Your search keyword '"Nicholas A Lesniak"' showing total 7 results

1. Diluted Fecal Community Transplant Restores Clostridioides difficile Colonization Resistance to Antibiotic-Perturbed Murine Communities

Author

Nicholas A. Lesniak, Sarah Tomkovich, Andrew Henry, Ana Taylor, Joanna Colovas, Lucas Bishop, Kathryn McBride, and Patrick D. Schloss

Subjects

Male, Bacteria, Clostridioides difficile, Clindamycin, Cefoperazone, Fecal Microbiota Transplantation, Microbiology, Anti-Bacterial Agents, Gastrointestinal Microbiome, Mice, Inbred C57BL, Feces, Mice, Clostridioides, Virology, RNA, Ribosomal, 16S, Clostridium Infections, Streptomycin, Animals, Disease Susceptibility

Abstract

Fecal communities transplanted into individuals can eliminate recurrent Clostridioides difficile infection (CDI) with high efficacy. However, this treatment is only used once CDI becomes resistant to antibiotics or has recurred multiple times. We sought to investigate whether a fecal community transplant (FCT) pretreatment could be used to prevent CDI altogether. We treated male C57BL/6 mice with either clindamycin, cefoperazone, or streptomycin and then inoculated them with the microbial community from untreated mice before challenge with C. difficile. We measured colonization and sequenced the V4 region of the 16S rRNA gene to understand the dynamics of the murine fecal community in response to the FCT and C. difficile challenge. Clindamycin-treated mice became colonized with C. difficile but cleared it naturally and did not benefit from the FCT. Cefoperazone-treated mice became colonized by C. difficile, but the FCT enabled clearance of C. difficile. In streptomycin-treated mice, the FCT was able to prevent C. difficile from colonizing. We then diluted the FCT and repeated the experiments. Cefoperazone-treated mice no longer cleared C. difficile. However, streptomycin-treated mice colonized with 1:10

Published

2022

2. The gut bacterial community potentiates Clostridioides difficile infection severity

Author

Nicholas A. Lesniak, Alyxandria M. Schubert, Kaitlin J. Flynn, Jhansi L. Leslie, Hamide Sinani, Ingrid L. Bergin, Vincent B. Young, and Patrick D. Schloss

Subjects

Bile Acids and Salts, Feces, Mice, Bacteria, Clostridioides difficile, Virology, Clostridium Infections, Animals, Humans, Microbiology, Gastrointestinal Microbiome

Abstract

The severity of Clostridioides difficile infections (CDI) has increased over the last few decades. Patient age, white blood cell count, creatinine levels as well as C. difficile ribotype and toxin genes have been associated with disease severity. However, it is unclear whether there is an association between members of the gut microbiota and disease severity. The gut microbiota is known to interact with C. difficile during infection. Perturbations to the gut microbiota are necessary for C. difficile to colonize the gut. The gut microbiota can inhibit C. difficile colonization through bile acid metabolism, nutrient consumption and bacteriocin production. Here we sought to demonstrate that members of the gut bacterial communities can also contribute to disease severity. We derived diverse gut communities by colonizing germ-free mice with different human fecal communities. The mice were then infected with a single C. difficile ribotype 027 clinical isolate which resulted in moribundity and histopathologic differences. The variation in severity was associated with the human fecal community that the mice received. Generally, bacterial populations with pathogenic potential, such as Escherichia, Helicobacter, and Klebsiella, were associated with more severe outcomes. Bacterial groups associated with fiber degradation, bile acid metabolism and lantibiotic production, such as Anaerostipes and Coprobacillus, were associated with less severe outcomes. These data indicate that, in addition to the host and C. difficile, populations of gut bacteria can influence CDI disease severity.ImportanceClostridioides difficile colonization can be asymptomatic or develop into an infection, ranging in severity from mild diarrhea to toxic megacolon, sepsis, and death. Models that predict severity and guide treatment decisions are based on clinical factors and C. difficile characteristics. Although the gut microbiome plays a role in protecting against CDI, its effect on CDI disease severity is unclear and has not been incorporated into disease severity models. We demonstrated that variation in the microbiome of mice colonized with human feces yielded a range of disease outcomes. These results revealed groups of bacteria associated with both severe and mild C. difficile infection outcomes. Gut bacterial community data from patients with CDI could improve our ability to identify patients at risk of developing more severe disease and improve interventions which target C. difficile and the gut bacteria to reduce host damage.

Published

2022

3. Clearance of Clostridioides difficile colonization is associated with antibiotic-specific bacterial changes

Author

Alyxandria M. Schubert, Patrick D. Schloss, Hamide Sinani, and Nicholas A. Lesniak

Subjects

medicine.drug_class, Antibiotics, Porphyromonadaceae, Cefoperazone, microbiome, Colonisation resistance, Gut flora, Biology, microbial ecology, digestive system, Microbiology, Feces, Mice, 03 medical and health sciences, fluids and secretions, colonization resistance, microbiota, medicine, Animals, Colonization, Molecular Biology, 030304 developmental biology, 0303 health sciences, Bacteria, Clostridioides difficile, 030306 microbiology, Clindamycin, Clostridium difficile, dynamics, biology.organism_classification, Enterobacteriaceae, QR1-502, Anti-Bacterial Agents, Gastrointestinal Microbiome, stomatognathic diseases, Clostridium Infections, Streptomycin, Disease Susceptibility, 16S rRNA gene, Bacteroides, Research Article, medicine.drug

Abstract

The community of microorganisms, or microbiota, in our intestines prevents pathogens like C. difficile from colonizing and causing infection. However, antibiotics can disturb the gut microbiota, which allows C. difficile to colonize. C. difficile infections (CDI) are primarily treated with antibiotics, which frequently leads to recurrent infections because the microbiota has not yet returned to a resistant state., The gut bacterial community prevents many pathogens from colonizing the intestine. Previous studies have associated specific bacteria with clearing Clostridioides difficile colonization across different community perturbations. However, those bacteria alone have been unable to clear C. difficile colonization. To elucidate the changes necessary to clear colonization, we compared differences in bacterial abundance between communities able and unable to clear C. difficile colonization. We treated mice with titrated doses of antibiotics prior to C. difficile challenge, resulting in no colonization, colonization and clearance, or persistent colonization. Previously, we observed that clindamycin-treated mice were susceptible to colonization but spontaneously cleared C. difficile. Therefore, we investigated whether other antibiotics would show the same result. We found that reduced doses of cefoperazone and streptomycin permitted colonization and clearance of C. difficile. Mice that cleared colonization had antibiotic-specific community changes and predicted interactions with C. difficile. Clindamycin treatment led to a bloom in populations related to Enterobacteriaceae. Clearance of C. difficile was concurrent with the reduction of those blooming populations and the restoration of community members related to the Porphyromonadaceae and Bacteroides. Cefoperazone created a susceptible community characterized by drastic reductions in the community diversity and interactions and a sustained increase in the abundance of many facultative anaerobes. Lastly, clearance in streptomycin-treated mice was associated with the recovery of multiple members of the Porphyromonadaceae, with little overlap in the specific Porphyromonadaceae observed in the clindamycin treatment. Further elucidation of how C. difficile colonization is cleared from different gut bacterial communities will improve C. difficile infection treatments. IMPORTANCE The community of microorganisms, or microbiota, in our intestines prevents pathogens like C. difficile from colonizing and causing infection. However, antibiotics can disturb the gut microbiota, which allows C. difficile to colonize. C. difficile infections (CDI) are primarily treated with antibiotics, which frequently leads to recurrent infections because the microbiota has not yet returned to a resistant state. The recurrent infection cycle often ends when the fecal microbiota from a presumed resistant person is transplanted into the susceptible person. Although this treatment is highly effective, we do not understand the mechanism. We hope to improve the treatment of CDI through elucidating how the bacterial community eliminates CDI. We found that C. difficile colonized susceptible mice but was spontaneously eliminated in an antibiotic treatment-specific manner. These data indicate that each community had different requirements for clearing colonization. Understanding how different communities clear colonization will reveal targets to improve CDI treatments.

Published

2020

4. The proton pump inhibitor omeprazole does not promote Clostridioides difficile colonization in a murine model

Author

Patrick D. Schloss, Nicholas A. Lesniak, Sarah Tomkovich, Lucas Bishop, Yuan Li, and Madison J. Fitzgerald

Subjects

0301 basic medicine, Antibiotics, lcsh:QR1-502, microbiome, Observation, microbial ecology, lcsh:Microbiology, Feces, Mice, RNA, Ribosomal, 16S, Cluster Analysis, Colonization, Phylogeny, Omeprazole, 0303 health sciences, Microbiota, pathogenesis, Clostridium difficile, Fecal microbiota, QR1-502, 3. Good health, Carrier State, Disease Susceptibility, medicine.drug, DNA, Bacterial, medicine.drug_class, mouse model, 030106 microbiology, Proton-pump inhibitor, Colonisation resistance, DNA, Ribosomal, Microbiology, Host-Microbe Biology, 03 medical and health sciences, colonization resistance, medicine, Animals, Microbiome, Molecular Biology, 030304 developmental biology, Clostridioides difficile, 030306 microbiology, business.industry, Clindamycin, Proton Pump Inhibitors, Sequence Analysis, DNA, infection, Disease Models, Animal, 030104 developmental biology, 13. Climate action, Murine model, Clostridium Infections, 16S rRNA gene, business, Clostridioides

Abstract

Antibiotics are the primary risk factor for Clostridioides difficile infections (CDIs), but other factors may also increase a person’s risk. In epidemiological studies, proton pump inhibitor (PPI) use has been associated with CDI incidence and recurrence. PPIs have also been associated with alterations in the human intestinal microbiota in observational and interventional studies. We evaluated the effects of the PPI omeprazole on the structure of the murine intestinal microbiota and its ability to disrupt colonization resistance to C. difficile. We found omeprazole treatment had minimal impact on the murine fecal microbiota and did not promote C. difficile colonization. Further studies are needed to determine whether other factors contribute to the association between PPIs and CDIs seen in humans or whether aspects of murine physiology may limit its utility to test these types of hypotheses., Proton pump inhibitor (PPI) use has been associated with microbiota alterations and susceptibility to Clostridioides difficile infections (CDIs) in humans. We assessed how PPI treatment alters the fecal microbiota and whether treatment promotes CDIs in a mouse model. Mice receiving a PPI treatment were gavaged with 40 mg of omeprazole per kg of body weight during a 7-day pretreatment phase, the day of C. difficile challenge, and the following 9 days. We found that mice treated with omeprazole were not colonized by C. difficile. When omeprazole treatment was combined with a single clindamycin treatment, one cage of mice remained resistant to C. difficile colonization, while the other cage was colonized. Treating mice with only clindamycin followed by challenge resulted in C. difficile colonization. 16S rRNA gene sequencing analysis revealed that omeprazole had minimal impact on the structure of the murine microbiota throughout the 16 days of omeprazole exposure. These results suggest that omeprazole treatment alone is not sufficient to disrupt microbiota resistance to C. difficile infection in mice that are normally resistant in the absence of antibiotic treatment. IMPORTANCE Antibiotics are the primary risk factor for Clostridioides difficile infections (CDIs), but other factors may also increase a person’s risk. In epidemiological studies, proton pump inhibitor (PPI) use has been associated with CDI incidence and recurrence. PPIs have also been associated with alterations in the human intestinal microbiota in observational and interventional studies. We evaluated the effects of the PPI omeprazole on the structure of the murine intestinal microbiota and its ability to disrupt colonization resistance to C. difficile. We found omeprazole treatment had minimal impact on the murine fecal microbiota and did not promote C. difficile colonization. Further studies are needed to determine whether other factors contribute to the association between PPIs and CDIs seen in humans or whether aspects of murine physiology may limit its utility to test these types of hypotheses.

Published

2019

5. The Glucoamylase Inhibitor Acarbose Has a Diet-Dependent and Reversible Effect on the Murine Gut Microbiome

Author

Nicole M. Koropatkin, Nancy N. Baxter, Patrick D. Schloss, Hamide Sinani, and Nicholas A. Lesniak

Subjects

0301 basic medicine, Dietary Fiber, Male, Bacteroidaceae, 030106 microbiology, lcsh:QR1-502, Type 2 diabetes, Biology, Pharmacology, Gut flora, Microbiology, lcsh:Microbiology, Host-Microbe Biology, 03 medical and health sciences, Feces, Mice, RNA, Ribosomal, 16S, medicine, Animals, Glycoside Hydrolase Inhibitors, Molecular Biology, Acarbose, Bacteria, gut microbiota, starch, Lachnospiraceae, biology.organism_classification, medicine.disease, Fatty Acids, Volatile, QR1-502, 3. Good health, Metformin, Diet, Gastrointestinal Microbiome, Bifidobacteriaceae, Mice, Inbred C57BL, Butyrates, 030104 developmental biology, Postprandial, Erratum, acarbose, Akkermansia muciniphila, medicine.drug, Research Article

Abstract

The gut microbial community has a profound influence on host physiology in both health and disease. In diabetic individuals, the gut microbiota can affect the course of disease, and some medications for diabetes, including metformin, seem to elicit some of their benefits via an interaction with the microbiota. Here, we report that acarbose, a glucoamylase inhibitor for type 2 diabetes, changes the murine gut bacterial community structure in a reversible and diet-dependent manner. In both high-starch and high-fiber diet backgrounds, acarbose treatment results in increased short-chain fatty acids, particularly butyrate, as measured in stool samples. As we learn more about how human disease is affected by the intestinal bacterial community, the interplay between medications such as acarbose and the diet will become increasingly important to evaluate., Acarbose is a safe and effective medication for type 2 diabetes that inhibits host glucoamylases to prevent starch digestion in the small intestines and thus decrease postprandial blood glucose levels. This results in an increase in dietary starch in the distal intestine, where it becomes food for the gut bacterial community. Here, we examined the effect of acarbose therapy on the gut community structure in mice fed either a high-starch (HS) or high-fiber diet rich in plant polysaccharides (PP). The fecal microbiota of animals consuming a low dose of acarbose (25 ppm) was not significantly different from that of control animals that did not receive acarbose. However, a high dose of acarbose (400 ppm) with the HS diet resulted in a substantial change to the microbiota structure. Most notably, the HS diet with a high dose of acarbose lead to an expansion of the Bacteroidaceae and Bifidobacteriaceae and a decrease in the Verrucomicrobiaceae (such as Akkermansia muciniphila) and the Bacteroidales S24-7. Once acarbose treatment ceased, the community composition quickly reverted to mirror that of the control group, suggesting that acarbose does not irreversibly alter the gut community. The high dose of acarbose in the PP diet resulted in a distinct community structure with increased representation of Bifidobacteriaceae and Lachnospiraceae. Short-chain fatty acids (SCFAs) measured from stool samples were increased, especially butyrate, as a result of acarbose treatment in both diets. These data demonstrate the potential of acarbose to change the gut community structure and increase beneficial SCFA output in a diet-dependent manner. IMPORTANCE The gut microbial community has a profound influence on host physiology in both health and disease. In diabetic individuals, the gut microbiota can affect the course of disease, and some medications for diabetes, including metformin, seem to elicit some of their benefits via an interaction with the microbiota. Here, we report that acarbose, a glucoamylase inhibitor for type 2 diabetes, changes the murine gut bacterial community structure in a reversible and diet-dependent manner. In both high-starch and high-fiber diet backgrounds, acarbose treatment results in increased short-chain fatty acids, particularly butyrate, as measured in stool samples. As we learn more about how human disease is affected by the intestinal bacterial community, the interplay between medications such as acarbose and the diet will become increasingly important to evaluate.

Published

2019

6. Coordination chemistry controls the thiol oxidase activity of the B

Author

Zhu, Li, Aranganathan, Shanmuganathan, Markus, Ruetz, Kazuhiro, Yamada, Nicholas A, Lesniak, Bernhard, Kräutler, Thomas C, Brunold, Markos, Koutmos, and Ruma, Banerjee

Subjects

Oxidative Stress, polycyclic compounds, Mutation, Missense, Enzymology, Animals, Humans, Oxidoreductases Acting on Sulfur Group Donors, Cobamides, Caenorhabditis elegans, Caenorhabditis elegans Proteins, Carrier Proteins, Oxidoreductases

Abstract

The cobalamin or B12 cofactor supports sulfur and one-carbon metabolism and the catabolism of odd-chain fatty acids, branched-chain amino acids, and cholesterol. CblC is a B12-processing enzyme involved in an early cytoplasmic step in the cofactor-trafficking pathway. It catalyzes the glutathione (GSH)-dependent dealkylation of alkylcobalamins and the reductive decyanation of cyanocobalamin. CblC from Caenorhabditis elegans (ceCblC) also exhibits a robust thiol oxidase activity, converting reduced GSH to oxidized GSSG with concomitant scrubbing of ambient dissolved O2. The mechanism of thiol oxidation catalyzed by ceCblC is not known. In this study, we demonstrate that novel coordination chemistry accessible to ceCblC-bound cobalamin supports its thiol oxidase activity via a glutathionyl-cobalamin intermediate. Deglutathionylation of glutathionyl-cobalamin by a second molecule of GSH yields GSSG. The crystal structure of ceCblC provides insights into how architectural differences at the α- and β-faces of cobalamin promote the thiol oxidase activity of ceCblC but mute it in wild-type human CblC. The R161G and R161Q mutations in human CblC unmask its latent thiol oxidase activity and are correlated with increased cellular oxidative stress disease. In summary, we have uncovered key architectural features in the cobalamin-binding pocket that support unusual cob(II)alamin coordination chemistry and enable the thiol oxidase activity of ceCblC.

Published

2017

7. Unusual aerobic stabilization of Cob(I)alamin by a B12-trafficking protein allows chemoenzymatic synthesis of organocobalamins

Author

Ruma Banerjee, Zhu Li, and Nicholas A. Lesniak

Subjects

Stereochemistry, Biochemistry, Catalysis, Cofactor, Article, Glutathione transferase, chemistry.chemical_compound, Colloid and Surface Chemistry, polycyclic compounds, Animals, Humans, Cyanocobalamin, Thiol oxidase activity, Caenorhabditis elegans, Caenorhabditis elegans Proteins, Glutathione Transferase, biology, Biological activity, Biological Transport, General Chemistry, Glutathione, biology.organism_classification, Aerobiosis, Vitamin B 12, chemistry, biology.protein, CBLC, Oxidoreductases

Abstract

CblC, a B12 trafficking protein, exhibits glutathione transferase and reductive decyanase activities for processing alkylcobalamins and cyanocobalamin, respectively, to a common intermediate that is subsequently converted to the biologically active forms of the cofactor. We recently discovered that the Caenorhabditis elegans CblC catalyzes thiol-dependent decyanation of CNCbl and reduction of OH2Cbl and stabilizes the paramagnetic cob(II)alamin product under aerobic conditions. In this study, we report the striking ability of the worm CblC to stabilize the highly reactive cob(I)alamin product of the glutathione transferase reaction. The unprecedented stabilization of the supernucleophilic cob(I)alamin species under aerobic conditions by the intrinsic thiol oxidase activity of CblC, was exploited for the chemoenzymatic synthesis of organocobalamin derivatives under mild conditions.

Published

2014