scholarly journals The requirement for the amino acid co-germinant duringC. difficilespore germination is influenced by mutations inyabGandcspA

2018 ◽  
Author(s):  
Ritu Shrestha ◽  
Joseph A. Sorg
Keyword(s):  
Amino Acids ◽  
Bile Acid ◽  
Amino Acid ◽  
Clostridium Difficile ◽  
Cholic Acid ◽  
Spore Germination ◽  
Ems Mutagenesis ◽  
Bile Acid Receptor ◽  
Transmission Of Disease ◽  
Cholic Acid Derivatives

AbstractClostridium difficilespore germination is critical for the transmission of disease.C. difficilespores germinate in response to cholic acid derivatives, such as taurocholate (TA), and amino acids, such as glycine or alanine. Although the bile acid germinant receptor is known, the amino acid germinant receptor has remained elusive. Here, we used EMS mutagenesis to generate mutants with altered requirements for the amino acid co-germinant, similar to the strategy used previously to identify the bile acid receptor, CspC. Surprisingly, we identified strains that do not require amino acids as co-germinants, and the mutant spores germinated in response to TA alone. Upon sequencing these mutants, we identified different mutations inyabG.InC. difficile, yabGexpression is required for the processing of CspBA to CspB and CspA and preproSleC to proSleC during spore formation. A definedyabGmutant exacerbated the EMS mutant phenotype. Moreover, we found that various mutations incspAcaused spores to germinate in the presence of TA alone without the requirement of an amino acid. Thus, our study provides evidence that apart from regulating the CspC levels in the spore, CspA is important for recognition of amino acids as co-germinants duringC. difficilespore germination and that two pseudoproteases (CspC and CspA) function as theC. difficilegerminant receptors.

Discovery of novel cholic acid derivatives as highly potent agonists for G protein-coupled bile acid receptor

2021 ◽  
pp. 105588
Author(s):  
Mingcheng Qian ◽  
Zhijie Luo ◽  
Wenwen Hou ◽  
Jingjing Sun ◽  
Xin Lu ◽  
...  
Keyword(s):  
Bile Acid ◽  
G Protein ◽  
Cholic Acid ◽  
Acid Receptor ◽  
Bile Acid Receptor ◽  
G Protein Coupled ◽  
Cholic Acid Derivatives

scholarly journals Germinant Synergy FacilitatesClostridium difficileSpore Germination under Physiological Conditions

mSphere ◽  
2018 ◽  
Vol 3 (5) ◽  
Author(s):  
Travis J. Kochan ◽  
Michelle S. Shoshiev ◽  
Jessica L. Hastie ◽  
Madeline J. Somers ◽  
Yael M. Plotnick ◽  
...  
Keyword(s):  
Amino Acids ◽  
Clostridium Difficile ◽  
Spore Germination ◽  
Bile Salts ◽  
Gi Tract ◽  
Infectious Diarrhea ◽  
Content Type ◽  
Increased Risk ◽  
Calcium Reabsorption

ABSTRACTClostridium difficileis a Gram-positive obligate anaerobe that forms spores in order to survive for long periods in the unfavorable environment outside a host.C. difficileis the leading cause of nosocomial infectious diarrhea worldwide.C. difficileinfection (CDI) arises after a patient treated with broad-spectrum antibiotics ingests infectious spores. The first step inC. difficilepathogenesis is the metabolic reactivation of dormant spores within the gastrointestinal (GI) tract through a process known as germination. In this work, we aim to elucidate the specific conditions and the location within the GI tract that facilitate this process. Our data suggest thatC. difficilegermination occurs through a two-step biochemical process that is regulated by pH and bile salts, amino acids, and calcium present within the GI tract. Maximal germination occurs at a pH ranging from 6.5 to 8.5 in the terminal small intestine prior to bile salt and calcium reabsorption by the host. Germination can be initiated by lower concentrations of germinants when spores are incubated with a combination of bile salts, calcium, and amino acids, and this synergy is dependent on the availability of calcium. The synergy described here allows germination to proceed in the presence of inhibitory bile salts and at physiological concentrations of germinants, effectively decreasing the concentrations of nutrients required to initiate an essential step of pathogenesis.IMPORTANCEClostridium difficileis an anaerobic spore-forming human pathogen that is the leading cause of nosocomial infectious diarrhea worldwide. Germination of infectious spores is the first step in the development of aC. difficileinfection (CDI) after ingestion and passage through the stomach. This study investigates the specific conditions that facilitateC. difficilespore germination, including the following: location within the gastrointestinal (GI) tract, pH, temperature, and germinant concentration. The germinants that have been identified in culture include combinations of bile salts and amino acids or bile salts and calcium, butin vitro, these function at concentrations that far exceed normal physiological ranges normally found in the mammalian GI tract. In this work, we describe and quantify a previously unreported synergy observed when bile salts, calcium, and amino acids are added together. These germinant cocktails improve germination efficiency by decreasing the required concentrations of germinants to physiologically relevant levels. Combinations of multiple germinant types are also able to overcome the effects of inhibitory bile salts. In addition, we propose that the acidic conditions within the GI tract regulateC. difficilespore germination and could provide a biological explanation for why patients taking proton pump inhibitors are associated with increased risk of developing a CDI.

Preparation of amino acid-appended cholic acid derivatives as sensitizers of Gram-negative bacteria

1999 ◽  
Vol 40 (10) ◽  
pp. 1865-1868 ◽  
Author(s):  
Atiq-ur-Rehman ◽  
Chunhong Li ◽  
Loren P. Budge ◽  
Sarah E. Street ◽  
Paul B. Savage
Keyword(s):  
Amino Acid ◽  
Cholic Acid ◽  
Gram Negative Bacteria ◽  
Gram Negative ◽  
Cholic Acid Derivatives

scholarly journals Spore Cortex Hydrolysis Precedes Dipicolinic Acid Release during Clostridium difficile Spore Germination

2015 ◽  
Vol 197 (14) ◽  
pp. 2276-2283 ◽  
Author(s):  
Michael B. Francis ◽  
Charlotte A. Allen ◽  
Joseph A. Sorg
Keyword(s):  
Bacillus Subtilis ◽  
Bile Acid ◽  
Clostridium Difficile ◽  
Spore Germination ◽  
Dipicolinic Acid ◽  
Model Organism ◽  
Stage I ◽  
Content Type ◽  
The Core ◽  
Dormant Spore

ABSTRACTBacterial spore germination is a process whereby a dormant spore returns to active, vegetative growth, and this process has largely been studied in the model organismBacillus subtilis. InB. subtilis, the initiation of germinant receptor-mediated spore germination is divided into two genetically separable stages. Stage I is characterized by the release of dipicolinic acid (DPA) from the spore core. Stage II is characterized by cortex degradation, and stage II is activated by the DPA released during stage I. Thus, DPA release precedes cortex hydrolysis duringB. subtilisspore germination. Here, we investigated the timing of DPA release and cortex hydrolysis duringClostridium difficilespore germination and found that cortex hydrolysis precedes DPA release. Inactivation of either the bile acid germinant receptor,cspC, or the cortex hydrolase,sleC, prevented both cortex hydrolysis and DPA release. Because both cortex hydrolysis and DPA release duringC. difficilespore germination are dependent on the presence of the germinant receptor and the cortex hydrolase, the release of DPA from the core may rely on the osmotic swelling of the core upon cortex hydrolysis. These results have implications for the hypothesized glycine receptor and suggest that the initiation of germinant receptor-mediatedC. difficilespore germination proceeds through a novel germination pathway.IMPORTANCEClostridium difficileinfects antibiotic-treated hosts and spreads between hosts as a dormant spore. In a host, spores germinate to the vegetative form that produces the toxins necessary for disease.C. difficilespore germination is stimulated by certain bile acids and glycine. We recently identified the bile acid germinant receptor as the germination-specific, protease-like CspC. CspC is likely cortex localized, where it can transmit the bile acid signal to the cortex hydrolase, SleC. Due to the differences in location of CspC compared to theBacillus subtilisgerminant receptors, we hypothesized that there are fundamental differences in the germination processes between the model organism andC. difficile. We found thatC. difficilespore germination proceeds through a novel pathway.

scholarly journals Reexamining the Germination Phenotypes of Several Clostridium difficile Strains Suggests Another Role for the CspC Germinant Receptor

2015 ◽  
Vol 198 (5) ◽  
pp. 777-786 ◽  
Author(s):  
Disha Bhattacharjee ◽  
Michael B. Francis ◽  
Xicheng Ding ◽  
Kathleen N. McAllister ◽  
Ritu Shrestha ◽  
...  
Keyword(s):  
Bile Acid ◽  
Clostridium Difficile ◽  
Bile Acids ◽  
Spore Germination ◽  
Germination Rate ◽  
Taurocholic Acid ◽  
Receptor Complex ◽  
Health Care Environment ◽  
Content Type ◽  
Downstream Processes

ABSTRACTClostridium difficilespore germination is essential for colonization and disease. The signals that initiateC. difficilespore germination are a combination of taurocholic acid (a bile acid) and glycine. Interestingly, the chenodeoxycholic acid class (CDCA) bile acids competitively inhibit taurocholic acid-mediated germination, suggesting that compounds that inhibit spore germination could be developed into drugs that prophylactically preventC. difficileinfection or reduce recurring disease. However, a recent report called into question the utility of such a strategy to prevent infection by describingC. difficilestrains that germinated in the apparent absence of bile acids or germinated in the presence of the CDCA inhibitor. Because the mechanisms ofC. difficilespore germination are beginning to be elucidated, the mechanism of germination in these particular strains could yield important information on howC. difficilespores initiate germination. Therefore, we quantified the interaction of these strains with taurocholic acid and CDCA, the rates of spore germination, the release of DPA from the spore core, and the abundance of the germinant receptor complex (CspC, CspB, and SleC). We found that strains previously observed to germinate in the absence of taurocholic acid correspond to more potent 50% effective concentrations (EC50values; the concentrations that achieve a half-maximum germination rate) of the germinant and are still inhibited by CDCA, possibly explaining the previous observations. By comparing the germination kinetics and the abundance of proteins in the germinant receptor complex, we revised our original model for CspC-mediated activation of spore germination and propose that CspC may activate spore germination and then inhibit downstream processes.IMPORTANCEClostridium difficileforms metabolically dormant spores that persist in the health care environment. In susceptible hosts,C. difficilespores germinate in response to certain bile acids and glycine. Blocking germination byC. difficilespores is an attractive strategy to prevent the initiation of disease or to block recurring infection. However, certainC. difficilestrains have been identified whose spores germinate in the absence of bile acids or are not blocked by known inhibitors ofC. difficilespore germination (calling into question the utility of such strategies). Here, we further investigate these strains and reestablish that bile acid activators and inhibitors of germination affect these strains and use these data to suggest another role for theC. difficilebile acid germinant receptor.

scholarly journals Nuclear and cytosolic distribution of conjugated cholic acid and radiolabelled glycocholic acid in rat liver

1979 ◽  
Vol 178 (1) ◽  
pp. 71-78 ◽  
Author(s):  
R C Strange ◽  
G J Beckett ◽  
I W Percy-Robb
Keyword(s):  
Bile Acid ◽  
Bile Acids ◽  
Cholic Acid ◽  
Rat Liver ◽  
Superior Mesenteric Vein ◽  
Acid Synthesis ◽  
Bile Acid Synthesis ◽  
Acid Receptor ◽  
Glycocholic Acid ◽  
Bile Acid Receptor

1. Normally fed and cholestyramine-treated rats were injected through the superior mesenteric vein with different amounts of radiolabelled glycoholic acid and the appearance of radioactivity in bile was measured. 2. In normally fed rats radioactivity appeared in bile within 30 s of injection and reached a maximum after 2 1/2 min; in the cholestyramine-treated animals the appearance of radioactivity was slower and less of the injected material was excreted into bile. 3. At 10 min after injection, livers were removed and the amounts of radioactive glycoholic acid and endogenous cholic acid conjugates in nuclei and cytosol were determined; most of the bile acid was found in the cytosol, only small amounts being found in nuclei. 4. Nuclear preparations from both normally fed and cholestyramine-fed rats were extracted with KCl (0.4 M) in an attempt to identify a putative bile acid receptor, but no such receptor was found. 5. Regulation of bile acid synthesis does not involve nuclear binding of bile acids.

scholarly journals Antibiotic-Induced Alterations of the Gut Microbiota Alter Secondary Bile Acid Production and Allow for Clostridium difficile Spore Germination and Outgrowth in the Large Intestine

mSphere ◽  
2016 ◽  
Vol 1 (1) ◽  
Author(s):  
Casey M. Theriot ◽  
Alison A. Bowman ◽  
Vincent B. Young
Keyword(s):  
Bile Acid ◽  
Clostridium Difficile ◽  
Gut Microbiota ◽  
Bile Acids ◽  
Large Intestine ◽  
Spore Germination ◽  
Secondary Bile Acid ◽  
Content Type ◽  
Secondary Bile Acids

ABSTRACT Antibiotics alter the gastrointestinal microbiota, allowing for Clostridium difficile infection, which is a significant public health problem. Changes in the structure of the gut microbiota alter the metabolome, specifically the production of secondary bile acids. Specific bile acids are able to initiate C. difficile spore germination and also inhibit C. difficile growth in vitro, although no study to date has defined physiologically relevant bile acids in the gastrointestinal tract. In this study, we define the bile acids C. difficile spores encounter in the small and large intestines before and after various antibiotic treatments. Antibiotics that alter the gut microbiota and deplete secondary bile acid production allow C. difficile colonization, representing a mechanism of colonization resistance. Multiple secondary bile acids in the large intestine were able to inhibit C. difficile spore germination and growth at physiological concentrations and represent new targets to combat C. difficile in the large intestine. It is hypothesized that the depletion of microbial members responsible for converting primary bile acids into secondary bile acids reduces resistance to Clostridium difficile colonization. To date, inhibition of C. difficile growth by secondary bile acids has only been shown in vitro. Using targeted bile acid metabolomics, we sought to define the physiologically relevant concentrations of primary and secondary bile acids present in the murine small and large intestinal tracts and how these impact C. difficile dynamics. We treated mice with a variety of antibiotics to create distinct microbial and metabolic (bile acid) environments and directly tested their ability to support or inhibit C. difficile spore germination and outgrowth ex vivo. Susceptibility to C. difficile in the large intestine was observed only after specific broad-spectrum antibiotic treatment (cefoperazone, clindamycin, and vancomycin) and was accompanied by a significant loss of secondary bile acids (deoxycholate, lithocholate, ursodeoxycholate, hyodeoxycholate, and ω-muricholate). These changes were correlated to the loss of specific microbiota community members, the Lachnospiraceae and Ruminococcaceae families. Additionally, physiological concentrations of secondary bile acids present during C. difficile resistance were able to inhibit spore germination and outgrowth in vitro. Interestingly, we observed that C. difficile spore germination and outgrowth were supported constantly in murine small intestinal content regardless of antibiotic perturbation, suggesting that targeting growth of C. difficile will prove most important for future therapeutics and that antibiotic-related changes are organ specific. Understanding how the gut microbiota regulates bile acids throughout the intestine will aid the development of future therapies for C. difficile infection and other metabolically relevant disorders such as obesity and diabetes. IMPORTANCE Antibiotics alter the gastrointestinal microbiota, allowing for Clostridium difficile infection, which is a significant public health problem. Changes in the structure of the gut microbiota alter the metabolome, specifically the production of secondary bile acids. Specific bile acids are able to initiate C. difficile spore germination and also inhibit C. difficile growth in vitro, although no study to date has defined physiologically relevant bile acids in the gastrointestinal tract. In this study, we define the bile acids C. difficile spores encounter in the small and large intestines before and after various antibiotic treatments. Antibiotics that alter the gut microbiota and deplete secondary bile acid production allow C. difficile colonization, representing a mechanism of colonization resistance. Multiple secondary bile acids in the large intestine were able to inhibit C. difficile spore germination and growth at physiological concentrations and represent new targets to combat C. difficile in the large intestine.

Amino acid uptake and protein synthesis in germinating spores of Saccharomyces cerevisiae

1977 ◽  
Vol 23 (4) ◽  
pp. 407-412 ◽  
Author(s):  
S. D. Steele ◽  
J. J. Miller
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Amino Acids ◽  
Protein Synthesis ◽  
Amino Acid ◽  
Spore Germination ◽  
Amino Acid Uptake ◽  
Acid Uptake ◽  
Intracellular Pool ◽  
Germination Medium ◽  
Exogenous Proline

Spores transferred to germination medium incorporated exogenous lysine into protein within 20 min but required 2–3 h to begin incorporation of exogenous proline or alanine. During this time considerable uptake of amino acids into the intracellular pool occurred. Cycloheximide added to the germination medium inhibited incorporation of lysine into protein but did not lessen its accumulation in the pool. Spore germination was inhibited by cycloheximide.

Amino acid–bile acid based molecules: extremely narrow surfactant nanotubes formed by a phenylalanine-substituted cholic acid

2012 ◽  
Vol 48 (98) ◽  
pp. 12011 ◽  
Author(s):  
Leana Travaglini ◽  
Andrea D'Annibale ◽  
Karin Schillén ◽  
Ulf Olsson ◽  
Simona Sennato ◽  
...  
Keyword(s):  
Bile Acid ◽  
Amino Acid ◽  
Cholic Acid

scholarly journals Inhibiting the Initiation of Clostridium difficile Spore Germination using Analogs of Chenodeoxycholic Acid, a Bile Acid

2010 ◽  
Vol 192 (19) ◽  
pp. 4983-4990 ◽  
Author(s):  
Joseph A. Sorg ◽  
Abraham L. Sonenshein
Keyword(s):  
Bile Acid ◽  
Gastrointestinal Tract ◽  
Clostridium Difficile ◽  
Spore Germination ◽  
Competitive Inhibitor ◽  
Apparent Affinity ◽  
Core Member ◽  
Normal Human ◽  
Menten Kinetic ◽  
Colonic Environment

ABSTRACT To cause disease, Clostridium difficile spores must germinate in the host gastrointestinal tract. Germination is initiated upon exposure to glycine and certain bile acids, e.g., taurocholate. Chenodeoxycholate, another bile acid, inhibits taurocholate-mediated germination. By applying Michaelis-Menten kinetic analysis to C. difficile spore germination, we found that chenodeoxycholate is a competitive inhibitor of taurocholate-mediated germination and appears to interact with the spores with greater apparent affinity than does taurocholate. We also report that several analogs of chenodeoxycholate are even more effective inhibitors. Some of these compounds resist 7α-dehydroxylation by Clostridium scindens, a core member of the normal human colonic microbiota, suggesting that they are more stable than chenodeoxycholate in the colonic environment.

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