thiotrophic bacteria thriving on the surface of animals (ectosymbionts) is less understood. One long standing hypothesis posits that attachment to animals that migrate between reduced and oxic environments would boost sulfur oxidation, as the ectosymbionts would alternatively access sulfide and oxygen, the most favorable electron acceptor. Here, we investigated the effect of oxygen on the physiology of Candidatus Thiosymbion oneisti, a Gammaproteobacterium which lives attached to marine nematodes inhabiting shallow water sand. Surprisingly, sulfur oxidation genes were upregulated in anoxic relative to oxic conditions. Furthermore, under anoxia, the ectosymbiont appeared to be less stressed and to proliferate more. We propose that animal-mediated access to oxygen, rather than enhancing sulfur oxidation, would facilitate assimilation of carbon and nitrogen by the ectosymbiont.

Published

2020

28. An optimized metaproteomics protocol for a holistic taxonomic and functional characterization of microbial communities from marine particles

Author

Stephanie Markert, Jörg Bernhardt, Daniela Zühlke, Dirk Albrecht, Claudia Hirschfeld, Doreen Schultz, Katharina Riedel, and Thomas Ben Francis

Subjects

Cyanobacteria, Proteomics, 03 medical and health sciences, Bacterial Proteins, Tandem Mass Spectrometry, Protein purification, Lysis buffer, Seawater, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, 0303 health sciences, biology, Bacteria, 030306 microbiology, Microbiota, Eutrophication, biology.organism_classification, Agricultural and Biological Sciences (miscellaneous), Biochemistry, Metagenomics, Metaproteomics, Metagenome, North Sea, Proteobacteria, Flavobacteriia, Chromatography, Liquid

Abstract

This study aimed to establish a robust and reliable metaproteomics protocol for an in-depth characterization of marine particle-associated (PA) bacteria. To this end, we compared six well-established protein extraction protocols together with different MS-sample preparation techniques using particles sampled during a North Sea spring algae bloom in 2009. In the final optimized workflow, proteins are extracted using a combination of SDS-containing lysis buffer and cell disruption by bead-beating, separated by SDS-PAGE, in-gel digested and analysed by LC-MS/MS, before MASCOT search against a metagenome-based database and data processing/visualization with the in-house-developed bioinformatics tools Prophane and Paver. As an application example, free-living (FL) and particulate communities sampled in April 2009 were analysed, resulting in an as yet unprecedented number of 9354 and 5034 identified protein groups for FL and PA bacteria, respectively. Our data suggest that FL and PA communities appeared similar in their taxonomic distribution, with notable exceptions: eukaryotic proteins and proteins assigned to Flavobacteriia, Cyanobacteria, and some proteobacterial genera were found more abundant on particles, whilst overall proteins belonging to Proteobacteria were more dominant in the FL fraction. Furthermore, our data points to functional differences including proteins involved in polysaccharide degradation, sugar- and phosphorus uptake, adhesion, motility, and stress response.

Published

2020

29. Extensive Transfer of Genes for Edible Seaweed Digestion from Marine to Human Gut Bacteria

Author

Austin Campbell, Ahmed Ali, Jaagni Parnami, Nicholas A. Pudlo, David N. Bolam, Stephanie Markert, D. Wade Abbott, Gabriel V. Pereira, Duna Martin, Melissa Cid, Eric C. Martens, Karthik Urs, Yao Xiao, Ryan Adams, Frank Unfried, Dörte Becher, Jan-Hendrik Hehemann, Thomas M. Schmidt, Thomas Schweder, and Jeffrey P Tingley

Subjects

chemistry.chemical_classification, biology, Firmicutes, Zoology, Context (language use), biology.organism_classification, Polysaccharide, Edible seaweed, chemistry, Microbiome, Bacteroides, Digestion, Gene, Bacteria

Abstract

SummaryHumans harbor numerous species of colonic bacteria that digest the fiber polysaccharides in commonly consumed terrestrial plants. More recently in history, regional populations have consumed edible macroalgae seaweeds containing unique polysaccharides. It remains unclear how extensively gut bacteria have adapted to digest these nutrients and use these abilities to colonize microbiomes around the world, especially outside Asia. Here, we show that the ability of gut bacteria to digest seaweed polysaccharides is more pervasive than previously appreciated. Using culture-based approaches, we show that known Bacteroides genes involved in seaweed degradation have mobilized into many members of this genus. We also identify several previously unknown examples of marine bacteria-derived genes, and their corresponding mobile DNA elements, that are involved in degrading seaweed polysaccharides. Some of these genes reside in gut-resident, Gram-positive Firmicutes, for which phylogenetic analysis suggests an origin in the Epulopiscium gut symbionts of marine fishes. Our results are important for understanding the metabolic plasticity of the human gut microbiome, the global exchange of genes in the context of dietary selective pressures and identifying new functions that can be introduced or engineered to design and fill orthogonal niches for a future generation of engineered probiotics.

Published

2020

30. Alpha‐ and beta‐mannan utilization by marine Bacteroidetes

Author

Lennart Kappelmann, Hanno Teeling, Tao Song, Burak Avci, Rudolf Amann, Frank Unfried, Stephanie Markert, Jing Chen, Thomas Schweder, Ping Xie, Jens Harder, Jan-Hendrik Hehemann, Dörte Becher, and Craig S. Robb

Subjects

Proteomics, 0301 basic medicine, Polysaccharide, Microbiology, Carbon Cycle, Mannans, 03 medical and health sciences, Marine bacteriophage, Bacterial Proteins, Algae, Humans, Organic matter, Ecology, Evolution, Behavior and Systematics, Mannan, chemistry.chemical_classification, biology, Bacteroidetes, Carbon fixation, biology.organism_classification, 030104 developmental biology, chemistry, Biochemistry, Carbohydrate Metabolism, North Sea, Bacteroides

Abstract

Marine microscopic algae carry out about half of the global carbon dioxide fixation into organic matter. They provide organic substrates for marine microbes such as members of the Bacteroidetes that degrade algal polysaccharides using carbohydrate-active enzymes (CAZymes). In Bacteroidetes genomes CAZyme encoding genes are mostly grouped in distinct regions termed polysaccharide utilization loci (PULs). While some studies have shown involvement of PULs in the degradation of algal polysaccharides, the specific substrates are for the most part still unknown. We investigated four marine Bacteroidetes isolated from the southern North Sea that harbour putative mannan-specific PULs. These PULs are similarly organized as PULs in human gut Bacteroides that digest α- and β-mannans from yeasts and plants respectively. Using proteomics and defined growth experiments with polysaccharides as sole carbon sources we could show that the investigated marine Bacteroidetes express the predicted functional proteins required for α- and β-mannan degradation. Our data suggest that algal mannans play an as yet unknown important role in the marine carbon cycle, and that biochemical principles established for gut or terrestrial microbes also apply to marine bacteria, even though their PULs are evolutionarily distant.

Published

2018

31. Polysaccharide utilization loci of North Sea Flavobacteriia as basis for using SusC/D-protein expression for predicting major phytoplankton glycans

Author

Hanno Teeling, Stephanie Markert, Thomas Schweder, Frank Unfried, Jens Harder, Dörte Becher, Jan-Hendrik Hehemann, Karen Krüger, Lennart Kappelmann, Nicole Shapiro, and Rudolf Amann

Subjects

Proteomics, Glycan, Mannose, Polysaccharide, Microbiology, Genome, Article, Fucose, 03 medical and health sciences, Laminarin, chemistry.chemical_compound, Bacterial Proteins, Algae, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, biology, 030306 microbiology, Polysaccharides, Bacterial, Gene Expression Regulation, Bacterial, Genomics, biology.organism_classification, Biochemistry, chemistry, Phytoplankton, biology.protein, North Sea, Flavobacteriaceae, Flavobacteriia

Abstract

Marine algae convert a substantial fraction of fixed carbon dioxide into various polysaccharides. Flavobacteriia that are specialized on algal polysaccharide degradation feature genomic clusters termed polysaccharide utilization loci (PULs). As knowledge on extant PUL diversity is sparse, we sequenced the genomes of 53 North Sea Flavobacteriia and obtained 400 PULs. Bioinformatic PUL annotations suggest usage of a large array of polysaccharides, including laminarin, α-glucans, and alginate as well as mannose-, fucose-, and xylose-rich substrates. Many of the PULs exhibit new genetic architectures and suggest substrates rarely described for marine environments. The isolates' PUL repertoires often differed considerably within genera, corroborating ecological niche-associated glycan partitioning. Polysaccharide uptake in Flavobacteriia is mediated by SusCD-like transporter complexes. Respective protein trees revealed clustering according to polysaccharide specificities predicted by PUL annotations. Using the trees, we analyzed expression of SusC/D homologs in multiyear phytoplankton bloom-associated metaproteomes and found indications for profound changes in microbial utilization of laminarin, α-glucans, β-mannan, and sulfated xylan. We hence suggest the suitability of SusC/D-like transporter protein expression within heterotrophic bacteria as a proxy for the temporal utilization of discrete polysaccharides.

Published

2018

32. Limonene dehydrogenase hydroxylates the allylic methyl group of cyclic monoterpenes in the anaerobic terpene degradation by Castellaniella defragrans

Author

Manuel Liebeke, Jens Harder, Edinson Puentes-Cala, and Stephanie Markert

Subjects

0301 basic medicine, chemistry.chemical_classification, Limonene, biology, Stereochemistry, Monoterpene, Perillyl alcohol, 030106 microbiology, Dehydrogenase, Cell Biology, Flavin group, Biochemistry, Cofactor, 03 medical and health sciences, chemistry.chemical_compound, chemistry, Oxidoreductase, biology.protein, Molecular Biology, Methyl group

Abstract

The enzymatic functionalization of hydrocarbons is a central step in the global carbon cycle initiating the mineralization of methane, isoprenes, and monoterpenes, the most abundant biologically produced hydrocarbons. Also, terpene-modifying enzymes have found many applications in the energy-economic biotechnological production of fine chemicals. Here, we describe a limonene dehydrogenase that was purified from the facultatively anaerobic betaproteobacterium Castellaniella defragrans 65Phen grown on monoterpenes under denitrifying conditions in the absence of molecular oxygen. The purified limonene:ferrocenium oxidoreductase activity hydroxylated the methyl group of limonene (1-methyl-4-(1-methylethenyl)-cyclohex-1-ene) yielding perillyl alcohol ([4-(prop-1-en-2-yl)cyclohex-1-en-1-yl]methanol). The enzyme had a DTT:perillyl alcohol oxidoreductase activity yielding limonene. Mass spectrometry and molecular size determinations revealed a heterodimeric enzyme comprising CtmA and CtmB. Recently, the two proteins had been identified by transposon mutagenesis and proteomics as part of the cyclic terpene metabolism (ctm) in C. defragrans and are annotated as FAD-dependent oxidoreductases of the protein domain family phytoene dehydrogenases and related proteins (COG1233). CtmAB is the first heterodimeric enzyme in this protein superfamily. Flavins in the purified CtmAB are oxidized by ferrocenium and are reduced by limonene. Heterologous expression of CtmA, CtmB, and CtmAB in Escherichia coli demonstrated that limonene dehydrogenase activity required both subunits, each carrying a flavin cofactor. Native CtmAB oxidized a wide range of monocyclic monoterpenes containing the allylic methyl group motif (1-methyl-cyclohex-1-ene). In conclusion, we have identified CtmAB as a hydroxylating limonene dehydrogenase and the first heteromer in a family of FAD-dependent dehydrogenases acting on allylic methylene or methyl CH-bonds. We suggest placing in Enzyme Nomenclature as new entry EC 1.17.99.8.

Published

2018

33. Exploiting fine-scale genetic and physiological variation of closely related microbes to reveal unknown enzyme functions

Author

Jan-Hendrik Hehemann, Stephanie Markert, Martin F. Polz, Frank Unfried, Thomas Schweder, Matthew J. Plutz, Christopher V. Rao, Sujit Sadashiv Jagtap, Geethika Yalamanchili, and Ahmet H. Badur

Subjects

Proteomics, 0301 basic medicine, Signal peptide, Aquatic Organisms, Glycan, Alginates, Genomics, Crystallography, X-Ray, Microbiology, Biochemistry, Substrate Specificity, Gene Knockout Techniques, 03 medical and health sciences, Bacterial Proteins, Glucuronic Acid, Species Specificity, Extracellular, Molecular Biology, Gene, Phylogeny, Polysaccharide-Lyases, Vibrio, chemistry.chemical_classification, Molecular Structure, biology, Hexuronic Acids, Hydrolysis, Gene Expression Regulation, Bacterial, Cell Biology, Hydrogen-Ion Concentration, biology.organism_classification, Recombinant Proteins, Isoenzymes, Molecular Weight, 030104 developmental biology, Enzyme, chemistry, biology.protein, Biomarkers, Bacteria

Abstract

Polysaccharide degradation by marine microbes represents one of the largest and most rapid heterotrophic transformations of organic matter in the environment. Microbes employ systems of complementary carbohydrate-specific enzymes to deconstruct algal or plant polysaccharides (glycans) into monosaccharides. Because of the high diversity of glycan substrates, the functions of these enzymes are often difficult to establish. One solution to this problem may lie within naturally occurring microdiversity; varying numbers of enzymes, due to gene loss, duplication, or transfer, among closely related environmental microbes create metabolic differences akin to those generated by knock-out strains engineered in the laboratory used to establish the functions of unknown genes. Inspired by this natural fine-scale microbial diversity, we show here that it can be used to develop hypotheses guiding biochemical experiments for establishing the role of these enzymes in nature. In this work, we investigated alginate degradation among closely related strains of the marine bacterium Vibrio splendidus. One strain, V. splendidus 13B01, exhibited high extracellular alginate lyase activity compared with other V. splendidus strains. To identify the enzymes responsible for this high extracellular activity, we compared V. splendidus 13B01 with the previously characterized V. splendidus 12B01, which has low extracellular activity and lacks two alginate lyase genes present in V. splendidus 13B01. Using a combination of genomics, proteomics, biochemical, and functional screening, we identified a polysaccharide lyase family 7 enzyme that is unique to V. splendidus 13B01, secreted, and responsible for the rapid digestion of extracellular alginate. These results demonstrate the value of querying the enzymatic repertoires of closely related microbes to rapidly pinpoint key proteins with beneficial functions.

Published

2017

34. Host-Microbe Interactions in the Chemosynthetic Riftia pachyptila Symbiosis

Author

Manuel Kleiner, Thorsten B. H. Reusch, Horst Felbeck, Tjorven Hinzke, Robert Häsler, Stefan M. Sievert, Thomas Schweder, Philip Rosenstiel, Corinna Breusing, Rabea Schlüter, and Stephanie Markert

Subjects

Proteomics, 0106 biological sciences, Aquatic Organisms, animal structures, Proteome, Adaptation, Biological, 01 natural sciences, Microbiology, Host-Microbe Biology, host-microbe interactions, chemosynthesis, Transcriptome, 03 medical and health sciences, Symbiosis, hydrothermal vents, Animals, Seawater, Host protein, 030304 developmental biology, holobiont, Chemosynthesis, Genetics, Pachyptila, 0303 health sciences, biology, Host (biology), Microbiota, 010604 marine biology & hydrobiology, fungi, food and beverages, Polychaeta, Substrate (biology), biochemical phenomena, metabolism, and nutrition, biology.organism_classification, symbiosis, QR1-502, Metabolome, bacteria, Animal Nutritional Physiological Phenomena, metaproteomics, Energy Metabolism, Oxidation-Reduction, Metabolic Networks and Pathways, Bacteria, Research Article

Abstract

All animals are associated with microorganisms; hence, host-microbe interactions are of fundamental importance for life on earth. However, we know little about the molecular basis of these interactions. Therefore, we studied the deep-sea Riftia pachyptila symbiosis, a model association in which the tubeworm host is associated with only one phylotype of endosymbiotic bacteria and completely depends on this sulfur-oxidizing symbiont for nutrition. Using a metaproteomics approach, we identified both metabolic interaction processes, such as substrate transfer between the two partners, and interactions that serve to maintain the symbiotic balance, e.g., host efforts to control the symbiont population or symbiont strategies to modulate these host efforts. We suggest that these interactions are essential principles of mutualistic animal-microbe associations., The deep-sea tubeworm Riftia pachyptila lacks a digestive system but completely relies on bacterial endosymbionts for nutrition. Although the symbiont has been studied in detail on the molecular level, such analyses were unavailable for the animal host, because sequence information was lacking. To identify host-symbiont interaction mechanisms, we therefore sequenced the Riftia transcriptome, which served as a basis for comparative metaproteomic analyses of symbiont-containing versus symbiont-free tissues, both under energy-rich and energy-limited conditions. Our results suggest that metabolic interactions include nutrient allocation from symbiont to host by symbiont digestion and substrate transfer to the symbiont by abundant host proteins. We furthermore propose that Riftia maintains its symbiont by protecting the bacteria from oxidative damage while also exerting symbiont population control. Eukaryote-like symbiont proteins might facilitate intracellular symbiont persistence. Energy limitation apparently leads to reduced symbiont biomass and increased symbiont digestion. Our study provides unprecedented insights into host-microbe interactions that shape this highly efficient symbiosis.

Published

2019

35. Characterization of a thaumarchaeal symbiont that drives incomplete nitrification in the tropical sponge Ianthella basta

Author

Michael Wagner, Thomas Rattei, Florian U. Moeller, Dmitrij Turaev, Per Halkjær Nielsen, Faris Behnam, Mads Albertsen, Nicole S. Webster, Daryl Domman, Stephanie Markert, Andreas Richter, Dörte Becher, Margarete Watzka, Craig W. Herbold, Maria Mooshammer, and Thomas Schweder

Subjects

Proteases, Chemoautotrophic Growth, Thaumarchaeota, medicine.medical_treatment, Microbiology, 03 medical and health sciences, Ianthella basta, Ammonia, medicine, Animals, 14. Life underwater, Ecology, Evolution, Behavior and Systematics, Research Articles, In Situ Hybridization, Fluorescence, Nitrites, Phylogeny, Soil Microbiology, 030304 developmental biology, Genetics, 0303 health sciences, Protease, biology, 030306 microbiology, Host (biology), biology.organism_classification, Archaea, Nitrification, Porifera, Sponge, Metagenomics, Evolutionary biology, Metaproteomics, Candidatus, Oxidation-Reduction, Research Article

Abstract

SummaryMarine sponges represent one of the few eukaryotic groups that frequently harbor symbiotic members of theThaumarchaeota, which are important chemoautotrophic ammonia-oxidizers in many environments. However, in most studies, direct demonstration of ammonia-oxidation by these archaea within sponges is lacking, and little is known about sponge-specific adaptations of ammonia-oxidizing archaea (AOA). Here, we characterized the thaumarchaeal symbiont of the marine spongeIanthella bastausing metaproteogenomics, fluorescencein situhybridization, qPCR and isotope-based functional assays. “CandidatusNitrosospongia bastadiensis” is only distantly related to cultured AOA. It is an abundant symbiont that is solely responsible for nitrite formation from ammonia inI. bastathat surprisingly does not harbor nitrite-oxidizing microbes. Furthermore, this AOA is equipped with an expanded set of extracellular subtilisin-like proteases, a metalloprotease unique among archaea, as well as a putative branched-chain amino acid ABC transporter. This repertoire is strongly indicative of a mixotrophic lifestyle and is (with slight variations) also found in other sponge-associated, but not in free-living AOA. We predict that this feature as well as an expanded and unique set of secreted serpins (protease inhibitors), a unique array of eukaryotic-like proteins, and a DNA-phosporothioation system, represent important adaptations of AOA to life within these ancient filter-feeding animals.Originality-Significance StatementMany marine sponges harbor symbiotic members of theThaumarchaeota, but there is generally only indirect evidence available about their functional role within these filter-feeding animals. Furthermore, the specific adaptations of thaumarchaeal symbionts to their sponge hosts are incompletely understood. In this study, we thoroughly characterized a thaumarchaeal symbiont residing in the reef spongeIanthella bastaand demonstrate by using a combination of molecular tools and isotope techniques, that it is the only ammonia-oxidizer in its host. In contrast to other sponges,I. bastadoes not contain nitrite-oxidizing microbes and thus excretes considerable amounts of nitrite. Furthermore, using metagenomics and metaproteomics we reveal important adaptations of this symbiont, that represents a new genus within theThaumarchaeota, and conclude that it most likely lives as a mixotroph in its sponge host.

Published

2019

36. Biopearling of Interconnected Outer Membrane Vesicle Chains by a Marine Flavobacterium

Author

Androniki Kolovou, Erhard Rhiel, Sten Littmann, Stephanie Markert, Jens Harder, Greta Reintjes, Thomas Schweder, Dörte Becher, Rachel Santarella-Mellwig, Martin Schorb, and Tanja Fischer

Subjects

Proteomics, Aquatic Organisms, Vesicle lumen, Flavobacterium, Applied Microbiology and Biotechnology, Extracellular Vesicles, 03 medical and health sciences, Laminarin, chemistry.chemical_compound, Environmental Microbiology, Secretion, Glucans, 030304 developmental biology, 0303 health sciences, Ecology, biology, 030306 microbiology, Vesicle, Cell Membrane, Eutrophication, biology.organism_classification, Microscopy, Electron, Membrane, chemistry, Liposomes, Biophysics, Bacterial outer membrane, Flavobacteriia, Bacterial Outer Membrane Proteins, Food Science, Biotechnology

Abstract

Large surface-to-volume ratios provide optimal nutrient uptake conditions for small microorganisms in oligotrophic habitats. The surface area can be increased with appendages. Here, we describe chains of interconnecting vesicles protruding from cells of strain Hel3_A1_48, affiliating with Formosa spp. within the Flavobacteriia and originating from coastal free-living bacterioplankton. The chains were up to 10 μm long and had vesicles emanating from the outer membrane with a single membrane and a size of 80 to 100 nm by 50 to 80 nm. Cells extruded membrane tubes in the exponential phase, whereas vesicle chains dominated on cells in the stationary growth phase. This formation is known as pearling, a physical morphogenic process in which membrane tubes protrude from liposomes and transform into chains of interconnected vesicles. Proteomes of whole-cell membranes and of detached vesicles were dominated by outer membrane proteins, including the type IX secretion system and surface-attached peptidases, glycoside hydrolases, and endonucleases. Fluorescein-labeled laminarin stained the cells and the vesicle chains. Thus, the appendages provide binding domains and degradative enzymes on their surfaces and probably storage volume in the vesicle lumen. Both may contribute to the high abundance of these Formosa-affiliated bacteria during laminarin utilization shortly after spring algal blooms. IMPORTANCE Microorganisms produce membrane vesicles. One synthesis pathway seems to be pearling that describes the physical formation of vesicle chains from phospholipid vesicles via extended tubes. Bacteria with vesicle chains had been observed as well as bacteria with tubes, but pearling was so far not observed. Here, we report the observation of, initially, tubes and then vesicle chains during the growth of a flavobacterium, suggesting biopearling of vesicle chains. The flavobacterium is abundant during spring bacterioplankton blooms developing after algal blooms and has a special set of enzymes for laminarin, the major storage polysaccharide of microalgae. We demonstrated with fluorescently labeled laminarin that the vesicle chains bind laminarin or contain laminarin-derived compounds. Proteomic analyses revealed surface-attached degradative enzymes on the outer membrane vesicles. We conclude that the large surface area and the lumen of vesicle chains may contribute to the ecological success of this marine bacterium.

Published

2019

37. Verrucomicrobia use hundreds of enzymes to digest the algal polysaccharide fucoidan

Author

Andreas, Sichert, Christopher H, Corzett, Matthew S, Schechter, Frank, Unfried, Stephanie, Markert, Dörte, Becher, Antonio, Fernandez-Guerra, Manuel, Liebeke, Thomas, Schweder, Martin F, Polz, and Jan-Hendrik, Hehemann

Subjects

Glycoside Hydrolases, Proteome, Sulfates, Esterases, Phaeophyta, United States, Substrate Specificity, Bacterial Proteins, Verrucomicrobia, Cell Wall, Genes, Bacterial, Polysaccharides, Metagenome, Sulfatases, Transcriptome, Metabolic Networks and Pathways, Phylogeny

Abstract

Brown algae are important players in the global carbon cycle by fixing carbon dioxide into 1 Gt of biomass annually, yet the fate of fucoidan-their major cell wall polysaccharide-remains poorly understood. Microbial degradation of fucoidans is slower than that of other polysaccharides, suggesting that fucoidans are more recalcitrant and may sequester carbon in the ocean. This may be due to the complex, branched and highly sulfated structure of fucoidans, which also varies among species of brown algae. Here, we show that 'Lentimonas' sp. CC4, belonging to the Verrucomicrobia, acquired a remarkably complex machinery for the degradation of six different fucoidans. The strain accumulated 284 putative fucoidanases, including glycoside hydrolases, sulfatases and carbohydrate esterases, which are primarily located on a 0.89-megabase pair plasmid. Proteomics reveals that these enzymes assemble into substrate-specific pathways requiring about 100 enzymes per fucoidan from different species of brown algae. These enzymes depolymerize fucoidan into fucose, which is metabolized in a proteome-costly bacterial microcompartment that spatially constrains the metabolism of the toxic intermediate lactaldehyde. Marine metagenomes and microbial genomes show that Verrucomicrobia including 'Lentimonas' are abundant and highly specialized degraders of fucoidans and other complex polysaccharides. Overall, the complexity of the pathways underscores why fucoidans are probably recalcitrant and more slowly degraded, since only highly specialized organisms can effectively degrade them in the ocean.

Published

2019

38. A marine bacterial enzymatic cascade degrades the algal polysaccharide ulvan

Author

Robert Larocque, Jan-Hendrik Hehemann, Gurvan Michel, Marcus Bäumgen, Dörte Becher, Aurélie Préchoux, Mihovilovic, Thomas Schweder, Stephanie Markert, Thomas Roret, Uwe T. Bornscheuer, Christian Stanetty, Frank Unfried, Lukas Reisky, Tao Song, N. Gerlach, Marie-Katherin Zühlke, Craig S. Robb, Anke Trautwein-Schult, Laboratoire de Biologie Intégrative des Modèles Marins (LBI2M), Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Station biologique de Roscoff (SBR), Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Centre National de la Recherche Scientifique (CNRS), Universität Greifswald - University of Greifswald, Leibniz Institute of Plant Genetics and Crop Plant Research [Gatersleben] (IPK-Gatersleben), Max Planck Institute for Marine Microbiology, and Max-Planck-Gesellschaft

Subjects

Models, Molecular, Protein Conformation, [SDV]Life Sciences [q-bio], Biomass, Polysaccharide, Algal bloom, Gene Expression Regulation, Enzymologic, 03 medical and health sciences, Bacterial Proteins, Algae, Polysaccharides, Botany, [CHIM.CRIS]Chemical Sciences/Cristallography, Glycoside hydrolase, [SDV.BBM]Life Sciences [q-bio]/Biochemistry, Molecular Biology, 14. Life underwater, Molecular Biology, ComputingMilieux_MISCELLANEOUS, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, biology, Chemistry, fungi, 030302 biochemistry & molecular biology, food and beverages, Gene Expression Regulation, Bacterial, Genomics, Cell Biology, biology.organism_classification, Metabolic pathway, Carbohydrate Metabolism, Fermentation, Sulfatases, Flavobacteriaceae, Genome, Bacterial, Flavobacterium

Abstract

Marine seaweeds increasingly grow into extensive algal blooms, which are detrimental to coastal ecosystems, tourism and aquaculture. However, algal biomass is also emerging as a sustainable raw material for the bioeconomy. The potential exploitation of algae is hindered by our limited knowledge of the microbial pathways-and hence the distinct biochemical functions of the enzymes involved-that convert algal polysaccharides into oligo- and monosaccharides. Understanding these processes would be essential, however, for applications such as the fermentation of algal biomass into bioethanol or other value-added compounds. Here, we describe the metabolic pathway that enables the marine flavobacterium Formosa agariphila to degrade ulvan, the main cell wall polysaccharide of bloom-forming Ulva species. The pathway involves 12 biochemically characterized carbohydrate-active enzymes, including two polysaccharide lyases, three sulfatases and seven glycoside hydrolases that sequentially break down ulvan into fermentable monosaccharides. This way, the enzymes turn a previously unexploited renewable into a valuable and ecologically sustainable bioresource.

Published

2019

39. A robust metaproteomics pipeline for a holistic taxonomic and functional characterization of microbial communities from marine particles

Author

Katharina Riedel, Claudia Hirschfeld, T. B. Francis, Jörg Bernhardt, Daniel Schultz, Dirk Albrecht, D. Zuehlke, and Stephanie Markert

Subjects

Marine bacteriophage, biology, Metagenomics, Ecology, Microorganism, Aquatic ecosystem, Metaproteomics, Proteobacteria, Plankton, biology.organism_classification, Flavobacteriia

Abstract

SummaryThis study aimed to establish a robust, reproducible and reliable metaproteomic pipeline for an in-depth characterization of marine particle-associated (PA) bacteria. To this end, we compared six well-established protein extraction protocols together with different MS-sample preparation techniques using particles sampled during a North Sea spring algae bloom in 2009. In this optimized workflow, proteins are extracted using a combination of SDS-containing lysis buffer and cell disruption by bead-beating, separated by SDS-PAGE, in-gel digested and analysed by LC-MS/MS, before MASCOT search against a metagenome-based database and data processing/visualization with the in-house-developed bioinformatics tools Prophane and Paver.As proof of principle, free-living (FL) and particulate communities sampled in April 2009 were analysed, resulting in an as yet unprecedented number of 9,354 and 5,034 identified protein groups for FL and PA bacteria, respectively. Our data revealed that FL and PA communities appeared similar in their taxonomic distribution, with notable exceptions: eukaryotic proteins and proteins assigned to Flavobacteriia, Cyanobacteria, and some proteobacterial genera were found more abundant on particles, whilst overall proteins belonging to Proteobacteria were more dominant in the FL fraction. In contrast, significant functional differences including proteins involved in polysaccharide degradation, sugar- and phosphorus uptake, adhesion, motility, and stress response were detected.Originality-Significance StatementMarine particles consist of organic particulate matter (e.g. phyto- or zooplankton) and particle-associated (PA) microbial communities, which are often embedded in a sugary matrix. A significant fraction of the decaying algal biomass in marine ecosystems is expected to be mineralized by PA heterotrophic communities, which are thus greatly contributing to large-scale carbon fluxes. Whilst numerous studies have investigated the succession of planktonic marine bacteria along phytoplankton blooms, the community structure and functionality of PA bacterial communities remained largely unexplored and knowledge on specific contributions of these microorganisms to carbon cycling is still surprisingly limited. This has been mostly been due to technical problems, i.e. to the difficulty to retrieve genomic DNA and proteins from these polysaccharide-rich entities, their enormous complexity and the high abundance of eukaryotic microorganisms.Our study presents an innovative, robust, reproducible, and reliable metaproteomics pipeline for marine particles, which will help to address and fill the above-described knowledge gap. Employing the here established workflow enabled us to identify more than 5,000 PA proteins, which is, at least to our knowledge, the largest number of protein groups ever assigned to marine particles. Notably, the novel pipeline has been validated by a first, comparative metaproteome analysis of free-living and PA bacterial communities indicating a significant functional shift enabling surface-associated bacteria to adapt to particle-specific living conditions. In conclusion, our novel metaproteomics pipeline presents a solid and promising methodological groundwork for future culture-independent analyses of seasonal taxonomic and functional successions of PA microbial communities in aquatic habitats.

Published

2019

40. Individual Physiological Adaptations Enable Selected Bacterial Taxa To Prevail during Long-Term Incubations

Author

Dörte Becher, Frank Unfried, Daniel P. R. Herlemann, Thomas Schweder, Christian Hentschker, I. de Bruijn, Anders F. Andersson, Christian Meeske, Klaus Jürgens, Stephanie Markert, and Center of Limnology

Subjects

Time Factors, Proteome, Baltic Sea, Oceans and Seas, Enclosure, Biology, Bacterial Physiological Phenomena, Applied Microbiology and Biotechnology, Microbial Ecology, salinity, 03 medical and health sciences, enclosure, Microbial ecology, Bacterial Proteins, RNA, Ribosomal, 16S, Dissolved organic carbon, Seawater, Incubation, 030304 developmental biology, Sweden, 0303 health sciences, Spongiibacter, Ecology, 030306 microbiology, Bacterial Load, Salinity, RNA, Bacterial, Taxon, Microbial population biology, articles, bottle effect, Food Science, Biotechnology

Abstract

Enclosure experiments are frequently used to investigate the impact of changing environmental conditions on microbial assemblages. Yet, how the incuba- tion itself challenges complex bacterial communities is thus far unknown. In this study, metaproteomic profiling, 16S rRNA gene analyses, and cell counts were com- bined to evaluate bacterial communities derived from marine, mesohaline, and oli- gohaline conditions after long-term batch incubations. Early in the experiment, the three bacterial communities were highly diverse and differed significantly in their compositions. Manipulation of the enclosures with terrigenous dissolved organic car- bon resulted in notable differences compared to the control enclosures at this early phase of the experiment. However, after 55 days, bacterial communities in the ma- nipulated and the control enclosures under marine and mesohaline conditions were all dominated by gammaproteobacterium Spongiibacter. In the oligohaline enclo- sures, actinobacterial cluster I of the hgc group (hgc-I) remained abundant in the late phase of the incubation. Metaproteome analyses suggested that the ability to use outer membrane-based internal energy stores, in addition to the previously de- scribed grazing resistance, may enable the gammaproteobacterium Spongiibacter to prevail in long-time incubations. Under oligohaline conditions, the utilization of ex- ternal recalcitrant carbon appeared to be more important (hgc-I). Enclosure experi- ments with complex natural microbial communities are important tools to investi- gate the effects of manipulations. However, species-specific properties, such as individual carbon storage strategies, can cause manipulation-independent effects and need to be considered when interpreting results from enclosures. This study was financially supported by the SAW-funded ATKiM project, which provided funds to D. P. R. Herlemann, C. Meeske, K. Jürgens, S. Markert, and T. Schweder. D. P. R. Herlemann was also supported by the European Regional Develop- ment Fund/Estonian Research Council funded Mobilitas Plus Top Researcher grant MOBTT24. We thank the crew and captain of the RV Meteor (M86, M87) for support during the research cruise. The computations were performed on resources provided by the Swedish National Infrastructure for Computing (SNIC) at the PDC Centre for High Performance Computing (PDC-HPC) and Uppsala Multidisciplinary Center for Advanced Computational Science (UPPMAX). We thank Jana Matulla for excellent technical assis- tance and Stephan Fuchs for his help and advice in MS database construction. We also thank Stefan E. Heiden for valuable help with the CDD BLAST analyses. This study was financially supported by the SAW-funded ATKiM project, which provided funds to D. P. R. Herlemann, C. Meeske, K. Jürgens, S. Markert, and T. Schweder. D. P. R. Herlemann was also supported by the European Regional Develop- ment Fund/Estonian Research Council funded Mobilitas Plus Top Researcher grant MOBTT24. We thank the crew and captain of the RV Meteor (M86, M87) for support during the research cruise. The computations were performed on resources provided by the Swedish National Infrastructure for Computing (SNIC) at the PDC Centre for High Performance Computing (PDC-HPC) and Uppsala Multidisciplinary Center for Advanced Computational Science (UPPMAX). We thank Jana Matulla for excellent technical assis- tance and Stephan Fuchs for his help and advice in MS database construction. We also thank Stefan E. Heiden for valuable help with the CDD BLAST analyses.

Published

2019

41. Centrifugation-Based Enrichment of Bacterial Cell Populations for Metaproteomic Studies on Bacteria-Invertebrate Symbioses

Author

Tjorven, Hinzke, Manuel, Kleiner, and Stephanie, Markert

Subjects

Proteomics, Bacteria, Proteome, Centrifugation, Density Gradient, Animals, Centrifugation, Symbiosis, Invertebrates

Abstract

Owing to high sample complexity, metaproteomic investigations on bacteria-animal symbioses with two or more uncultured partners can be challenging. A selective isolation or enrichment of distinct (sub-)populations within those consortia can solve this problem. Subsequent discrete proteomic analyses benefit from increased sample purity and higher proteome coverage for each of the individual organisms. Here, we describe centrifugation-based methods that allow for a separation of the host and its bacterial symbiont population(s), or even for an enrichment of distinct symbiotic cell cycle stages in the deep-sea mussels Bathymodiolus azoricus and B. thermophilus, the gutless oligochaete Olavius algarvensis and the deep-sea tube worm Riftia pachyptila, respectively.

Published

2018

42. Transcriptomic and proteomic insight into the mechanism of cyclooctasulfur- versus thiosulfate-oxidation by the chemolithoautotroph Sulfurimonas denitrificans

Author

Jesse McNichol, Petra Pjevac, Florian Götz, Dörte Becher, Marc Mussmann, Stephanie Markert, Stefan M. Sievert, and Thomas Schweder

Subjects

Proteomics, Chemoautotrophic Growth, Proteome, Helicobacteraceae, Sulfur metabolism, Thiosulfates, chemistry.chemical_element, Biology, Microbiology, Transcriptome, 03 medical and health sciences, chemistry.chemical_compound, Gene, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Thiosulfate, 0303 health sciences, 030306 microbiology, Gene Expression Regulation, Bacterial, biology.organism_classification, Sulfur, chemistry, Biochemistry, Oxidation-Reduction, Bacteria

Abstract

Chemoautotrophic bacteria belonging to the genus Sulfurimonas (class Campylobacteria) were previously identified as key players in the turnover of zero-valence sulfur, a central intermediate in the marine sulfur cycle. S. denitrificans was further shown to be able to oxidize cyclooctasulfur (S8 ). However, at present the mechanism of activation and metabolism of cyclooctasulfur is not known. Here, we assessed the transcriptome and proteome of S. denitrificans grown with either thiosulfate or S8 as the electron donor. While the overall expression profiles under the two growth conditions were rather similar, distinct differences were observed that could be attributed to the utilization of S8 . This included a higher abundance of expressed genes related to surface attachment in the presence of S8 , and the differential regulation of the sulfur-oxidation multienzyme complex (SOX), which in S. denitrificans is encoded in two gene clusters: soxABXY 1 Z 1 and soxCDY 2 Z 2 . While the proteins of both clusters were present with thiosulfate, only proteins of the soxCDY 2 Z 2 were detected at significant levels with S8 . Based on these findings a model for the oxidation of S8 is proposed. Our results have implications for interpreting metatranscriptomic and -proteomic data and for the observed high level of diversification of soxY 2 Z 2 among sulfur-oxidizing Campylobacteria.

Published

2018

43. Centrifugation-Based Enrichment of Bacterial Cell Populations for Metaproteomic Studies on Bacteria–Invertebrate Symbioses

Author

Tjorven Hinzke, Manuel Kleiner, and Stephanie Markert

Subjects

0301 basic medicine, education.field_of_study, biology, Host (biology), fungi, Population, food and beverages, Zoology, biology.organism_classification, Bacterial cell structure, Tube worm, 03 medical and health sciences, 030104 developmental biology, Symbiosis, Proteome, Centrifugation, education, Bacteria

Abstract

Owing to high sample complexity, metaproteomic investigations on bacteria-animal symbioses with two or more uncultured partners can be challenging. A selective isolation or enrichment of distinct (sub-)populations within those consortia can solve this problem. Subsequent discrete proteomic analyses benefit from increased sample purity and higher proteome coverage for each of the individual organisms. Here, we describe centrifugation-based methods that allow for a separation of the host and its bacterial symbiont population(s), or even for an enrichment of distinct symbiotic cell cycle stages in the deep-sea mussels Bathymodiolus azoricus and B. thermophilus, the gutless oligochaete Olavius algarvensis and the deep-sea tube worm Riftia pachyptila, respectively.

Published

2018

44. Adaptive mechanisms that provide competitive advantages to marine bacteroidetes during microalgal blooms

Author

Rudolf Amann, Hanno Teeling, Thomas Schweder, Stefan E. Heiden, Craig S. Robb, Jens Harder, Stephanie Markert, Tjorven Hinzke, Bernhard M. Fuchs, Richard L. Hahnke, Karen Krüger, Tristan Barbeyron, Lennart Kappelmann, Greta Reintjes, Doerte Becher, Stefan Becker, Burak Avci, Frank Unfried, Jan-Hendrik Hehemann, Tanja Fischer, Universität Greifswald - University of Greifswald, Max Planck Institute for Marine Microbiology, Max-Planck-Gesellschaft, University of Bremen, Végétaux marins et biomolécules, Station biologique de Roscoff [Roscoff] (SBR), Université Pierre et Marie Curie - Paris 6 (UPMC)-Centre National de la Recherche Scientifique (CNRS)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Centre National de la Recherche Scientifique (CNRS)-GOEMAR-Centre National de la Recherche Scientifique (CNRS), Station biologique de Roscoff (SBR), and Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)

Subjects

0301 basic medicine, Water microbiology, Hydrolases, SUCCESSION, Microbial ecology, Laminarin, chemistry.chemical_compound, PHYTOPLANKTON, Phytoplankton/metabolism, Microalgae, Glucans/metabolism, Glucans, Flavobacteriaceae/genetics, chemistry.chemical_classification, biology, Eutrophication, MICROBIOTA, Adaptation, Physiological, Bacteroidetes/genetics, [SDV.MP]Life Sciences [q-bio]/Microbiology and Parasitology, BACTERIA, CARBOHYDRATE-ACTIVE ENZYMES, North Sea, Flavobacteriaceae, 030106 microbiology, Heterotroph, BACTERIOPLANKTON, POLYSACCHARIDE UTILIZATION LOCI, Polysaccharide, Microbiology, Algal bloom, Article, Carbon Cycle, 03 medical and health sciences, Bacterial Proteins, Polysaccharides, ddc:570, Botany, REVEALS, Polysaccharides/metabolism, 14. Life underwater, Ecology, Evolution, Behavior and Systematics, IDENTIFICATION, Hydrolases/genetics, Bacteroidetes, Bacterial Proteins/genetics, fungi, DEGRADATION, biology.organism_classification, 030104 developmental biology, chemistry, 13. Climate action, Metagenomics, Phytoplankton, Metaproteomics, Microalgae/metabolism, Bacteria

Abstract

International audience; Polysaccharide degradation by heterotrophic microbes is a key process within Earth’s carbon cycle. Here, we use environmental proteomics and metagenomics in combination with cultivation experiments and biochemical characterizations to investigate the molecular details of in situ polysaccharide degradation mechanisms during microalgal blooms. For this, we use laminarin as a model polysaccharide. Laminarin is a ubiquitous marine storage polymer of marine microalgae and is particularly abundant during phytoplankton blooms. In this study, we show that highly specialized bacterial strains of the Bacteroidetes phylum repeatedly reached high abundances during North Sea algal blooms and dominated laminarin turnover. These genomically streamlined bacteria of the genus Formosa have an expanded set of laminarin hydrolases and transporters that belonged to the most abundant proteins in the environmental samples. In vitro experiments with cultured isolates allowed us to determine the functions of in situ expressed key enzymes and to confirm their role in laminarin utilization. It is shown that laminarin consumption of Formosa spp. is paralleled by enhanced uptake of diatom-derived peptides. This study reveals that genome reduction, enzyme fusions, transporters, and enzyme expansion as well as a tight coupling of carbon and nitrogen metabolism provide the tools, which make Formosa spp. so competitive during microalgal blooms.

Published

2018

45. Limonene dehydrogenase hydroxylates the allylic methyl group of cyclic monoterpenes in the anaerobic terpene degradation by

Author

Edinson, Puentes-Cala, Manuel, Liebeke, Stephanie, Markert, and Jens, Harder

Subjects

Bacterial Proteins, Monoterpenes, Enzymology, Amino Acid Sequence, Hydroxylation, Oxidoreductases, Sequence Alignment, Limonene, Alcaligenaceae

Abstract

The enzymatic functionalization of hydrocarbons is a central step in the global carbon cycle initiating the mineralization of methane, isoprenes, and monoterpenes, the most abundant biologically produced hydrocarbons. Also, terpene-modifying enzymes have found many applications in the energy-economic biotechnological production of fine chemicals. Here, we describe a limonene dehydrogenase that was purified from the facultatively anaerobic betaproteobacterium Castellaniella defragrans 65Phen grown on monoterpenes under denitrifying conditions in the absence of molecular oxygen. The purified limonene:ferrocenium oxidoreductase activity hydroxylated the methyl group of limonene (1-methyl-4-(1-methylethenyl)-cyclohex-1-ene) yielding perillyl alcohol ([4-(prop-1-en-2-yl)cyclohex-1-en-1-yl]methanol). The enzyme had a DTT:perillyl alcohol oxidoreductase activity yielding limonene. Mass spectrometry and molecular size determinations revealed a heterodimeric enzyme comprising CtmA and CtmB. Recently, the two proteins had been identified by transposon mutagenesis and proteomics as part of the cyclic terpene metabolism (ctm) in C. defragrans and are annotated as FAD-dependent oxidoreductases of the protein domain family phytoene dehydrogenases and related proteins (COG1233). CtmAB is the first heterodimeric enzyme in this protein superfamily. Flavins in the purified CtmAB are oxidized by ferrocenium and are reduced by limonene. Heterologous expression of CtmA, CtmB, and CtmAB in Escherichia coli demonstrated that limonene dehydrogenase activity required both subunits, each carrying a flavin cofactor. Native CtmAB oxidized a wide range of monocyclic monoterpenes containing the allylic methyl group motif (1-methyl-cyclohex-1-ene). In conclusion, we have identified CtmAB as a hydroxylating limonene dehydrogenase and the first heteromer in a family of FAD-dependent dehydrogenases acting on allylic methylene or methyl CH-bonds. We suggest placing in Enzyme Nomenclature as new entry EC 1.17.99.8.

Published

2017

46. Efficient protein extraction for proteomics and metaproteomics (also suitable for low biomass samples) v1

Author

Tjorven Hinzke and Stephanie Markert

Subjects

Chromatography, Lysis, Chemistry, Protein purification, Metaproteomics, Biomass, Proteomics, Sodium Deoxycholate

Abstract

This protocol describes an optimized protein extraction method for (meta-) proteomic analyses. It is based on several existing protocols (see references below) that were combined and adapted and is also compatible with low biomass samples. References: Erde et al. 2014, J. Proteome Res. 13, 1885-1895 Kleiner et al. 2017, Nat. Comm. 8, Article Number 1558 Kulak et al. 2014, Nat. Methods 11, 319-324 León et al. 2013, Mol. Cell. Proteomics 12, 2992-3005 Masuda 2008, J. Proteome Res. 7, 731-740 Wang et al. 2015, Int. J. Anal. Chem. 2015,Article ID 763969 Wisniewski et al. 2009, Nat. Methods 6, 359-362

Published

2017

47. Genome sequence of the sulfur-oxidizing Bathymodiolus thermophilus gill endosymbiont

Author

Thomas Schweder, Andrea Thürmer, Stefan E. Heiden, Stephanie Markert, Stefan M. Sievert, Ruby Ponnudurai, Rolf Daniel, Manuel Kleiner, Horst Felbeck, Rabea Schlüter, and Lizbeth Sayavedra

Subjects

0106 biological sciences, 0301 basic medicine, lcsh:QH426-470, Population, 01 natural sciences, Genome, Thiotrophy, Microbiology, 03 medical and health sciences, Symbiosis, Gammaproteobacteria, Genetics, Bathymodiolus thermophilus, 14. Life underwater, Extended Genome Report, Uncultured endosymbiont, education, Gene, Whole genome sequencing, education.field_of_study, Marine invertebrate symbiosis, biology, 010604 marine biology & hydrobiology, fungi, food and beverages, biology.organism_classification, lcsh:Genetics, Hydrothermal vents, 030104 developmental biology, Biochemistry, Autotrophy, bacteria, Energy source

Abstract

Bathymodiolus thermophilus, a mytilid mussel inhabiting the deep-sea hydrothermal vents of the East Pacific Rise, lives in symbiosis with chemosynthetic Gammaproteobacteria within its gills. The intracellular symbiont population synthesizes nutrients for the bivalve host using the reduced sulfur compounds emanating from the vents as energy source. As the symbiont is uncultured, comprehensive and detailed insights into its metabolism and its interactions with the host can only be obtained from culture-independent approaches such as genomics and proteomics. In this study, we report the first draft genome sequence of the sulfur-oxidizing symbiont of B. thermophilus, here tentatively named Candidatus Thioglobus thermophilus. The draft genome (3.1 Mb) harbors 3045 protein-coding genes. It revealed pathways for the use of sulfide and thiosulfate as energy sources and encodes the Calvin-Benson-Bassham cycle for CO2 fixation. Enzymes required for the synthesis of the tricarboxylic acid cycle intermediates oxaloacetate and succinate were absent, suggesting that these intermediates may be substituted by metabolites from external sources. We also detected a repertoire of genes associated with cell surface adhesion, bacteriotoxicity and phage immunity, which may perform symbiosis-specific roles in the B. thermophilus symbiosis.

Published

2017

48. Insight into the evolution of microbial metabolism from the deep-branching bacterium, Thermovibrio ammonificans

Author

Michael Hügler, Costantino Vetriani, Stephanie Markert, Dörte Becher, Stefan M. Sievert, Thomas Schweder, Donato Giovannelli, Giovannelli, Donato, Sievert, Stefan M., Hügler, Michael, Markert, Stephanie, Becher, Dörte, Schweder, Thoma, and Vetriani, Costantino

Subjects

0301 basic medicine, Proteomics, Immunology and Microbiology (all), Microbial metabolism, genomic, SEA HYDROTHERMAL VENT, HYDROGEN-OXIDIZING BACTERIUM, COMPLETE GENOME SEQUENCE, NITRATE-AMMONIFYING BACTERIUM, AUTOTROPHIC CARBON FIXATION, TRICARBOXYLIC-ACID CYCLE, SP-NOV, GEN. NOV, MAXIMUM-LIKELIHOOD, THERMOPHILUS TK-6, Biology (General), Thermovibrio ammonifican, thermophile, Microbiology and Infectious Disease, biology, Ecology, General Neuroscience, Carbon fixation, General Medicine, Genomics, Biological Evolution, Genomics and Evolutionary Biology, Aquificae, Medicine, deep-sea vents, Metabolic Networks and Pathways, Research Article, thermophiles, QH301-705.5, Science, infectious disease, General Biochemistry, Genetics and Molecular Biology, Evolution, Molecular, 03 medical and health sciences, Bacteria, Anaerobic, evolution, Gene, deep-sea vent, Neuroscience (all), Biochemistry, Genetics and Molecular Biology (all), General Immunology and Microbiology, Thermophile, evolutionary biology, microbiology, Metabolic Networks and Pathway, Proteomic, biology.organism_classification, Early Earth, chemolithoautotrophy, 030104 developmental biology, 13. Climate action, Evolutionary biology, Thermovibrio ammonificans, Other, metabolism, Bacteria

Abstract

Anaerobic thermophiles inhabit relic environments that resemble the early Earth. However, the lineage of these modern organisms co-evolved with our planet. Hence, these organisms carry both ancestral and acquired genes and serve as models to reconstruct early metabolism. Based on comparative genomic and proteomic analyses, we identified two distinct groups of genes in Thermovibrio ammonificans: the first codes for enzymes that do not require oxygen and use substrates of geothermal origin; the second appears to be a more recent acquisition, and may reflect adaptations to cope with the rise of oxygen on Earth. We propose that the ancestor of the Aquificae was originally a hydrogen oxidizing, sulfur reducing bacterium that used a hybrid pathway for CO2 fixation. With the gradual rise of oxygen in the atmosphere, more efficient terminal electron acceptors became available and this lineage acquired genes that increased its metabolic flexibility while retaining ancestral metabolic traits. DOI: http://dx.doi.org/10.7554/eLife.18990.001, eLife digest Life may have arisen on our planet as far back as four billion years ago. Unlike today, the Earth’s atmosphere at the time had no oxygen and an abundance of volcanic emissions including hydrogen, carbon dioxide and sulfur gases. These dramatic differences have led scientists to wonder: how did the ancient microorganisms that inhabited our early planet make a living? And how has microbial life co-evolved with the Earth? One way to answer these questions is to study bacteria that live today in environments that resemble the early Earth. Deep-sea hydrothermal vents are regions of the deep ocean where active volcanic processes recreate primordial conditions. These habitats support microorganisms that are highly adapted to live off hydrogen, carbon dioxide and sulfur gases, and studying these modern-day microorganisms could give insights into the earliest life on Earth. Thermovibrio ammonificans is a bacterium that was obtained from an underwater volcanic system in the East Pacific. Giovannelli et al. have now asked if T. ammonificans might have inherited some of its genetic traits from a long-gone ancestor that also thrived off volcanic gases. The genetic makeup of this microorganism was examined for genes that would help it thrive at a deep-sea hydrothermal vent. Next, Giovannelli et al. compared these genes to related copies in other species of bacteria to reconstruct how the metabolism of T. ammonificans might have changed over time. This approach identified a group of likely ancient genesthat allow a microorganism to use chemicals like hydrogen, carbon dioxide and sulfur to fuel its growth and metabolism. These findings support the hypothesis that an ancestor of T. ammonificans could live off volcanic gases and that the core set of genes involved in those activities had been passed on, through the generations, to this modern-day microorganism. Giovannelli et al. also identified a second group of genes in T. ammonificans that indicate that this bacterium also co-evolved with Earth’s changing conditions, in particular the rise in the concentration of oxygen. The findings of Giovannelli et al. provide insight into how the metabolism of microbes has co-evolved with the Earth’s changing conditions, and will allow others to formulate new hypotheses that can be tested in laboratory experiments. DOI: http://dx.doi.org/10.7554/eLife.18990.002

Published

2017

49. Author response: Insight into the evolution of microbial metabolism from the deep-branching bacterium, Thermovibrio ammonificans

Author

Costantino Vetriani, Stephanie Markert, Donato Giovannelli, Dörte Becher, Stefan M. Sievert, Michael Hügler, and Thomas Schweder

Subjects

Biochemistry, biology, Chemistry, Microbial metabolism, Thermovibrio ammonificans, Branching (polymer chemistry), biology.organism_classification, Bacteria

Published

2017

50. Metabolic and physiological interdependencies in the Bathymodiolus azoricus symbiosis

Author

Stephanie Markert, Nicole Dubilier, Doerte Becher, Martin Moche, Andreas Otto, Thomas Schweder, Manuel Kleiner, Noriyuki Satoh, Lizbeth Sayavedra, Jillian M. Petersen, Takeshi Takeuchi, and Ruby Ponnudurai

Subjects

Gills, 0301 basic medicine, animal structures, Proteome, Microorganism, Sulfur metabolism, Biology, Microbiology, 03 medical and health sciences, Hydrothermal Vents, Species Specificity, Microbial ecology, Symbiosis, Gammaproteobacteria, Animals, Ecology, Evolution, Behavior and Systematics, Host (biology), fungi, food and beverages, biochemical phenomena, metabolism, and nutrition, biology.organism_classification, Biosynthetic Pathways, 030104 developmental biology, Calyptogena magnifica, Environmental biotechnology, Biochemistry, Mytilidae, bacteria, Original Article, Methane, Oxidation-Reduction, Sulfur

Abstract

The hydrothermal vent mussel Bathymodiolus azoricus lives in an intimate symbiosis with two types of chemosynthetic Gammaproteobacteria in its gills: a sulfur oxidizer and a methane oxidizer. Despite numerous investigations over the last decades, the degree of interdependence between the three symbiotic partners, their individual metabolic contributions, as well as the mechanism of carbon transfer from the symbionts to the host are poorly understood. We used a combination of proteomics and genomics to investigate the physiology and metabolism of the individual symbiotic partners. Our study revealed that key metabolic functions are most likely accomplished jointly by B. azoricus and its symbionts: (1) CO2 is pre-concentrated by the host for carbon fixation by the sulfur-oxidizing symbiont, and (2) the host replenishes essential biosynthetic TCA cycle intermediates for the sulfur-oxidizing symbiont. In return (3), the sulfur oxidizer may compensate for the host's putative deficiency in amino acid and cofactor biosynthesis. We also identified numerous ‘symbiosis-specific' host proteins by comparing symbiont-containing and symbiont-free host tissues and symbiont fractions. These proteins included a large complement of host digestive enzymes in the gill that are likely involved in symbiont digestion and carbon transfer from the symbionts to the host.

Published

2017