Your search keyword '"Plichta, Damian Rafal"' showing total 12 results

1. Predictive ability of host genetics and rumen microbiome for subclinical ketosis

Author

Gebreyesus, Grum, Difford, Gareth F., Buitenhuis, Bart, Lassen, Jan, Noel, Samantha Joan, Højberg, Ole, Plichta, Damian Rafal, Zhu, Zhigang, Poulsen, Nina A., Sundekilde, Ulrik K., Løvendahl, Peter, Sahana, Goutam, Gebreyesus, Grum, Difford, Gareth F., Buitenhuis, Bart, Lassen, Jan, Noel, Samantha Joan, Højberg, Ole, Plichta, Damian Rafal, Zhu, Zhigang, Poulsen, Nina A., Sundekilde, Ulrik K., Løvendahl, Peter, and Sahana, Goutam

Abstract

Subclinical metabolic disorders such as ketosis cause substantial economic losses for dairy farmers in addition to the serious welfare issues they pose for dairy cows. Major hurdles in genetic improvement against metabolic disorders such as ketosis include difficulties in large-scale phenotype recording and low heritability of traits. Milk concentrations of ketone bodies, such as acetone and β-hydroxybutyric acid (BHB), might be useful indicators to select cows for low susceptibility to ketosis. However, heritability estimates reported for milk BHB and acetone in several dairy cattle breeds were low. The rumen microbial community has been reported to play a significant role in host energy homeostasis and metabolic and physiologic adaptations. The current study aims at investigating the effects of cows' genome and rumen microbial composition on concentrations of acetone and BHB in milk, and identifying specific rumen microbial taxa associated with variation in milk acetone and BHB concentrations. We determined the concentrations of acetone and BHB in milk using nuclear magnetic resonance spectroscopy on morning milk samples collected from 277 Danish Holstein cows. Imputed high-density genotype data were available for these cows. Using genomic and microbial prediction models with a 10-fold resampling strategy, we found that rumen microbial composition explains a larger proportion of the variation in milk concentrations of acetone and BHB than do host genetics. Moreover, we identified associations between milk acetone and BHB with some specific bacterial and archaeal operational taxonomic units previously reported to have low to moderate heritability, presenting an opportunity for genetic improvement. However, higher covariation between specific microbial taxa and milk acetone and BHB concentrations might not necessarily indicate a causal relationship; therefore further validation is needed before considering implementation in selection programs.

Published

2020

2. Host genetics and the rumen microbiome jointly associate with methane emissions in dairy cows

Author

Difford, Gareth Frank, Plichta, Damian Rafal, Løvendahl, Peter, Lassen, Jan, Noel, Samantha Joan, Højberg, Ole, Wright, André-Denis G., Zhu, Zhigang, Kristensen, Lise, Nielsen, Henrik Bjørn, Guldbrandtsen, Bernt, Sahana, Goutam, and Leeb, Tosso

Subjects

0301 basic medicine, Cancer Research, Atmospheric Science, Heredity, Genotype, SDG 13 - Climate Action, Archaeal Taxonomy, Archaean Biology, Genetics (clinical), Data Management, Genetics, Genome, biology, Ecology, Microbiota, food and beverages, Agriculture, 04 agricultural and veterinary sciences, Genomics, Chemistry, Milk, Community Ecology, Medical Microbiology, Physical Sciences, Female, Methane, Research Article, Microbial Taxonomy, Computer and Information Sciences, Rumen, Livestock, lcsh:QH426-470, Microbial Genomics, Animal Breeding and Genomics, Microbiology, 03 medical and health sciences, Greenhouse Gases, Life Science, Animals, Environmental Chemistry, Fokkerij en Genomica, Microbiome, Molecular Biology, Community Structure, Ecology, Evolution, Behavior and Systematics, Taxonomy, Bacteria, Host Microbial Interactions, Host (biology), Ecology and Environmental Sciences, 0402 animal and dairy science, Chemical Compounds, Organisms, Biology and Life Sciences, Heritability, biology.organism_classification, 040201 dairy & animal science, Archaea, lcsh:Genetics, 030104 developmental biology, Atmospheric Chemistry, Earth Sciences, Microbial genetics, Cattle

Abstract

Cattle and other ruminants produce large quantities of methane (~110 million metric tonnes per annum), which is a potent greenhouse gas affecting global climate change. Methane (CH4) is a natural by-product of gastro-enteric microbial fermentation of feedstuffs in the rumen and contributes to 6% of total CH4 emissions from anthropogenic-related sources. The extent to which the host genome and rumen microbiome influence CH4 emission is not yet well known. This study confirms individual variation in CH4 production was influenced by individual host (cow) genotype, as well as the host’s rumen microbiome composition. Abundance of a small proportion of bacteria and archaea taxa were influenced to a limited extent by the host’s genotype and certain taxa were associated with CH4 emissions. However, the cumulative effect of all bacteria and archaea on CH4 production was 13%, the host genetics (heritability) was 21% and the two are largely independent. This study demonstrates variation in CH4 emission is likely not modulated through cow genetic effects on the rumen microbiome. Therefore, the rumen microbiome and cow genome could be targeted independently, by breeding low methane-emitting cows and in parallel, by investigating possible strategies that target changes in the rumen microbiome to reduce CH4 emissions in the cattle industry., Author summary Methane is a potent greenhouse gas and ruminant livestock contribute a substantial amount of total methane from human activities. Variation between cows’ methane production has been found partly due to their genetics (heritable), making genetic selection a promising strategy for breeding low methane emitting cows. We hypothesized that the total methane production by a cow is affected by rumen microbes which are directly responsible for production of methane, as well as the cows’ own genetics and their interaction. We sampled the rumen contents of 750 dairy cows and found the relative abundance of some bacteria and archaea to be heritable and associated with methane production, but the majority of variation in relative abundance of rumen bacteria and archaea is due to non-genetic factors. We compared the amount of variation in methane production associated with host genetics as well as rumen bacteria and archaea and found the host genetics to explain 21% and rumen microbes 13%. Importantly, the two were largely independent of each other, so breeding for low methane emitting cows is unlikely to result in unfavorable changes in the rumen microbiome. However, further functional annotation of rumen microbiota is needed to confirm this. Strategies that target each source of variation can be conducted in parallel to optimize reduction in methane production from dairy cows.

Published

2018

3. 6S rRNA sequence of rumen microbes in dairy cattle

Author

Difford, Gareth, Plichta, Damian Rafal, Løvendahl, Peter, Lassen, Jan, Noel, Samantha Joan, Højberg, Ole, Wright, André Denis G., Zhu, Zhigang, Kristensen, Lise, Nielsen, Henrik Bjørn, Guldbrandtsen, Bernt, Sahana, Goutam, Difford, Gareth, Plichta, Damian Rafal, Løvendahl, Peter, Lassen, Jan, Noel, Samantha Joan, Højberg, Ole, Wright, André Denis G., Zhu, Zhigang, Kristensen, Lise, Nielsen, Henrik Bjørn, Guldbrandtsen, Bernt, and Sahana, Goutam

Abstract

The 16S rRNA sequence data was generated in the project entitled "Reduction of methane emissions from dairy cows and concurrent improvement of feed efficiency obtained through host genetics and next generation sequencing of rumen microbiome" using Illumina sequencing technology.

Published

2018

4. Contamination of the Arctic reflected in microbial metagenomes from the Greenland ice sheet:Letter

Author

Hauptmann, Aviaja Zenia Edna Lyberth, Sicheritz-Pontén, Thomas, Cameron, Karen A., Bælum, Jacob, Plichta, Damian Rafal, Dalgaard, Marlene Danner, Stibal, Marek, Hauptmann, Aviaja Zenia Edna Lyberth, Sicheritz-Pontén, Thomas, Cameron, Karen A., Bælum, Jacob, Plichta, Damian Rafal, Dalgaard, Marlene Danner, and Stibal, Marek

Abstract

Globally emitted contaminants accumulate in the Arctic and are stored in the frozen environments of the cryosphere. Climate change influences the release of these contaminants through elevated melt rates, resulting in increased contamination locally. Our understanding of how biological processes interact with contamination in the Arctic is limited. Through shotgun metagenomic data and binned genomes from metagenomes we show that microbial communities, sampled from multiple surface ice locations on the Greenland ice sheet, have the potential for resistance to and degradation of contaminants. The microbial potential to degrade anthropogenic contaminants, such as toxic and persistent polychlorinated biphenyls, was found to be spatially variable and not limited to regions close to human activities. Binned genomes showed close resemblance to microorganisms isolated from contaminated habitats. These results indicate that, from a microbiological perspective, the Greenland ice sheet cannot be seen as a pristine environment.

Published

2017

5. Transcriptional interactions suggest niche segregation among microorganisms in the human gut

Author

Plichta, Damian Rafal, Juncker, Agnieszka Sierakowska, Bertalan, Marcelo, Rettedal, Elizabeth, Gautier, Laurent, Varela, Encarna, Manichanh, Chaysavanh, Fouqueray, Charlène, Levenez, Florence, Nielsen, Trine, Dore, Joel, Machado, Ana Manuel Dantas, de Evgrafov, Mari Cristina Rodriguez, Hansen, Torben, Jorgensen, Torben, Bork, Peer, Guarner, Francisco, Pedersen, Oluf, Consortium, MetaHit, Sommer, Morten O. A., Ehrlich, S. Dusko, Sicheritz-Ponten, Thomas, Brunak, Soren, Nielsen, H. Bjorn, Almeida, Mathieu, Batto, Jean-Michel, Blottiere, Herve, Cultrone, Antonietta, Delorme, Christine, derwyn, rozenn, Guédon, Eric, Haimet, Florence, Jamet, Alexandre, Juste, Catherine, Kennedy, Sean P., Kaci, Ghalia, Layec, Séverine, Leclerc, Marion, Léonard, Pierre, Maguin, Emmanuelle, Pons, Nicolas, Renault, Pierre, Sanchez, Nicolas, Van De Guchte, Maarten, Van Hylckama Vlieg, Johan, Vandemeulebrouck, Gaetana, Winogradsky, Yohanan, Department of Systems Biology, Center for Biological Sequence Analysis, Technical University of Denmark [Lyngby] (DTU), A/S, Clinical-Microbiomics, Novo Nordisk Foundation Center for Biosustainability, Department of Systems Biology, DTU Multi-Assay Core, Digestive System Research Unit, Vall d'Hebron University Hospital, MetaGenoPolis, Institut National de la Recherche Agronomique (INRA), Novo Nordisk Foundation Center for Basic Metabolic Research (CBMR), Faculty of Health and Medical Sciences, University of Copenhagen = Københavns Universitet (KU)-University of Copenhagen = Københavns Universitet (KU), MICrobiologie de l'ALImentation au Service de la Santé (MICALIS), Institut National de la Recherche Agronomique (INRA)-AgroParisTech, Faculty of Health Sciences, University of Southern Denmark (SDU), Faculty of Medicine, Aalborg University [Denmark] (AAU), Research Centre for Prevention and Health, Capital region, Glostrup University Hospital, University of Copenhagen = Københavns Universitet (KU), European Molecular Biology Laboratory [Hamburg] (EMBL), Centre for Host-Microbiome Interactions, Dental Institute Central Office, Guy’s Hospital, King‘s College London, Disease Systems Biology [Copenhagen], Novo Nordisk Foundation Center for Protein Research (CPR), University of Copenhagen = Københavns Universitet (KU)-University of Copenhagen = Københavns Universitet (KU)-Faculty of Health and Medical Sciences, Clinical Microbiomics, International Human Microbiome Standards [FP7-HEALTH-2010-261376], Metagenopolis [ANR-11-DPBS-0001], Novo Nordisk Foundation, Lundbeck Foundation, European Project: 201052, Vall d'Hebron University Hospital [Barcelona], Génie et Microbiologie des Procédés Alimentaires (GMPA), AgroParisTech-Institut National de la Recherche Agronomique (INRA), Danmarks Tekniske Universitet = Technical University of Denmark (DTU), University of Copenhagen = Københavns Universitet (UCPH)-University of Copenhagen = Københavns Universitet (UCPH), University of Copenhagen = Københavns Universitet (UCPH), and University of Copenhagen = Københavns Universitet (UCPH)-University of Copenhagen = Københavns Universitet (UCPH)-Faculty of Health and Medical Sciences

Subjects

0301 basic medicine, Microbiology (medical), Feces/microbiology, Systems Analysis, ATP-Binding Cassette Transporters/genetics, Denmark, [SDV]Life Sciences [q-bio], Microbial Interactions/genetics, 030106 microbiology, Immunology, Gastrointestinal Microbiome/genetics, Biology, Applied Microbiology and Biotechnology, Microbiology, 03 medical and health sciences, Feces, Microbial ecology, Journal Article, Genetics, Humans, Butyrates/metabolism, Microbiome, Regulation of gene expression, Ecology, Metabolic Networks and Pathways/genetics, Gene Expression Profiling, Niche segregation, Chemotaxis, Cell Biology, Carbon Dioxide, Gastrointestinal Microbiome, Gene expression profiling, Butyrates, 030104 developmental biology, Metagenomics, Spain, Bifidobacterium bifidum/genetics, Metagenome, Microbial Interactions, Carbon Dioxide/metabolism, ATP-Binding Cassette Transporters, Bifidobacterium bifidum, Adaptation, Metabolic Networks and Pathways

Abstract

The human gastrointestinal (GI) tract is the habitat for hundreds of microbial species, of which many cannot be cultivated readily, presumably because of the dependencies between species 1. Studies of microbial co-occurrence in the gut have indicated community substructures that may reflect functional and metabolic interactions between cohabiting species 2,3. To move beyond species co-occurrence networks, we systematically identified transcriptional interactions between pairs of coexisting gut microbes using metagenomics and microarray-based metatranscriptomics data from 233 stool samples from Europeans. In 102 significantly interacting species pairs, the transcriptional changes led to a reduced expression of orthologous functions between the coexisting species. Specific species-species transcriptional interactions were enriched for functions important for H 2 and CO 2 homeostasis, butyrate biosynthesis, ATP-binding cassette (ABC) transporters, flagella assembly and bacterial chemotaxis, as well as for the metabolism of carbohydrates, amino acids and cofactors. The analysis gives the first insight into the microbial community-wide transcriptional interactions, and suggests that the regulation of gene expression plays an important role in species adaptation to coexistence and that niche segregation takes place at the transcriptional level.

Published

2016

6. The impact of the rumen microbiome on the detailed milk fatty acid profile in Danish Holstein cattle

Author

Buitenhuis, Albert Johannes, Poulsen, Nina Aagaard, Noel, Samantha Joan, Plichta, Damian Rafal, and Lassen, Jan

Published

2016

7. Colonic transit time is related to bacterial metabolism and mucosal turnover in the gut

Author

Roager, Henrik Munch, Hansen, Lea Benedicte Skov, Bahl, Martin I, Frandsen, Henrik Lauritz, Carvalho, Vera, Gøbel, Rikke J, Dalgaard, Marlene Danner, Plichta, Damian Rafal, Sparholt, Morten H, Vestergaard, Henrik, Hansen, Torben, Sicheritz-Ponten, Thomas, Nielsen, H Bjørn, Pedersen, Oluf, Lauritzen, Lotte, Kristensen, Mette Bredal, Gupta, Ramneek, Licht, Tine R, Roager, Henrik Munch, Hansen, Lea Benedicte Skov, Bahl, Martin I, Frandsen, Henrik Lauritz, Carvalho, Vera, Gøbel, Rikke J, Dalgaard, Marlene Danner, Plichta, Damian Rafal, Sparholt, Morten H, Vestergaard, Henrik, Hansen, Torben, Sicheritz-Ponten, Thomas, Nielsen, H Bjørn, Pedersen, Oluf, Lauritzen, Lotte, Kristensen, Mette Bredal, Gupta, Ramneek, and Licht, Tine R

Abstract

Little is known about how colonic transit time relates to human colonic metabolism and its importance for host health, although a firm stool consistency, a proxy for a long colonic transit time, has recently been positively associated with gut microbial richness. Here, we show that colonic transit time in humans, assessed using radio-opaque markers, is associated with overall gut microbial composition, diversity and metabolism. We find that a long colonic transit time associates with high microbial richness and is accompanied by a shift in colonic metabolism from carbohydrate fermentation to protein catabolism as reflected by higher urinary levels of potentially deleterious protein-derived metabolites. Additionally, shorter colonic transit time correlates with metabolites possibly reflecting increased renewal of the colonic mucosa. Together, this suggests that a high gut microbial richness does not per se imply a healthy gut microbial ecosystem and points at colonic transit time as a highly important factor to consider in microbiome and metabolomics studies.

Published

2016

8. Colonic transit time is related to bacterial metabolism and mucosal turnover in the human gut

Author

Roager, Henrik Munch, Hansen, Lea Benedicte Skov, Bahl, Martin Iain, Frandsen, Henrik Lauritz, Carvalho, Vera, Gøbel, Rikke J., Dalgaard, Marlene Danner, Plichta, Damian Rafal, Sparholt, Morten, Vestergaard, Henrik, Hansen, Torben, Sicheritz-Pontén, Thomas, Nielsen, Henrik Bjørn, Pedersen, Oluf, Lauritzen, Lotte, Kristensen, Mette, Licht, Tine Rask, Roager, Henrik Munch, Hansen, Lea Benedicte Skov, Bahl, Martin Iain, Frandsen, Henrik Lauritz, Carvalho, Vera, Gøbel, Rikke J., Dalgaard, Marlene Danner, Plichta, Damian Rafal, Sparholt, Morten, Vestergaard, Henrik, Hansen, Torben, Sicheritz-Pontén, Thomas, Nielsen, Henrik Bjørn, Pedersen, Oluf, Lauritzen, Lotte, Kristensen, Mette, and Licht, Tine Rask

Abstract

Little is known about how colonic transit time relates to human colonic metabolism, and its importance for host health, although stool consistency, a proxy for colonic transit time, has recently been negatively associated with gut microbial richness. To address the relationships between colonic transit time and the gut microbial composition and metabolism, we assessed the colonic transit time of 98 subjects using radiopaque markers, and profiled their gut microbiota by16S rRNA gene sequencing and their urine metabolome by ultra performance liquid chromatography mass spectrometry. Based on correlation analyses, we show that colonic transit time is associated with overall gut microbial composition, diversity and metabolism. A relatively prolonged colonic transit time associates with high microbial species richness and a shift in colonic metabolism from carbohydrate fermentation to protein catabolism as reflected by higher urinary levels of potentially deleterious protein-derived metabolites. Additionally, shorter colonic transit time correlates with metabolites likely reflecting increased renewal of the colonic mucosa. Together, this suggests that a high gut microbial richness does not per se imply a healthy gut microbial ecosystem and points at colonic transit time as a highly important factor to consider in microbiome and metabolomics studies.

Published

2016

9. Identification and assembly of genomes and genetic elements in complex metagenomic samples without using reference genomes

Author

Nielsen, H Bjørn, Almeida, Mathieu, Juncker, Agnieszka, Rasmussen, Simon, Li, Junhua, Sunagawa, Shinichi, Plichta, Damian Rafal, Gautier, Laurent, Pedersen, Anders G., Le Chatelier, Emmanuelle, Pelletier, Eric, Bonde, Ida, Nielsen, Trine, Manichanh, Chaysavanh, Arumugam, Manimozhiyan, Batto, Jean-Michel, dos Santos, Marcelo Bertalan Quintanilha, Blom, Nikolaj, Borruel, Natalia, Burgdorf, Kristoffer Sølvsten, Boumezbeur, Fouad, Casellas, Francesc, Doré, Joël, Dworzynski, Piotr, Guarner, Francisco, Hansen, Torben, Hildebrand, Falk, Kaas, Rolf Sommer, Kennedy, Sean, Kristiansen, Karsten, Kultima, Jens Roat, Léonard, Pierre, Levenez, Florence, Lund, Ole, Moumen, Bouziane, Le Paslier, Denis, Pons, Nicolas, Pedersen, Oluf Borbye, Prifti, Edi, Qin, Junjie, Raes, Jeroen, Sørensen, Søren Johannes, Tap, Julien, Tims, Sebastian, Ussery, David, Yamada, Takuji, Renault, Pierre, Sicheritz-Pontén, Thomas, Bork, Peer, Wang, Jun, Nielsen, H Bjørn, Almeida, Mathieu, Juncker, Agnieszka, Rasmussen, Simon, Li, Junhua, Sunagawa, Shinichi, Plichta, Damian Rafal, Gautier, Laurent, Pedersen, Anders G., Le Chatelier, Emmanuelle, Pelletier, Eric, Bonde, Ida, Nielsen, Trine, Manichanh, Chaysavanh, Arumugam, Manimozhiyan, Batto, Jean-Michel, dos Santos, Marcelo Bertalan Quintanilha, Blom, Nikolaj, Borruel, Natalia, Burgdorf, Kristoffer Sølvsten, Boumezbeur, Fouad, Casellas, Francesc, Doré, Joël, Dworzynski, Piotr, Guarner, Francisco, Hansen, Torben, Hildebrand, Falk, Kaas, Rolf Sommer, Kennedy, Sean, Kristiansen, Karsten, Kultima, Jens Roat, Léonard, Pierre, Levenez, Florence, Lund, Ole, Moumen, Bouziane, Le Paslier, Denis, Pons, Nicolas, Pedersen, Oluf Borbye, Prifti, Edi, Qin, Junjie, Raes, Jeroen, Sørensen, Søren Johannes, Tap, Julien, Tims, Sebastian, Ussery, David, Yamada, Takuji, Renault, Pierre, Sicheritz-Pontén, Thomas, Bork, Peer, and Wang, Jun

Abstract

Most current approaches for analyzing metagenomic data rely on comparisons to reference genomes, but the microbial diversity of many environments extends far beyond what is covered by reference databases. De novo segregation of complex metagenomic data into specific biological entities, such as particular bacterial strains or viruses, remains a largely unsolved problem. Here we present a method, based on binning co-abundant genes across a series of metagenomic samples, that enables comprehensive discovery of new microbial organisms, viruses and co-inherited genetic entities and aids assembly of microbial genomes without the need for reference sequences. We demonstrate the method on data from 396 human gut microbiome samples and identify 7,381 co-abundance gene groups (CAGs), including 741 metagenomic species (MGS). We use these to assemble 238 high-quality microbial genomes and identify affiliations between MGS and hundreds of viruses or genetic entities. Our method provides the means for comprehensive profiling of the diversity within complex metagenomic samples.

Published

2014

10. Mapping the genome of Plasmodium falciparum on the drug-like chemical space reveals novel anti-malarial targets and potential drug leads

Author

Jensen, Kasper, Plichta, Damian Rafal, Panagiotou, Gianni, Kouskoumvekaki, Irene, Jensen, Kasper, Plichta, Damian Rafal, Panagiotou, Gianni, and Kouskoumvekaki, Irene

Abstract

The parasite Plasmodium falciparum is the main agent responsible for malaria. In this study, we exploited a recently published chemical library from GlaxoSmithKline (GSK) that had previously been confirmed to inhibit parasite growth of the wild type (3D7) and the multi-drug resistance (D2d) strains, in order to uncover the weak links in the proteome of the parasite. We predicted 293 proteins of P. falciparum, including the six out of the seven verified targets for P. falciparum malaria treatment, as targets of 4645 GSK active compounds. Furthermore, we prioritized druggable targets, based on a number of factors, such as essentiality for growth, lack of homology with human proteins, and availability of experimental data on ligand activity with a non-human homologue of a parasite protein. We have additionally prioritized predicted ligands based on their polypharmacology profile, with focus on validated essential proteins and the effect of their perturbations on the metabolic network of P. falciparum, as well as indication of drug resistance emergence. Finally, we predict potential off-target effects on the human host with associations to cancer, neurological and dermatological disorders, based on integration of available chemical-protein and protein-protein interaction data. Our work suggests that a large number of the P. falciparum proteome is potentially druggable and could therefore serve as novel drug targets in the fight against malaria. At the same time, prioritized compounds from the GSK library could serve as lead compounds to medicinal chemists for further optimization.

Published

2012

11. Plichta, Damian Rafal

Author

Plichta, Damian Rafal and Plichta, Damian Rafal

Published

2012

12. Transcriptional interactions suggest niche segregation among microorganisms in the human gut.

Author

Plichta DR, Juncker AS, Bertalan M, Rettedal E, Gautier L, Varela E, Manichanh C, Fouqueray C, Levenez F, Nielsen T, Doré J, Machado AM, de Evgrafov MC, Hansen T, Jørgensen T, Bork P, Guarner F, Pedersen O, Sommer MO, Ehrlich SD, Sicheritz-Pontén T, Brunak S, and Nielsen HB

Subjects

ATP-Binding Cassette Transporters genetics, Bifidobacterium bifidum genetics, Bifidobacterium bifidum metabolism, Butyrates metabolism, Carbon Dioxide metabolism, Denmark, Feces microbiology, Gastrointestinal Microbiome physiology, Humans, Metabolic Networks and Pathways genetics, Spain, Systems Analysis, Gastrointestinal Microbiome genetics, Gene Expression Profiling, Metagenome, Microbial Interactions genetics, Microbial Interactions physiology

Abstract

The human gastrointestinal (GI) tract is the habitat for hundreds of microbial species, of which many cannot be cultivated readily, presumably because of the dependencies between species 1 . Studies of microbial co-occurrence in the gut have indicated community substructures that may reflect functional and metabolic interactions between cohabiting species 2,3 . To move beyond species co-occurrence networks, we systematically identified transcriptional interactions between pairs of coexisting gut microbes using metagenomics and microarray-based metatranscriptomics data from 233 stool samples from Europeans. In 102 significantly interacting species pairs, the transcriptional changes led to a reduced expression of orthologous functions between the coexisting species. Specific species-species transcriptional interactions were enriched for functions important for H 2 and CO 2 homeostasis, butyrate biosynthesis, ATP-binding cassette (ABC) transporters, flagella assembly and bacterial chemotaxis, as well as for the metabolism of carbohydrates, amino acids and cofactors. The analysis gives the first insight into the microbial community-wide transcriptional interactions, and suggests that the regulation of gene expression plays an important role in species adaptation to coexistence and that niche segregation takes place at the transcriptional level.

Published

2016