Your search keyword '"Taylor M Young"' showing total 6 results

1. MgrB-Dependent Colistin Resistance in Klebsiella pneumoniae Is Associated with an Increase in Host-to-Host Transmission

Author

Andrew S. Bray, Richard D. Smith, Andrew W. Hudson, Giovanna E. Hernandez, Taylor M. Young, Hannah E. George, Robert K. Ernst, and M. Ammar Zafar

Subjects

antimicrobial peptides, gastrointestinal infection, host-to-host transmission, infection control, stress adaptation, two-component regulatory systems, Microbiology, QR1-502

Abstract

ABSTRACT Due to its high transmissibility, Klebsiella pneumoniae is one of the leading causes of nosocomial infections. Here, we studied the biological cost of colistin resistance, an antibiotic of last resort, in this opportunistic pathogen using a murine model of gut colonization and transmission. Colistin resistance in K. pneumoniae is commonly the result of the inactivation of the small regulatory protein MgrB. Without a functional MgrB, the two-component system PhoPQ is constitutively active, leading to an increase in lipid A modifications and subsequent colistin resistance. Using an isogenic mgrB deletion mutant (MgrB−), we demonstrate that the mutant’s colistin resistance is not associated with a fitness defect under in vitro growth conditions. However, in our murine model of K. pneumoniae gastrointestinal (GI) colonization, the MgrB− colonizes the gut poorly, allowing us to identify a fitness cost. Moreover, the MgrB− mutant has higher survival outside the host compared with the parental strain. We attribute this enhanced survivability to dysregulation of the PhoPQ two-component system and accumulation of the master stress regulator RpoS. The enhanced survival of MgrB− may be critical for its rapid host-to-host transmission observed in our model. Together, our data using multiple clinical isolates demonstrate that MgrB-dependent colistin resistance in K. pneumoniae comes with a biological cost in gut colonization. However, this cost is mitigated by enhanced survival outside the host and consequently increases its host-to-host transmission. Additionally, it underscores the importance of considering the entire life cycle of a pathogen to determine the actual biological cost associated with antibiotic resistance. IMPORTANCE The biological cost associated with colistin resistance in Klebsiella pneumoniae was examined using a murine model of K. pneumoniae gut colonization and fecal-oral transmission. A common mutation resulting in colistin resistance in K. pneumoniae is a loss-of-function mutation of the small regulatory protein MgrB that regulates the two-component system PhoPQ. Even though colistin resistance in K. pneumoniae comes with a fitness defect in gut colonization, it increases bacterial survival outside the host enabling it to transmit more effectively to a new host. The enhanced survival is dependent upon the accumulation of RpoS and dysregulation of the PhoPQ. Hence, our study expands our understanding of the underlying molecular mechanism contributing to the transmission of colistin-resistant K. pneumoniae.

Published

2022

2. Teaching Postsecondary Students to Use Analogies as a Cognitive Learning Strategy: An Intervention

Author

Joseph C. Tise, Rayne A. Sperling, Michael S. Dann, and Taylor M. Young

Subjects

General Biochemistry, Genetics and Molecular Biology, Education

Abstract

This intervention extends learning strategies research into authentic learning environments. It shows college biology students can learn to generate analogies as a learning strategy and get better at doing so. Finally, students’ generated-analogy quality predicts analogical reasoning and knowledge of cognition.

Published

2023

3. The Two-Component System YesMN Promotes Pneumococcal Host-to-Host Transmission and Regulates Genes Involved in Zinc Homeostasis

Author

M. Ammar Zafar, Alicia Costa-Terryl, and Taylor M. Young

Subjects

Infectious Diseases, Immunology, Parasitology, Molecular Pathogenesis, Microbiology

Abstract

The ability to sense and respond rapidly to the dynamic environment of the upper respiratory tract (URT) makes Streptococcus pneumoniae (Spn) a highly successful human pathogen. Two-component systems (TCS) of Spn sense and respond to multiple signals it encounters allowing Spn to adapt and thrive in various host sites. Spn TCS have been implicated in their ability to promote pneumococcal colonization of the URT and virulence. As the disease state can be a dead-end for a pathogen, we considered whether TCS would contribute to pneumococcal transmission. Herein, we determined the role of YesMN, an understudied TCS of Spn, and observe that YesMN contributes towards pneumococcal shedding and transmission but is not essential for colonization. The YesMN regulon includes genes involved in zinc homeostasis and glycan metabolism, which are upregulated during reduced zinc availability in a YesMN dependent fashion. Thus, we identify the YesMN regulon and the molecular signals it senses that lead to the activation of genes involved in zinc homeostasis and glycan metabolism. Furthermore, in contract to Spn mono-infection, we demonstrate that YesMN is critical for high pneumococcal density in the URT during influenza A (IAV) coinfection. We attribute reduced colonization of the yesMN mutant due to increased association with and clearance by the mucus covering the URT epithelial surface. Thus, our results highlight the dynamic interactions that occur between Spn and IAV in the URT, and the role that TCS play in modulation of these interactions.

Published

2023

4. MgrB dependent colistin resistance in Klebsiella pneumoniae is associated with an increase in host-to-host transmission

Author

Richard D. Smith, Robert K. Ernst, Giovanna Hernandez, Taylor M Young, Andrew W Hudson, Andrew S. Bray, and Muhammad Ammar Zafar

Subjects

Regulation of gene expression, medicine.drug_class, Klebsiella pneumoniae, Antibiotics, Mutant, Biology, biology.organism_classification, Microbiology, Antibiotic resistance, Colistin, medicine, rpoS, Pathogen, medicine.drug

Abstract

Due to its high transmissibility, Klebsiella pneumoniae (Kpn) is one of the leading causes of nosocomial infections. Here, we studied the biological cost of colistin resistance, an antibiotic of last resort, of this opportunistic pathogen using a murine model of gut colonization and transmission. Colistin resistance in Kpn is commonly the result of inactivation of the small regulatory protein MgrB. Without a functional MgrB, the two-component system PhoPQ is constitutively active, leading to increased lipid A modifications and subsequent colistin resistance. Using an engineered MgrB mutant, we observed that MgrB-dependent colistin resistance is not associated with a fitness defect during in vitro growth conditions. However, colistin-resistant Kpn colonizes the murine gut poorly, which may be due to the decreased production of capsular polysaccharide by the mutant. The colistin-resistant mutant of Kpn had increased survival outside the host when compared to the parental colistin-sensitive strain. We attribute this enhanced survivability to dysregulation of the PhoPQ two-component system and accumulation of the master stress regulator RpoS. The enhanced survival of the colistin resistant strain may be a key factor in the observed rapid host-to-host transmission in our model. Together, our data demonstrate that colistin-resistant Kpn experiences a biological cost in gastrointestinal colonization. However, this cost is mitigated by enhanced survival outside the host, increasing the risk of transmission. Additionally, it underscores the importance of considering the entire life cycle of a pathogen to truly determine the biological cost associated with antibiotic resistance.ImportanceThe biological cost associated with colistin resistance in Klebsiella pneumoniae (Kpn) was examined using a murine model of Kpn gut colonization and fecal-oral transmission. A common mutation resulting in colistin resistance in Kpn is a loss-of-function mutation of the small regulatory protein MgrB that regulates the two-component system PhoPQ. Even though colistin resistance in Kpn comes with a fitness defect in gut colonization, it increases bacterial survival outside the host enabling it to more effectively transmit to a new host. The enhanced survival is dependent upon the accumulation of RpoS and dysregulation of the PhoPQ. Hence, our study expands our understanding of the underlying molecular mechanism contributing to the transmission of colistin-resistant Kpn.

Published

2021

5. An Animal Model to Study Klebsiella pneumoniae Gastro-Intestinal Colonization and Host-to-Host Transmission

Author

David L. Caudell, Muhammad Ammar Zafar, Andrew S. Bray, Ravinder Nagpal, Hariom Yadav, and Taylor M Young

Subjects

Transmission (medicine), medicine.drug_class, Klebsiella pneumoniae, Host (biology), Antibiotics, medicine, Colonization, Biology, biology.organism_classification, Pathogen, Feces, Bacteria, Microbiology

Abstract

An important yet poorly understood facet in the life cycle of a successful pathogen is the host-to-host transmission. Hospital-acquired infections (HAI) resulting from the transmission of drug-resistant pathogens affect hundreds of millions of patients worldwide. Klebsiella pneumoniae (Kpn), a gram-negative bacterium, is notorious for causing HAI, with many of these infections difficult to treat as Kpn has become multi-drug resistant. Epidemiological studies suggest that Kpn host-to-host transmission requires close contact and generally occurs through the fecal-oral route. Herein, we describe a murine model that can be utilized to study mucosal (oropharynx and gastrointestinal [GI]) colonization, shedding within feces, and transmission of Kpn through the fecal-oral route. Using an oral route of inoculation, and fecal shedding as a marker for GI colonization, we show that Kpn can asymptomatically colonize the GI tract of immunocompetent mice, and modifies the host GI microbiota. Colonization density within the GI tract and levels of shedding in the feces differed among the clinical isolates tested. A hypervirulent Kpn isolate was able to translocate from the GI tract and cause hepatic infection that mimicked the route of human infection. Expression of the capsule was required for colonization and, in turn, robust shedding. Furthermore, Kpn carrier mice were able to transmit to uninfected cohabitating mice. Lastly, treatment with antibiotics led to changes in the host microbiota and development of a transient super-shedder phenotype, which enhanced transmission efficiency. Thus, this model can be used to determine the contribution of host and bacterial factors towards Kpn dissemination.

Published

2020

6. Animal Model To Study Klebsiella pneumoniae Gastrointestinal Colonization and Host-to-Host Transmission

Author

Ravinder Nagpal, M. Ammar Zafar, David L. Caudell, Taylor M Young, Andrew S. Bray, and Hariom Yadav

Subjects

Klebsiella, hospital infections, antibiotic resistance, medicine.drug_class, Klebsiella pneumoniae, Gastrointestinal Diseases, Immunology, Antibiotics, enteric pathogens, Biology, Microbiology, fimbriae, Mice, Antibiotic resistance, medicine, Animals, host-pathogen interactions, Colonization, Pathogen, Feces, Transmission (medicine), transmission, Bacterial Infections, biology.organism_classification, animal models, capsular polysaccharide, Klebsiella Infections, Disease Models, Animal, Infectious Diseases, Parasitology

Abstract

An important yet poorly understood facet of the life cycle of a successful pathogen is host-to-host transmission. Hospital-acquired infections (HAI) resulting from the transmission of drug-resistant pathogens affect hundreds of millions of patients worldwide. Klebsiella pneumoniae, a Gram-negative bacterium, is notorious for causing HAI, with many of these infections difficult to treat, as K. pneumoniae has become multidrug resistant. Epidemiological studies suggest that K. pneumoniae host-to-host transmission requires close contact and generally occurs through the fecal-oral route., An important yet poorly understood facet of the life cycle of a successful pathogen is host-to-host transmission. Hospital-acquired infections (HAI) resulting from the transmission of drug-resistant pathogens affect hundreds of millions of patients worldwide. Klebsiella pneumoniae, a Gram-negative bacterium, is notorious for causing HAI, with many of these infections difficult to treat, as K. pneumoniae has become multidrug resistant. Epidemiological studies suggest that K. pneumoniae host-to-host transmission requires close contact and generally occurs through the fecal-oral route. Here, we describe a murine model that can be utilized to study mucosal (oropharynx and gastrointestinal [GI]) colonization, shedding within feces, and transmission of K. pneumoniae through the fecal-oral route. Using an oral route of inoculation, and fecal shedding as a marker for GI colonization, we showed that K. pneumoniae can asymptomatically colonize the GI tract in immunocompetent mice and modifies the host GI microbiota. Colonization density within the GI tract and levels of shedding in the feces differed among the clinical isolates tested. A hypervirulent K. pneumoniae isolate was able to translocate from the GI tract and cause hepatic infection that mimicked the route of human infection. Expression of the capsule was required for colonization and, in turn, robust shedding. Furthermore, K. pneumoniae carrier mice were able to transmit to uninfected cohabitating mice. Lastly, treatment with antibiotics led to changes in the host microbiota and development of a transient supershedder phenotype, which enhanced transmission efficiency. Thus, this model can be used to determine the contribution of host and bacterial factors toward K. pneumoniae dissemination.

Published

2020