Quantifying bacterial spore germination by single-cell impedance cytometry for assessment of host microbiota susceptibility to Clostridioides difficile infection.

The germination of ingested spores is often a necessary first step required for enabling bacterial outgrowth and host colonization, as in the case of Clostridioides difficile (C. difficile) infection. Spore germination rate in the colon depends on microbiota composition and its level of disruption by antibiotic treatment since secretions by commensal bacteria modulate primary to secondary bile salt levels to control germination. Assessment of C. difficile spore germination typically requires measurement of colony-forming units, which is labor intensive and takes at least 24 h to perform but is regularly required due to the high recurrence rates of nosocomial antibiotic-associated diarrhea. We present a rapid method to assess spore germination by using high throughput single-cell impedance cytometry (>300 events/s) to quantify live bacterial cells, by gating for their characteristic electrophysiology versus spores, so that germination can be assessed after just 4 h of culture at a detection limit of ~100 live cells per 50 μL sample. To detect the phenotype of germinated C. difficile bacteria, we utilize its characteristically higher net conductivity versus that of spore aggregates and non-viable C. difficile forms, which causes a distinctive high-frequency (10 MHz) impedance phase dispersion within moderately conductive media (0.8 S/m). In this manner, we can detect significant differences in spore germination rates within just 4 h, with increasing primary bile salt levels in vitro and using ex vivo microbiota samples from an antibiotic-treated mouse model to assess susceptibility to C. difficile infection. We envision a rapid diagnostic tool for assessing host microbiota susceptibility to bacterial colonization after key antibiotic treatments.

[1]  Paolo Bisegna,et al.  A neural network approach for real-time particle/cell characterization in microfluidic impedance cytometry , 2020, Analytical and Bioanalytical Chemistry.

[2]  C. Donskey,et al.  Vegetative Clostridium difficile Survives in Room Air on Moist Surfaces and in Gastric Contents with Reduced Acidity: a Potential Mechanism To Explain the Association between Proton Pump Inhibitors and C. difficile-Associated Diarrhea? , 2007, Antimicrobial Agents and Chemotherapy.

[3]  J. Bartlett,et al.  Biology of Clostridium difficile: implications for epidemiology and diagnosis. , 2011, Annual review of microbiology.

[4]  Winnie E. Svendsen,et al.  Bacteria Detection and Differentiation Using Impedance Flow Cytometry , 2018, Sensors.

[5]  W. D. de Vos,et al.  Gut microbiota composition and Clostridium difficile infection in hospitalized elderly individuals: a metagenomic study , 2016, Scientific Reports.

[6]  Alexander J. Probst,et al.  An in vitro culture model to study the dynamics of colonic microbiota in Syrian golden hamsters and their susceptibility to infection with Clostridium difficile , 2014, The ISME Journal.

[7]  Yi Wang,et al.  A microfluidic impedance flow cytometer for identification of differentiation state of stem cells. , 2013, Lab on a chip.

[8]  S. Foster,et al.  Peptidoglycan Structural Dynamics during Germination of Bacillus subtilis 168 Endospores , 1998, Journal of bacteriology.

[9]  Peter R. C. Gascoyne,et al.  Correlations between the dielectric properties and exterior morphology of cells revealed by dielectrophoretic field‐flow fractionation , 2013, Electrophoresis.

[10]  C. Surawicz,et al.  Treatment of refractory and recurrent Clostridium difficile infection , 2011, Nature Reviews Gastroenterology &Hepatology.

[11]  Elena Bianchi,et al.  Label-free identification of activated T lymphocytes through tridimensional microsensors on chip. , 2017, Biosensors & bioelectronics.

[12]  Cirle A. Warren,et al.  Rapid in vitro assessment of Clostridioides difficile inhibition by probiotics using dielectrophoresis to quantify cell structure alterations. , 2020, ACS infectious diseases.

[13]  Nathan S Swami,et al.  Conductance-based biophysical distinction and microfluidic enrichment of nano-vesicles derived from pancreatic tumor cells of varying invasiveness. , 2019, Analytical chemistry.

[14]  A. Lee,et al.  Cell Surface N-Glycans Influence Electrophysiological Properties and Fate Potential of Neural Stem Cells , 2018, Stem cell reports.

[15]  A. Sonenshein,et al.  Bile Salts and Glycine as Cogerminants for Clostridium difficile Spores , 2008, Journal of bacteriology.

[16]  Yi-Hsuan Su,et al.  Single-cell electro-phenotyping for rapid assessment of Clostridium difficile heterogeneity under vancomycin treatment at sub-MIC (minimum inhibitory concentration) levels. , 2018, Sensors and actuators. B, Chemical.

[17]  Lan Huang,et al.  Structure of the full-length Clostridium difficile toxin B , 2019, Nature Structural & Molecular Biology.

[18]  N. Swami,et al.  Electrophysiology-based stratification of pancreatic tumorigenicity by label-free single-cell impedance cytometry. , 2020, Analytica chimica acta.

[19]  Nathan S Swami,et al.  Label-Free Quantification of Intracellular Mitochondrial Dynamics Using Dielectrophoresis , 2017, Analytical chemistry.

[20]  Yi-Hsuan Su,et al.  Dielectrophoretic Monitoring and Interstrain Separation of Intact Clostridium difficile Based on Their S(Surface)-Layers , 2014, Analytical chemistry.

[21]  Federica Caselli,et al.  High accuracy particle analysis using sheathless microfluidic impedance cytometry. , 2016, Lab on a chip.

[22]  Amber Howerton,et al.  A new strategy for the prevention of Clostridium difficile infection. , 2013, The Journal of infectious diseases.

[23]  Lisa G Winston,et al.  Burden of Clostridium difficile Infection in the United States , 2015 .

[24]  S. Gawad,et al.  Single cell dielectric spectroscopy , 2007 .

[25]  Alyxandria M. Schubert,et al.  Germinant Synergy Facilitates Clostridium difficile Spore Germination under Physiological Conditions , 2018, mSphere.

[26]  R. Ley,et al.  Ecological and Evolutionary Forces Shaping Microbial Diversity in the Human Intestine , 2006, Cell.

[27]  A. Shen,et al.  The Conserved Spore Coat Protein SpoVM Is Largely Dispensable in Clostridium difficile Spore Formation , 2017, mSphere.

[28]  Hywel Morgan,et al.  Micro-impedance cytometry for detection and analysis of micron-sized particles and bacteria. , 2011, Lab on a chip.

[29]  Federica Caselli,et al.  High-throughput label-free characterization of viable, necrotic and apoptotic human lymphoma cells in a coplanar-electrode microfluidic impedance chip. , 2019, Biosensors & bioelectronics.

[30]  D. Relman,et al.  Clostridium difficile, Aging, and the Gut: Can Microbiome Rejuvenation Keep Us Young and Healthy? , 2018, The Journal of infectious diseases.

[31]  H. A. Pohl The Motion and Precipitation of Suspensoids in Divergent Electric Fields , 1951 .

[32]  Yi-Hsuan Su,et al.  Quantifying spatio-temporal dynamics of biomarker pre-concentration and depletion in microfluidic systems by intensity threshold analysis. , 2014, Biomicrofluidics.

[33]  Vincent B. Young,et al.  Antibiotic-Associated Diarrhea Accompanied by Large-Scale Alterations in the Composition of the Fecal Microbiota , 2004, Journal of Clinical Microbiology.

[34]  Stuart Johnson Recurrent Clostridium difficile infection: a review of risk factors, treatments, and outcomes. , 2009, The Journal of infection.

[35]  N. Swami,et al.  Review: Microbial analysis in dielectrophoretic microfluidic systems. , 2017, Analytica chimica acta.

[36]  L. Ranford-Cartwright,et al.  Dielectric characterization of Plasmodium falciparum-infected red blood cells using microfluidic impedance cytometry , 2018, Journal of The Royal Society Interface.

[37]  H. Bridle,et al.  Analysis of Parasitic Protozoa at the Single-cell Level using Microfluidic Impedance Cytometry , 2017, Scientific Reports.

[38]  J. Auchtung,et al.  Control of Clostridium difficile Infection by Defined Microbial Communities , 2017, Microbiology spectrum.

[39]  Hywel Morgan,et al.  AC ELECTROKINETICS: COLLOIDS AND NANOPARTICLES. , 2002 .

[40]  M. H. Foley,et al.  Updates to Clostridium difficile Spore Germination , 2018, Journal of bacteriology.

[41]  K. Garey,et al.  Economic burden of primary compared with recurrent Clostridium difficile infection in hospitalized patients: a prospective cohort study. , 2016, The Journal of hospital infection.

[42]  D. Gerding,et al.  Clinical Practice Guidelines for Clostridium difficile Infection in Adults: 2010 Update by the Society for Healthcare Epidemiology of America (SHEA) and the Infectious Diseases Society of America (IDSA) , 2010, Infection Control & Hospital Epidemiology.

[43]  Andreas Hierlemann,et al.  Resonance-enhanced microfluidic impedance cytometer for detection of single bacteria. , 2014, Lab on a chip.

[44]  V. Young,et al.  Interactions Between the Gastrointestinal Microbiome and Clostridium difficile. , 2015, Annual review of microbiology.

[45]  P. Eichenberger,et al.  The Spore Coat. , 2016, Microbiology spectrum.

[46]  P. Brigidi,et al.  Through Ageing, and Beyond: Gut Microbiota and Inflammatory Status in Seniors and Centenarians , 2010, PloS one.

[47]  L. Klobutcher,et al.  The Bacillus subtilis spore coat provides "eat resistance" during phagocytic predation by the protozoan Tetrahymena thermophila. , 2006, Proceedings of the National Academy of Sciences of the United States of America.

[48]  Yi-Hsuan Su,et al.  Tracking Inhibitory Alterations during Interstrain Clostridium difficile Interactions by Monitoring Cell Envelope Capacitance , 2016, ACS infectious diseases.

[49]  Nathan S Swami,et al.  Electrical tweezer for highly parallelized electrorotation measurements over a wide frequency bandwidth , 2014, Electrophoresis.

[50]  Amber Howerton,et al.  Mapping Interactions between Germinants and Clostridium difficile Spores , 2010, Journal of bacteriology.

[51]  Robbyn K. Anand,et al.  High-Throughput Selective Capture of Single Circulating Tumor Cells by Dielectrophoresis at a Wireless Electrode Array. , 2017, Journal of the American Chemical Society.

[52]  N. Fairweather,et al.  Functional Characterization of Clostridium difficile Spore Coat Proteins , 2013, Journal of bacteriology.

[53]  D. Lacy,et al.  Intestinal bile acids directly modulate the structure and function of C. difficile TcdB toxin , 2020, Proceedings of the National Academy of Sciences.

[54]  Michael R Hamblin,et al.  Clostridium difficile infection: molecular pathogenesis and novel therapeutics , 2014, Expert review of anti-infective therapy.

[55]  J. L. Giel,et al.  Metabolism of Bile Salts in Mice Influences Spore Germination in Clostridium difficile , 2010, PloS one.

[56]  M. Hayes,et al.  Isolation and identification of Listeria monocytogenes utilizing DC insulator-based dielectrophoresis. , 2019, Analytica chimica acta.

[57]  D. Paredes-Sabja,et al.  Clostridium difficile spore biology: sporulation, germination, and spore structural proteins. , 2014, Trends in microbiology.

[58]  R. Pethig Review article-dielectrophoresis: status of the theory, technology, and applications. , 2010, Biomicrofluidics.

[59]  V. Quagliarello,et al.  The Microbiota and Microbiome in Aging: Potential Implications in Health and Age‐Related Diseases , 2015, Journal of the American Geriatrics Society.

[60]  J. Bartlett Clostridium difficile: Old and New Observations , 2007 .

[61]  David A Burns,et al.  Sporulation studies in Clostridium difficile. , 2011, Journal of microbiological methods.

[62]  Thomas B. Jones,et al.  Electromechanics of Particles , 1995 .

[63]  Patrick D. Schloss,et al.  Microbiome Data Distinguish Patients with Clostridium difficile Infection and Non-C. difficile-Associated Diarrhea from Healthy Controls , 2014, mBio.