Molecular basis of motor switch complex from Helicobacter pylori. / CUHK electronic theses & dissertations collection

January 2011

Lam, Kwok Ho. / Thesis (Ph.D.)--Chinese University of Hong Kong, 2011. / Includes bibliographical references (leaves 149-159). / Electronic reproduction. Hong Kong : Chinese University of Hong Kong, [2012] System requirements: Adobe Acrobat Reader. Available via World Wide Web. / Abstract also in Chinese.

Cellular signal transduction

Chemotaxis

Helicobacter pylori

Chemotaxis

Helicobacter Pylori

Signal Transduction

Chemotaxis of Sperm Cells / Spermien-Chemotaxis

Friedrich, Benjamin

19 February 2009

Sperm cells are guided to the egg by chemoattractants in many species. Sperm cells are propelled in a liquid by the regular beat of their flagellum. In the presence of a concentration gradient of a chemoattractant, they can steer upwards the concentration gradient, a process called chemotaxis. Eggs release chemoattractants to guide the sperm cells to the egg. Sperm chemotaxis is best studied experimentally in the sea urchin. There, specific receptors in the flagellar membrane of the sperm cells are activated upon binding of chemoattractant molecules and trigger a signaling cascade which ultimately changes the activity of the molecular motors which drive the flagellar beat and result in a swimming response. Sea urchin sperm cells swim along circular and helical paths. Sperm cells of the sea urchin and several other species swim along helical paths far from boundary surfaces in the absence of chemoattractant. In a two-dimensional experimental geometry, sperm swimming paths are planar circles. The non-zero curvature of their swimming paths is a direct consequence of an asymmetry of their flagellar beat. In a concentration gradient of chemoattractant, sperm swimming path are drifting circles in two dimensions and bend helices in three dimensions. What is the working mechanism of sperm chemotaxis? In this thesis, we develop a theoretical description of sperm chemotaxis which can be subsumed as follows: While swimming along an approximately circular path in a concentration gradient a sperm cell traces a periodic concentration stimulus from the concentration field that has the frequency of circular swimming. The chemotactic signaling system processes this stimulus and causes a periodic modulation of the curvature of the swimming path which then gives rise to a swimming path which is a drifting circle. The relative direction of the drift with respect to the gradient direction is determined by the phase shift between the stimulus and the curvature oscillations. This picture is in perfect agreement with recent experimental findings. The mechanism is more general and also works in three dimensions for swimming along helical paths. Our results. Our theoretical description of sperm chemotaxis clarifies the concepts underlying sperm chemotaxis. In particular, we derive the role of internal timing of the chemotactic signaling system for sperm chemotaxis. We conclude that sampling a concentration field along circular and helical paths is a robust strategy for chemotaxis that does not require fine-tuning of parameters and which works reliable also in the presence of fluctuations. In a last chapter of this thesis, we discuss sperm chemotaxis in the more general context of an abstract search problem.

sperm cells

chemotaxis

motility

signaling

Spermien

Chemotaxis

Motilität

Signalverarbeitung

ddc:530

rvk:UG 3100

Molecular and genetic assessment of selected antiporters and methyl-accepting chemotaxis proteins in Vibrio cholerae

Quinn, Matthew J.

05 December 2011

The pathogen Vibrio cholerae uses cations as a primary currency of virulence and environmental persistence, using gradients of those cations to move, acquire nutrients, and control virulence gene expression. An understanding of the overlapping roles of bioenergetics and chemotaxis in the virulence and environmental survival of V. cholerae issues from a large body of prior work, but the interplay of each component is not yet clearly understood. To this end, the activity of the antiporters Vc-NhaP1, Vc-NhaA, and Vc-NhaB was assayed, as was the sodium transporting respiratory pump NQR, and environmental stimuli were paired with potential motilitylinked sensors. The Vc-NhaP1 antiporter was found to be a K⁺(Na⁺)/H⁺ antiporter essential for V. cholerae growth at low environmental pH. Deletion of the V. cholerae nhaP1 gene caused growth inhibition when external potassium was either limited (100 mM and below) or in excess (400 mM and above). This growth defect was most apparent at mid-logarithmic phase, after 4-6 hours of culturing. Using a pH-sensitive GFP protein, cytosolic pH was shown to be dependent on K⁺ in acidic external conditions in a Vc-NhaP1-dependent manner. When functionally expressed in an antiporterless E. coli strain and assayed in everted membrane vesicles, Vc-NhaP1 operated as an electroneutral alkali cation/proton antiporter, exchanging K⁺ or Na⁺ ions for protons within a broad pH range (7.25 to 9.0). These data establish the putative V. cholerae NhaP1 protein as a functional K⁺(Na⁺)/H⁺ antiporter of the CPA- 1 family that is required for bacterial pH homeostasis and growth in an acidic environment. Further, a model system comprised of a V. cholerae strain lacking both the nqr operon and the ORFs of Vc-nhaA or Vc-nhaB was generated and tested with and without lactate. These strains, along with the single mutants of nqr, Vc-nhaA, and Vc-nhaB, were assessed for aerobic growth as a function of media pH and cation concentration (Na⁺, Li⁺, or K⁺). Loss of Vc-NhaA and, to a lesser extent, Vc-NhaB, was better observed when NQR was absent but lactate was added to facilitate replenishment of the quinone pool. Loss of Vc-NhaA in this background inhibited growth most at basic pH under increasing Na⁺ and Li⁺ conditions, and loss of Vc- NhaB in this background inhibited was most severe in acidic conditions in the presence of 0-100 mM Na⁺ or Li⁺. We also observed the growth inhibition of Vc- NhaA in the absence of NQR and in the presence of lactate and 100-450 mM Li⁺, which has not been previously reported. These growth defects were restored upon expression of the cognate antiporter gene on an inducible expression vector. Lastly, potential chemotaxis stimuli were correlated with cognate methyl-accepting chemotaxis protein (MCP) receptors. The homology of MCP sensory domains among Vibrionaceae demonstrated a subset were unique to V. cholerae. Of these unique MCPs, transposon insertion in VC0098 significantly reduced chemotaxis swarm diameter towards Na⁺ and K⁺. Additionally, the MCP VCA0663 was shown, by transposon mutagenesis and complementation, to direct chemotaxis towards N-acetylglucosamine. Additional observations are described concerning the chemotaxis defects incurred by transposon mutagenesis of MCPs in vitro towards mucin, bile, or L-serine. MCP strains were also tested in vivo for 4 and 24 hours in the infant mouse model of infection. None of the observed chemotaxis defects showed complete loss of chemotaxis by transposon mutagenesis, in line with the hypothesis that the large number of MCPs encoded by V. cholerae result in redundant chemotaxis sensory functions. These findings add to the understanding of how bioenergetics and chemotaxis interact within V. cholerae, a foundation from which the bacterium can be understood and, eventually, controlled. / Graduation date: 2012

cholerae

antiporter

chemotaxis

Vibrio cholerae

Membrane proteins

Chemotaxis

Bacterial genetics

Molecular microbiology

Microbial metabolism

Chemotaxis of Sperm Cells

Friedrich, Benjamin

17 February 2009

Sperm cells are guided to the egg by chemoattractants in many species. Sperm cells are propelled in a liquid by the regular beat of their flagellum. In the presence of a concentration gradient of a chemoattractant, they can steer upwards the concentration gradient, a process called chemotaxis. Eggs release chemoattractants to guide the sperm cells to the egg. Sperm chemotaxis is best studied experimentally in the sea urchin. There, specific receptors in the flagellar membrane of the sperm cells are activated upon binding of chemoattractant molecules and trigger a signaling cascade which ultimately changes the activity of the molecular motors which drive the flagellar beat and result in a swimming response. Sea urchin sperm cells swim along circular and helical paths. Sperm cells of the sea urchin and several other species swim along helical paths far from boundary surfaces in the absence of chemoattractant. In a two-dimensional experimental geometry, sperm swimming paths are planar circles. The non-zero curvature of their swimming paths is a direct consequence of an asymmetry of their flagellar beat. In a concentration gradient of chemoattractant, sperm swimming path are drifting circles in two dimensions and bend helices in three dimensions. What is the working mechanism of sperm chemotaxis? In this thesis, we develop a theoretical description of sperm chemotaxis which can be subsumed as follows: While swimming along an approximately circular path in a concentration gradient a sperm cell traces a periodic concentration stimulus from the concentration field that has the frequency of circular swimming. The chemotactic signaling system processes this stimulus and causes a periodic modulation of the curvature of the swimming path which then gives rise to a swimming path which is a drifting circle. The relative direction of the drift with respect to the gradient direction is determined by the phase shift between the stimulus and the curvature oscillations. This picture is in perfect agreement with recent experimental findings. The mechanism is more general and also works in three dimensions for swimming along helical paths. Our results. Our theoretical description of sperm chemotaxis clarifies the concepts underlying sperm chemotaxis. In particular, we derive the role of internal timing of the chemotactic signaling system for sperm chemotaxis. We conclude that sampling a concentration field along circular and helical paths is a robust strategy for chemotaxis that does not require fine-tuning of parameters and which works reliable also in the presence of fluctuations. In a last chapter of this thesis, we discuss sperm chemotaxis in the more general context of an abstract search problem.

info:eu-repo/classification/ddc/530

ddc:530

EXPRESSION AND CHARACTERIZATION OF TOLL-LIKE RECEPTOR 10

2016 March 1900

Toll-like receptors (TLRs), named after toll proteins identified in Drosophila melanogaster, are the pattern recognition receptors in the innate immune system that detect microbes. TLRs are mono, membrane-spanning, as well as non-catalytic receptors, which are mainly expressed in sentinel cells, such as the dendritic cells, neutrophils and macrophages. While humans have ten TLRs (TLR 1 to 10), the mouse has another three (TLRs 11, 12, 13). TLRs are made up of glycoproteins, which have luminal ligand-binding sites consisting of leucine-rich repeat (LRR) for detection of pathogens leading to activation of immune cells. TLR1, 2, 4, and 6 are responsible for recognition of lipids (such as triacetylated lipopeptide), peptidoglycan, and lipopolysaccharide (LPS). However, the TLR3, 7, 8, and 9 mainly recognize nucleic acids, such as double-stranded RNA (dsRNA) and CpG DNA, while the TLR13 detects ribosomal RNA sequences. So far, there are no data on the localization and immunological functions of TLR10. I studied the expression, localization and role of TLR10 in S. pneumoniae infection. First, I examined the expression of TLR10 in lungs of pig, cattle, dog, rat, and chickens. The light and electron microscopic data show TLR10 expression in vascular endothelium and smooth muscles in lungs of control and inflamed animals. Further, we found altered basal level of expression and localization of TLR10 in bovine neutrophils treated with E. coli lipopolysaccharide. These data show the expression of TLR10 in the lungs of tested animal species, and its alteration by LPS in bovine neutrophils. The next study was designed to investigate the regulation of TLR10 expression and to address its role in neutrophil chemotaxis. E. coli LPS activated human neutrophils showed temporal and spatial change in TLR10 expression. Confocal microscopy showed cytosolic and nuclear distribution of TLR10 in normal and activated neutrophils. TLR10 in E. coli LPS-activated neutrophils colocalized with flotallin-1, a lipid raft marker, and EEA-1, an early endosomal marker, suggested its endocytosis. Live cell imaging of LPS activated neutrophils showed TLR10 translocation to the leading edge. Neutrophils upon TLR10 knockdown were unable for fMLP-induced migration. TLR10 knockdown reduced the number of membrane pseudopods in activated neutrophils without altering the expression of key proteins of actin nucleation process, ARP-3 and Diap1. These data show TLR4-mediated pathway for regulation of TLR10 expression, and that TLR10 may have a role in neutrophil chemotaxis. Next, I examined the role of TLR10 in innate immune response to S. pneumoniae infection in U937 human macrophage cell line. S. pneumoniae are major causative agents of pneumonia, meningitis and bacteremia. A significant increase in TLR10 mRNA expression was found in S. pneumoniae (107 cfu for 6hr) challenged macrophages. TLR10 knockdown significantly reduced production of IL-1β, IL-8, IL-17 and TNF-α and no significant change in IL-10 expression, and also significantly diminished nuclear translocation of NF-κB but without affecting the phagocytosis of S. pneumoniae. Altogether, I report the that TLR10 is expressed in the normal and inflamed lungs in cattle, pigs, dogs, rats, chickens and humans. The expression of TLR10 is altered in activated neutrophils, and it plays a role in neutrophils chemotaxis and production of pro-inflammatory cytokines in macrophages infected with S. pneumoniae.

Toll-like receptors

neutrophils

macrophages

chemotaxis

inflammation

Streptococcus pneumoniae

The C-Terminus of Transmembrane Helix 2 (TM2) of the Escherichia coli Tar Chemorecptor Determines Signal Output and Ligand Sensitivity

Adase, Christopher A. 1981-

14 March 2013

Methyl-accepting chemotaxis proteins MCPs can bind one or more receptor- specific ligands. In the case of the Tar MCP of Escherichia coli (TarEc), a primary attractant ligand is aspartate. Its binding to the periplasmic domain of Tar generates a conformational change that is transmitted via helix 4 transmembrane helix 2 (TM2). An inward movement of TM2 initiates a transmembrane signal to the cytoplasmic HAMP (histidine kinases, adenyl cyclases, methyl-accepting proteins, phosphatases) domain. Baseline CheA kinase-stimulating activity and ligand-induced responses are both strongly influenced by residues at the C-terminus of transmembrane helix 2 (TM2). The cytoplasmic aromatic anchor, composed of residues Trp-209 and Tyr-210 in TarEc, is of particular importance. These residues are not highly conserved among transmembrane receptors having a HAMP domain, although there are almost always some aromatic residues in this region. The question thus becomes what properties of this aromatic anchor are necessary for proper signal transduction. In this dissertation, I studied the effect on TarEc function by substituting all possible combinations of Ala, Phe, Tyr, and Trp at positions 209 and 210. This library of TarEc variants allowed the direct assessment of the effect of the residue composition of the aromatic anchor and led to a model of how the wild-type anchor maintains the base-line signaling state in TarEc. Additional receptor variants containing double aromatic tandems and Ala substitutions for the periplasmic Trp residue were created, and the aromatic residues were also shifted in position within the six residues 207-212. Trp, Tyr, and Phe, in that order, had the greatest effect on function when they were moved to novel positions. It was also discovered that Gly-211 plays a critical role in maintaining receptor function. A model was generated that proposes that Gly-211 plays a role in maintaining the flexibility of the TM2-HAMP domain connector. The results suggest that the signaling properties of the transmembrane sensor kinases of two-component systems can be predicted by the nature of their TM2-HAMP connections. It may also be possible to modulate their activity in a controlled way by manipulating the amino acid sequences that comprise those connections.

Transmembrane communication

Chemoreceptor

Signal transduction

Two component signaling

Chemotaxis

Structural studies of chemotaxis in prokaryotes and higher eukaryotes

Bell, Christian H.

January 2011

Chemotaxis, the ability of a cell to change its motility as a response to environmental stimuli, belongs to the most important signal transduction mechanisms in life. Evolution has created a plethora of different molecular mechanisms to enable cells to react appropriately to extracellular changes. In this thesis, chemotactic signal transduction pathways in bacteria, in particular two component signalling in R. sphaeroides, and eukaryotes, in particular human axon guidance, are studied by means of X-ray crystallography complemented with biophysical, biochemical and cellular studies. Two-component signal transduction in bacteria is one of the most abundant signalling pathways in biology. Here the determinants for specificity for a crucial sensor kinase-response regulator interaction are presented and used to design novel, synthetic two-component pairs. The activation mechanism of response regulators has been extensively studied and a model for activation that crucially involves a Thr and a Tyr residue has been widely accepted in the field. In this thesis, two structures of a response regulator from R. sphaeroides are presented and together with biophysical and cellular assays suggest a novel paradigm for response regulator activation. Axon guidance is an essential process in human development and relies crucially on chemotaxis. Two signalling pathways, the plexin-semaphorin and the Rgm-Neogenin pathway are studied extensively in this work. Structures of the intracellular region of Plexin-B1 provide an elegant mechanism explaining how ligand binding events on the extracellular and intracellular side can be integrated into a single signalling output. The study of RgmB in complex with its receptor Neogenin provides the first structural insight into the important family of repulsive guidance molecules and explains their role in the disease juvenile hemachromatosis. In summary, this work provides insights into a plethora of chemotactic pathways and extends our current knowledge of these important mechanisms significantly.

579.3

Biogenèse de la pellicule chez Shewanella oneidensis / Pellicle biogenesis in Shewanella oneidensis

Gambari, Cyril

16 July 2018

La bactérie aquatique Shewanella oneidensis est capable, en condition statique et en présence d'oxygène, de former un biofilm à l'interface air-liquide, appelé pellicule. Mon travail a porté sur la biogenèse de la pellicule.Il a été montré dans le groupe que le régulateur de réponse du système chimiotactique, la protéine CheY3, était impliqué dans la biogenèse de la pellicule. Cette protéine est essentielle dans les étapes précoces et tardives de sa formation alors que son partenaire habituel, CheA3, semble ne jouer un rôle que dans les étapes tardives. Mon travail s'est focalisé sur la recherche de partenaires de CheY3.J'ai introduit une banque d'ADN génomique de S. oneidensis dans la souche ΔcheY3 et j'ai cherché des gènes dont la surexpression permettait de restaurer la formation de la pellicule. Cette approche a révélé deux gènes pdgA et pdgB. J'ai montré que les protéines PdgA et PdgB étaient capables de synthétiser du di-GMPc, suggérant que ce messager secondaire est impliqué dans la biogenèse de la pellicule. L'hydrolyse du di-GMPc par des enzymes dédiées empêche en effet sa formation.J'ai montré que l'opéron mxd, contrôlant la synthèse d'exopolysaccharides dans les biofilms de surface, était impliqué dans la formation de la pellicule. La première protéine codée par cet opéron, MxdA, est capable de lier le di-GMPc. Des expériences de pontage chimique et de double hybride ont révélé que MxdA, CheY3, PdgA et PdgB, formaient un réseau de régulation gouvernant la biogenèse de la pellicule.J'ai montré que les systèmes à deux composants BarA/UvrY et ArcS/ArcA contrôlant la transcription de l'opéron mxd sont aussi impliqués dans la formation du biofilm flottant. / The aquatic bacterium Shewanella oneidensis is able to form, under static conditions and in the presence of oxygen, a biofilm at the air-liquid interface, called pellicle. My work was focused on the biogenesis of this pellicle.It was previously shown in the team that, surprisingly, the CheY3 protein, the response regulator of the chemotactic regulatory system, is involved in the biogenesis of the pellicle. This protein was shown to be essential both in early and late steps of pellicle formation whereas its usual partner, the kinase CheA3, seems to play a role in the late steps only. I was therefore looked for the partners of the CheY3 protein for pellicle formation.For this purpose, I have introduced a multi-copy genomic library in the ΔcheY3 strain and searched for genes whose overexpression allowed pellicle restoration. Strikingly, this approach revealed two genes pdgA and pdgB. Interestingly, we showed that PdgA and PdgB proteins are able to synthesize c-di-GMP, suggesting a role for this second messenger in pellicle biogenesis. Indeed, c-di-GMP hydrolysis by dedicated enzymes blocks pellicle formation.We also showed that the mxd operon, controlling the exopolysaccharides synthesis in biofilm associated with a solid surface, is also involved in pellicle formation. Moreover, the first protein encoded by this operon, MxdA, is able to bind c-di-GMP. Cross-linking and bacterial two-hybrid experiments revealed that MxdA, CheY3, PdgA and PdgB, form a complex regulatory pathway governing the biogenesis of the pellicle.Finally, we have shown that the two-component systems BarA/UvrY and ArcS/ArcA, controlling the mxd transcription, are also involved in pellicle formation.

Biofilm

Shewanella

Régulation

Chimiotactisme

Biofilm

Shewanella

Regulation

Chemotaxis

570

Function and Activation Mechanism of PLEKHG2, A Novel G Beta Gamma-Activated RhoGEF in Leukemia Cells

Runne, Caitlin M.

01 July 2013

The Rho family of GTPases plays a crucial role in the regulation of diverse cellular processes, including proliferation and actin cytoskeletal rearrangement to promote cell migration. However, dysregulation of RhoGTPases has been associated with disease, particularly cancers such as leukemia. Despite this, RhoGTPases are rarely mutated in cancer. Rather, dysregulation of their regulatory proteins through mutation or overexpression contributes to disease pathogenesis. RhoGTPases are activated through Rho guanine nucleotide exchange factors (GEFs). Although over eighty RhoGEFs have been identified that activate the 25 RhoGTPases, the pathological role of the majority of these proteins remains unclear. Further, whereas the majority of RhoGEFs are activated through tyrosine phosphorylation, a small subset can be activated through heterotrimeric G proteins, including through GΒ;Γ; subunits. However, the mechanism by which GΒ;Γ; induces RhoGEF activation remains unclear. PLEKHG2 is a Dbl family RhoGEF that was originally identified as a gene upregulated in a leukemia mouse model, and later shown to be activated by heterotrimeric G protein Β;Γ; subunits. However, its function and activation mechanisms remain elusive. Here we show that, as compared to primary human T cells, the expression of PLEKHG2 is upregulated in leukemia cell lines. Downregulation of PLEKHG2 by siRNAs specifically inhibited GΒ;Γ;-stimulated Rac and Cdc42, but not RhoA activation. Consequently, inhibition of PLEKHG2 blocked actin polymerization, protrusion formation, and leukemia cell migration in response to SDF1alpha;. Additional studies indicate that GΒ;Γ; likely activates PLEKHG2 by binding the N-terminus of PLEKHG2. This interaction results in the release of autoinhibition imposed by the C-terminus within a region encompassing the catalytic DH domain. As a result, overexpressing either the N-terminus of PLEKHG2 that binds GΒ;Γ; or the C-terminus that autoinhibits PLEKHG2 blocked GΒ;Γ;-stimulated Rac and Cdc42 activation and the ability of leukemia cell to form membrane protrusions and to migrate. Together, our results have demonstrated that PLEKHG2 functions as a novel GΒ;Γ; -stimulated RhoGEF that could contribute to chemokine-induced leukemia cell dissemination and leukemia pathogenesis.

Chemotaxis

GPCR

G proteins

Heterotrimeric G protein

Leukemia

PLEKHG2

Pharmacology

Mast Cell Migration in Inflammatory Diseases

Olsson, Niclas

January 2003

<p>Mast cells (MCs) are forceful multifunctional effector cells of the immune system. MCs are normally distributed throughout connective and mucosal tissues, but in several pathological conditions accumulation of MCs occur. This accumulation is probable due to directed migration of MCs and they are subjects for migration at least two different occations: 1) when they are recruited as progenitor cells from the blood into the tissue; and 2) when they as mature MCs are recruited to sites of inflammation. The aim of this study was to investigate MC migration to chemoattractants released <i>in vivo</i> or <i>in vitro</i> (body fluids collected from patients with asthma or rheumatoid arthritis and T_H1- and T_H2-cytokines) and to recombinant cytokines (transforming growth factor -β (TGF-β) and CCL5/RANTES).</p><p>This thesis shows that bronchoalveolar lavage (BAL) fluid from asthmatic patients and synovial fluid from patients with rheumatiod arthritis contain MC chemoattractants, and that part of the chemotactic activity can be related to the presence of stem cell factor (SCF) and TGF-β. We also show that MC chemotactic activity during pollen season is significantly increased compared to before pollen season. Furthermore, we demonstrate that TGF-β isoforms, CCL5, TNF-α and IL-4 act as MC chemoattractants in a bellshaped dose- dependent manner. TGF-β proved to be an extremely potent attractant giving an optimal migratory response at 40fM and TGF-β3 being the most effective isoform. The chemokine CCL5 induced migration through interaction with the receptors CCR1 and CCR4 expressed on MC. Furthermore, we also found that TNF-α produced by T_H1-lymphocytes and IL-4 produced by T_H2-lymphocytes are MC chemoattractants.</p><p>In conclusion, with this thesis we have identified six new human mast cell chemoattractants and provide evidence that BAL fluid and synovial fluid from patients with asthma and rheumatoid arthritis, respectivly, contain MC chemoattractants. This information provides important clues in understanding the mechanisms behind MC recruitment to sites of inflammation.</p>

Pathology

Mast cells

chemotaxis

inflammation

Patologi

Pathology

Patologi