Swimming motility of a gut bacterial symbiont promotes resistance to intestinal expulsion and enhances inflammation

Some of the densest microbial ecosystems in nature thrive within the intestines of humans and other animals. To protect mucosal tissues and maintain immune tolerance, animal hosts actively sequester bacteria within the intestinal lumen. In response, numerous bacterial pathogens and pathobionts have evolved strategies to subvert spatial restrictions, thereby undermining immune homeostasis. However, in many cases, it is unclear how escaping host spatial control benefits gut bacteria and how changes in intestinal biogeography are connected to inflammation. A better understanding of these processes could uncover new targets for treating microbiome-mediated inflammatory diseases. To this end, we investigated the spatial organization and dynamics of bacterial populations within the intestine using larval zebrafish and live imaging. We discovered that a proinflammatory Vibrio symbiont native to zebrafish governs its own spatial organization using swimming motility and chemotaxis. Surprisingly, we found that Vibrio’s motile behavior does not enhance its growth rate but rather promotes its persistence by enabling it to counter intestinal flow. In contrast, Vibrio mutants lacking motility traits surrender to host spatial control, becoming aggregated and entrapped within the lumen. Consequently, nonmotile and nonchemotactic mutants are susceptible to intestinal expulsion and experience large fluctuations in absolute abundance. Further, we found that motile Vibrio cells induce expression of the proinflammatory cytokine tumor necrosis factor alpha (TNFα) in gut-associated macrophages and the liver. Using inducible genetic switches, we demonstrate that swimming motility can be manipulated in situ to modulate the spatial organization, persistence, and inflammatory activity of gut bacterial populations. Together, our findings suggest that host spatial control over resident microbiota plays a broader role in regulating the abundance and persistence of gut bacteria than simply protecting mucosal tissues. Moreover, we show that intestinal flow and bacterial motility are potential targets for therapeutically managing bacterial spatial organization and inflammatory activity within the gut.

[1]  B. Finlay,et al.  Common themes in microbial pathogenicity , 1989, Microbiological reviews.

[2]  M. Westerfield The zebrafish book : a guide for the laboratory use of zebrafish (Danio rerio) , 1995 .

[3]  P. Limburg,et al.  In vivo IgA coating of anaerobic bacteria in human faeces. , 1996, Gut.

[4]  H. Bujard,et al.  Independent and tight regulation of transcriptional units in Escherichia coli via the LacR/O, the TetR/O and AraC/I1-I2 regulatory elements. , 1997, Nucleic acids research.

[5]  Jeff F. Miller,et al.  Roles for motility in bacterial–host interactions , 1997, Molecular microbiology.

[6]  K. Hammer,et al.  The Sequence of Spacers between the Consensus Sequences Modulates the Strength of Prokaryotic Promoters , 1998, Applied and Environmental Microbiology.

[7]  Jean-Christophe Olivo-Marin,et al.  Extraction of spots in biological images using multiscale products , 2002, Pattern Recognit..

[8]  J. Madara,et al.  Flagellin Is the Major Proinflammatory Determinant of Enteropathogenic Salmonella1 , 2003, The Journal of Immunology.

[9]  Vladimir Kolmogorov,et al.  An Experimental Comparison of Min-Cut/Max-Flow Algorithms for Energy Minimization in Vision , 2004, IEEE Trans. Pattern Anal. Mach. Intell..

[10]  B. Stecher,et al.  Flagella and Chemotaxis Are Required for Efficient Induction of Salmonella enterica Serovar Typhimurium Colitis in Streptomycin-Pretreated Mice , 2004, Infection and Immunity.

[11]  H. Lochs,et al.  Spatial Organization and Composition of the Mucosal Flora in Patients with Inflammatory Bowel Disease , 2005, Journal of Clinical Microbiology.

[12]  V. Pachnis,et al.  Enteric nervous system development and Hirschsprung's disease: advances in genetic and stem cell studies , 2007, Nature Reviews Neuroscience.

[13]  B. Lacy,et al.  Small intestinal bacterial overgrowth: a comprehensive review. , 2007, Gastroenterology & hepatology.

[14]  M. Vaneechoutte,et al.  Viscosity gradient within the mucus layer determines the mucosal barrier function and the spatial organization of the intestinal microbiota , 2007, Inflammatory bowel diseases.

[15]  W. Rabsch,et al.  Motility allows S. Typhimurium to benefit from the mucosal defence , 2008, Cellular microbiology.

[16]  M. Waldor,et al.  Reactogenicity of live-attenuated Vibrio cholerae vaccines is dependent on flagellins , 2010, Proceedings of the National Academy of Sciences.

[17]  Z. Gong,et al.  Morphological and molecular evidence for functional organization along the rostrocaudal axis of the adult zebrafish intestine , 2010, BMC Genomics.

[18]  B. Levin,et al.  The population dynamics of bacteria in physically structured habitats and the adaptive virtue of random motility , 2011, Proceedings of the National Academy of Sciences.

[19]  S. Mazmanian,et al.  Pathobionts of the gastrointestinal microbiota and inflammatory disease. , 2011, Current opinion in immunology.

[20]  R. Ley,et al.  The Antibacterial Lectin RegIIIγ Promotes the Spatial Segregation of Microbiota and Host in the Intestine , 2011, Science.

[21]  A. Andrianopoulos,et al.  mpeg1 promoter transgenes direct macrophage-lineage expression in zebrafish. , 2011, Blood.

[22]  K. Guillemin,et al.  Study of host-microbe interactions in zebrafish. , 2011, Methods in cell biology.

[23]  R. Vance,et al.  Lethal inflammasome activation by a multi-drug resistant pathobiont upon antibiotic disruption of the microbiota , 2012, Nature Medicine.

[24]  Christopher A. Voigt,et al.  Ribozyme-based insulator parts buffer synthetic circuits from genetic context , 2012, Nature Biotechnology.

[25]  Johannes E. Schindelin,et al.  Fiji: an open-source platform for biological-image analysis , 2012, Nature Methods.

[26]  R. Parthasarathy Rapid, accurate particle tracking by calculation of radial symmetry centers , 2012, Nature Methods.

[27]  William A. Walters,et al.  Transient inability to manage proteobacteria promotes chronic gut inflammation in TLR5-deficient mice. , 2012, Cell host & microbe.

[28]  L. T. Angenent,et al.  Innate and adaptive immunity interact to quench microbiome flagellar motility in the gut. , 2013, Cell host & microbe.

[29]  A. Huttenlocher,et al.  Heat Shock Modulates Neutrophil Motility in Zebrafish , 2013, PloS one.

[30]  M. Johansson,et al.  The gastrointestinal mucus system in health and disease , 2013, Nature Reviews Gastroenterology &Hepatology.

[31]  Luke A. Gilbert,et al.  Repurposing CRISPR as an RNA-Guided Platform for Sequence-Specific Control of Gene Expression , 2013, Cell.

[32]  R. Parthasarathy,et al.  Spatial and Temporal Features of the Growth of a Bacterial Species Colonizing the Zebrafish Gut , 2014, mBio.

[33]  Otto X. Cordero,et al.  Competition–dispersal tradeoff ecologically differentiates recently speciated marine bacterioplankton populations , 2014, Proceedings of the National Academy of Sciences.

[34]  M. Waldor,et al.  Insights into Vibrio cholerae Intestinal Colonization from Monitoring Fluorescently Labeled Bacteria , 2014, PLoS pathogens.

[35]  E. Ruby,et al.  A model symbiosis reveals a role for sheathed-flagellum rotation in the release of immunogenic lipopolysaccharide , 2014, eLife.

[36]  A. Kostic,et al.  The microbiome in inflammatory bowel disease: current status and the future ahead. , 2014, Gastroenterology.

[37]  Se Jin Song,et al.  The treatment-naive microbiome in new-onset Crohn's disease. , 2014, Cell host & microbe.

[38]  N. Katsanis,et al.  Epigenetic control of intestinal barrier function and inflammation in zebrafish , 2015, Proceedings of the National Academy of Sciences.

[39]  M. Beeby,et al.  The flagellum in bacterial pathogens: For motility and a whole lot more. , 2015, Seminars in cell & developmental biology.

[40]  A. Gosain,et al.  Hirschsprung's associated enterocolitis , 2015, Current opinion in pediatrics.

[41]  B. Bohannan,et al.  Individual Members of the Microbiota Disproportionately Modulate Host Innate Immune Responses. , 2015, Cell host & microbe.

[42]  K. Foster,et al.  Adhesion as a weapon in microbial competition , 2014, The ISME Journal.

[43]  S. Setayeshgar,et al.  Diffusion of Bacterial Cells in Porous Media. , 2016, Biophysical journal.

[44]  J. Raes,et al.  Population-level analysis of gut microbiome variation , 2016, Science.

[45]  T. R. Licht,et al.  Colonic transit time is related to bacterial metabolism and mucosal turnover in the gut , 2016, Nature Microbiology.

[46]  J. Eisen,et al.  Host Gut Motility Promotes Competitive Exclusion within a Model Intestinal Microbiota , 2016, PLoS biology.

[47]  Fabian Rivera-Chávez,et al.  Energy Taxis toward Host-Derived Nitrate Supports a Salmonella Pathogenicity Island 1-Independent Mechanism of Invasion , 2016, mBio.

[48]  R. Lamont,et al.  Dancing with the Stars: How Choreographed Bacterial Interactions Dictate Nososymbiocity and Give Rise to Keystone Pathogens, Accessory Pathogens, and Pathobionts. , 2016, Trends in microbiology.

[49]  John T. Sauls,et al.  Effect of flow and peristaltic mixing on bacterial growth in a gut-like channel , 2016, Proceedings of the National Academy of Sciences.

[50]  S. Mazmanian,et al.  Gut biogeography of the bacterial microbiota , 2015, Nature Reviews Microbiology.

[51]  E. Ruby,et al.  Rotation of Vibrio fischeri Flagella Produces Outer Membrane Vesicles That Induce Host Development , 2016, Journal of bacteriology.

[52]  K. Takeda,et al.  Lypd8 promotes the segregation of flagellated microbiota and colonic epithelia , 2016, Nature.

[53]  I. Amit,et al.  Microbiota Diurnal Rhythmicity Programs Host Transcriptome Oscillations , 2016, Cell.

[54]  B. Bohannan,et al.  The composition of the zebrafish intestinal microbial community varies across development , 2015, The ISME Journal.

[55]  K. Foster,et al.  Host Selection of Microbiota via Differential Adhesion. , 2016, Cell host & microbe.

[56]  S. Keely,et al.  Microbial colonization is required for normal neurobehavioral development in zebrafish , 2017, Scientific Reports.

[57]  K. Foster,et al.  The evolution of the host microbiome as an ecosystem on a leash , 2017, Nature.

[58]  C. Tropini,et al.  The Gut Microbiome: Connecting Spatial Organization to Function. , 2017, Cell host & microbe.

[59]  J. Eisen,et al.  The enteric nervous system promotes intestinal health by constraining microbiota composition , 2017, PLoS biology.

[60]  J. Eisen,et al.  Best practices for germ-free derivation and gnotobiotic zebrafish husbandry. , 2017, Methods in cell biology.

[61]  I-Min A. Chen,et al.  IMG/M: integrated genome and metagenome comparative data analysis system , 2016, Nucleic Acids Res..

[62]  G. Borisy,et al.  Spatial organization of a model 15-member human gut microbiota established in gnotobiotic mice , 2017, Proceedings of the National Academy of Sciences.

[63]  B. Bohannan,et al.  Interhost dispersal alters microbiome assembly and can overwhelm host innate immunity in an experimental zebrafish model , 2017, Proceedings of the National Academy of Sciences.

[64]  T. Furey,et al.  Genomic dissection of conserved transcriptional regulation in intestinal epithelial cells , 2017, PLoS biology.

[65]  R. Stocker,et al.  High-avidity IgA protects the intestine by enchaining growing bacteria , 2017, Nature.

[66]  R. Knight,et al.  Gut microbiota utilize immunoglobulin A for mucosal colonization , 2018, Science.

[67]  F. Bäckhed,et al.  Neonatal selection by Toll-like receptor 5 influences long-term gut microbiota composition , 2018, Nature.

[68]  R. Parthasarathy Monitoring microbial communities using light sheet fluorescence microscopy. , 2018, Current opinion in microbiology.

[69]  J. Eisen,et al.  Image velocimetry and spectral analysis enable quantitative characterization of larval zebrafish gut motility , 2017, bioRxiv.

[70]  K. Guillemin,et al.  A bacterial immunomodulatory protein with lipocalin-like domains facilitates host–bacteria mutualism in larval zebrafish , 2018, eLife.

[71]  B. Bohannan,et al.  Experimental bacterial adaptation to the zebrafish gut reveals a primary role for immigration , 2018, PLoS biology.

[72]  Sandy R. Pernitzsch,et al.  Healthy hosts rule within: ecological forces shaping the gut microbiota , 2018, Mucosal Immunology.

[73]  R. Parthasarathy,et al.  Modernized Tools for Streamlined Genetic Manipulation and Comparative Study of Wild and Diverse Proteobacterial Lineages , 2018, mBio.

[74]  R. Parthasarathy,et al.  Bacterial cohesion predicts spatial distribution in the larval zebrafish intestine , 2018, bioRxiv.

[75]  R. Parthasarathy,et al.  Sublethal antibiotics collapse gut bacterial populations by enhancing aggregation and expulsion , 2019, Proceedings of the National Academy of Sciences.

[76]  R. Stocker,et al.  The role of microbial motility and chemotaxis in symbiosis , 2019, Nature Reviews Microbiology.

[77]  B. Bohannan,et al.  Scales of persistence: transmission and the microbiome. , 2019, Current opinion in microbiology.

[78]  Wael Elhenawy,et al.  Host-Specific Adaptive Diversification of Crohn's Disease-Associated Adherent-Invasive Escherichia coli. , 2019, Cell host & microbe.