Your search keyword '"Collins, Kieran"' showing total 6 results

1. Chemotaxis Allows Bacteria To Overcome Host-Generated Reactive Oxygen Species That Constrain Gland Colonization

Author

Collins, Kieran D, Hu, Shuai, Grasberger, Helmut, Kao, John Y, and Ottemann, Karen M

Subjects

Microbiology, Biological Sciences, Biomedical and Clinical Sciences, Emerging Infectious Diseases, Infectious Diseases, Digestive Diseases, 1.1 Normal biological development and functioning, Aetiology, Underpinning research, 2.2 Factors relating to the physical environment, Animals, Bacterial Proteins, Carrier State, Chemotaxis, Female, Gastric Mucosa, Gene Expression Regulation, Genes, Bacterial, Helicobacter pylori, Humans, Male, Mice, Mice, Knockout, Mutation, Reactive Oxygen Species, MCP, biogeography, chemoreceptors, crypts, glands, reactive oxygen species, signal transduction, stomach, Agricultural and Veterinary Sciences, Medical and Health Sciences, Immunology, Medical microbiology

Abstract

The epithelial layer of the gastrointestinal tract contains invaginations, called glands or crypts, which are colonized by symbiotic and pathogenic microorganisms and may function as designated niches for certain species. Factors that control gland colonization are poorly understood, but bacterial chemotaxis aids occupation of these sites. We report here that a Helicobacter pylori cytoplasmic chemoreceptor, TlpD, is required for gland colonization in the stomach. tlpD mutants demonstrate gland colonization defects characterized by a reduction in the percentage of glands colonized but not in the number of bacteria per gland. Consistent with TlpD's reported role in reactive oxygen species (ROS) avoidance, tlpD mutants showed hallmarks of exposure to high ROS. To assess the role of host-generated ROS in TlpD-dependent gland colonization, we utilized mice that lack either the ability to generate epithelial hydrogen peroxide or immune cell superoxide. tlpD gland colonization defects were rescued to wild-type H. pylori levels in both of these mutants. These results suggest that multiple types of innate immune-generated ROS production limit gland colonization and that bacteria have evolved specific mechanisms to sense and direct their motility in response to this signal and thus spread throughout tissue.

Published

2018

2. Cooperation of two distinct coupling proteins creates chemosensory network connections

Author

Abedrabbo, Samar, Castellon, Juan, Collins, Kieran D, Johnson, Kevin S, and Ottemann, Karen M

Subjects

Infectious Diseases, Amino Acid Sequence, Bacterial Proteins, Carrier Proteins, Chemotaxis, Methyl-Accepting Chemotaxis Proteins, Phosphorylation, Protein Binding, Signal Transduction, signal transduction, scaffold, chemotaxis, chemoreceptor arrays

Abstract

Although it is appreciated that bacterial chemotaxis systems rely on coupling, also called scaffold, proteins to both connect input receptors with output kinases and build interkinase connections that allow signal amplification, it is not yet clear why many systems use more than one coupling protein. We examined the distinct functions for multiple coupling proteins in the bacterial chemotaxis system of Helicobacter pylori, which requires two nonredundant coupling proteins for chemotaxis: CheW and CheV1, a hybrid of a CheW and a phosphorylatable receiver domain. We report that CheV1 and CheW have largely redundant abilities to interact with chemoreceptors and the CheA kinase, and both similarly activated CheA's kinase activity. We discovered, however, that they are not redundant for formation of the higher order chemoreceptor arrays that are known to form via CheA-CheW interactions. In support of this possibility, we found that CheW and CheV1 interact with each other and with CheA independent of the chemoreceptors. Therefore, it seems that some microbes have modified array formation to require CheW and CheV1. Our data suggest that multiple coupling proteins may be used to provide flexibility in the chemoreceptor array formation.

Published

2017

3. The Helicobacter pylori CZB Cytoplasmic Chemoreceptor TlpD Forms an Autonomous Polar Chemotaxis Signaling Complex That Mediates a Tactic Response to Oxidative Stress

Author

Collins, Kieran D, Andermann, Tessa M, Draper, Jenny, Sanders, Lisa, Williams, Susan M, Araghi, Cameron, and Ottemann, Karen M

Subjects

Biochemistry and Cell Biology, Biological Sciences, Emerging Infectious Diseases, Infectious Diseases, Digestive Diseases, Digestive Diseases - (Peptic Ulcer), Infection, Bacterial Proteins, Chemotaxis, Gene Expression Regulation, Bacterial, Helicobacter pylori, Oxidative Stress, Signal Transduction, Agricultural and Veterinary Sciences, Medical and Health Sciences, Microbiology, Agricultural, veterinary and food sciences, Biological sciences, Biomedical and clinical sciences

Abstract

UnlabelledCytoplasmic chemoreceptors are widespread among prokaryotes but are far less understood than transmembrane chemoreceptors, despite being implicated in many processes. One such cytoplasmic chemoreceptor is Helicobacter pylori TlpD, which is required for stomach colonization and drives a chemotaxis response to cellular energy levels. Neither the signals sensed by TlpD nor its molecular mechanisms of action are known. We report here that TlpD functions independently of the other chemoreceptors. When TlpD is the sole chemoreceptor, it is able to localize to the pole and recruits CheW, CheA, and at least two CheV proteins to this location. It loses the normal membrane association that appears to be driven by interactions with other chemoreceptors and with CheW, CheV1, and CheA. These results suggest that TlpD can form an autonomous signaling unit. We further determined that TlpD mediates a repellent chemotaxis response to conditions that promote oxidative stress, including being in the presence of iron, hydrogen peroxide, paraquat, and metronidazole. Last, we found that all tested H. pylori strains express TlpD, whereas other chemoreceptors were present to various degrees. Our data suggest a model in which TlpD coordinates a signaling complex that responds to oxidative stress and may allow H. pylori to avoid areas of the stomach with high concentrations of reactive oxygen species.ImportanceHelicobacter pylori senses its environment with proteins called chemoreceptors. Chemoreceptors integrate this sensory information to affect flagellum-based motility in a process called chemotaxis. Chemotaxis is employed during infection and presumably aids H. pylori in encountering and colonizing preferred niches. A cytoplasmic chemoreceptor named TlpD is particularly important in this process, and we report here that this chemoreceptor is able to operate independently of other chemoreceptors to organize a chemotaxis signaling complex and mediate a repellent response to oxidative stress conditions. H. pylori encounters and must cope with oxidative stress during infection due to oxygen and reactive oxygen species produced by host cells. TlpD's repellent response may allow the bacteria to escape niches experiencing inflammation and elevated reactive oxygen species (ROS) production.

Published

2016

4. Internal Sense of Direction: Sensing and Signaling from Cytoplasmic Chemoreceptors

Author

Collins, Kieran D, Lacal, Jesus, and Ottemann, Karen M

Subjects

Biochemistry and Cell Biology, Biological Sciences, Archaea, Archaeal Proteins, Bacteria, Bacterial Proteins, Chemotaxis, Cytoplasm, Membrane Proteins, Models, Molecular, Signal Transduction, Technology, Medical and Health Sciences, Microbiology

Abstract

SummaryChemoreceptors sense environmental signals and drive chemotactic responses in Bacteria and Archaea. There are two main classes of chemoreceptors: integral inner membrane and soluble cytoplasmic proteins. The latter were identified more recently than integral membrane chemoreceptors and have been studied much less thoroughly. These cytoplasmic chemoreceptors are the subject of this review. Our analysis determined that 14% of bacterial and 43% of archaeal chemoreceptors are cytoplasmic, based on currently sequenced genomes. Cytoplasmic chemoreceptors appear to share the same key structural features as integral membrane chemoreceptors, including the formations of homodimers, trimers of dimers, and 12-nm hexagonal arrays within the cell. Cytoplasmic chemoreceptors exhibit varied subcellular locations, with some localizing to the poles and others appearing both cytoplasmic and polar. Some cytoplasmic chemoreceptors adopt more exotic locations, including the formations of exclusively internal clusters or moving dynamic clusters that coalesce at points of contact with other cells. Cytoplasmic chemoreceptors presumably sense signals within the cytoplasm and bear diverse signal input domains that are mostly N terminal to the domain that defines chemoreceptors, the so-called MA domain. Similar to the case for transmembrane receptors, our analysis suggests that the most common signal input domain is the PAS (Per-Arnt-Sim) domain, but a variety of other N-terminal domains exist. It is also common, however, for cytoplasmic chemoreceptors to have C-terminal domains that may function for signal input. The most common of these is the recently identified chemoreceptor zinc binding (CZB) domain, found in 8% of all cytoplasmic chemoreceptors. The widespread nature and diverse signal input domains suggest that these chemoreceptors can monitor a variety of cytoplasmically based signals, most of which remain to be determined.

Published

2014

5. Internal sense of direction: sensing and signaling from cytoplasmic chemoreceptors.

Author

Collins, Kieran D, Lacal, Jesus, and Ottemann, Karen M

Subjects

Cytoplasm, Bacteria, Archaea, Archaeal Proteins, Bacterial Proteins, Membrane Proteins, Signal Transduction, Chemotaxis, Models, Molecular, Models, Molecular, Microbiology, Biological Sciences, Medical and Health Sciences, Technology

Abstract

SummaryChemoreceptors sense environmental signals and drive chemotactic responses in Bacteria and Archaea. There are two main classes of chemoreceptors: integral inner membrane and soluble cytoplasmic proteins. The latter were identified more recently than integral membrane chemoreceptors and have been studied much less thoroughly. These cytoplasmic chemoreceptors are the subject of this review. Our analysis determined that 14% of bacterial and 43% of archaeal chemoreceptors are cytoplasmic, based on currently sequenced genomes. Cytoplasmic chemoreceptors appear to share the same key structural features as integral membrane chemoreceptors, including the formations of homodimers, trimers of dimers, and 12-nm hexagonal arrays within the cell. Cytoplasmic chemoreceptors exhibit varied subcellular locations, with some localizing to the poles and others appearing both cytoplasmic and polar. Some cytoplasmic chemoreceptors adopt more exotic locations, including the formations of exclusively internal clusters or moving dynamic clusters that coalesce at points of contact with other cells. Cytoplasmic chemoreceptors presumably sense signals within the cytoplasm and bear diverse signal input domains that are mostly N terminal to the domain that defines chemoreceptors, the so-called MA domain. Similar to the case for transmembrane receptors, our analysis suggests that the most common signal input domain is the PAS (Per-Arnt-Sim) domain, but a variety of other N-terminal domains exist. It is also common, however, for cytoplasmic chemoreceptors to have C-terminal domains that may function for signal input. The most common of these is the recently identified chemoreceptor zinc binding (CZB) domain, found in 8% of all cytoplasmic chemoreceptors. The widespread nature and diverse signal input domains suggest that these chemoreceptors can monitor a variety of cytoplasmically based signals, most of which remain to be determined.

Published

2014

6. TlpD mediates chemotactic repellent responses to reactive oxygen species that are relevant to Helicobacter pylori gastric gland colonization

Author

Collins, Kieran Dennehy

Subjects

Microbiology

Abstract

The human gastric pathogen Helicobacter pylori relies upon chemotaxis during early infection, although the system appears dispensable during later stages of infection. This body of work describes efforts to characterize the signals interpreted by the cytoplasmic chemoreceptor TlpD and gain insight into the role the chemoreceptor plays during infection. Results of this work suggest that TlpD mediates chemotactic repellent responses to stimuli that evoke reactive oxygen species (ROS) formation in the cytoplasm and that these responses are involved in H. pylori colonization of gastric glands. The first chapter serves as a review on chemotactic responses, and focuses on cytoplasmic chemoreceptors. This group of chemoreceptors are understudied relative to their transmembrane counterparts and are prevalent in both bacteria and archaea. An emphasis is placed on describing cytoplasmic chemoreceptors as a group, including likely ligand binding domains and their localization. The ensuing chapters describes basic aspects of TlpD chemotactic responses and their relevance to colonization of the gastric epithelium. TlpD was found to sense and respond to stimuli that provoke cytoplasmic ROS production independently of transmembrane chemoreceptors, which include extracellular iron, hydrogen peroxide and superoxide generators. These findings suggest that the chemoreceptor senses and responds to a yet unknown signal generated by oxidative stress imparted by ROS, which likely involve labile cytoplasmic iron pools. We go on to describe colonization defects of a tlpD mutant, which appears to be connected to gastric gland colonization. The gastric gland colonization defects noted in wild type hosts for a tlpD mutant were rescued in hosts that were deficient in ROS production at the gastric epithelium. These results suggested that TlpD-mediated chemotactic responses to ROS were involved in H. pylori gastric gland colonization, and could be involved in the spread of the bacteria between glands in response to ROS production. Finally we discuss mechanistic issues concerning TlpD recognition of ROS. Taken together these results have bolstered our basic understanding of TlpD signal transduction and the role of the chemoreceptor in host colonization.

Published

2017