Host and pathogen sensory systems as targets for therapeutic intervention

Kindrachuk, K. Jason

31 July 2007

A new paradigm for the treatment of infectious disease is through the modulation of innate immune responses. In this capacity, host defense peptides (HDPs) and synthetic Toll-like receptor 9 (TLR9) ligands have the greatest demonstrated potentials. The work presented here considers mechanisms for the improvement of these treatments through optimization, or in the case of HDPs the minimization, of the interactions of these ligands with sensory receptors.<p>Toll-like Receptor 9 activates the innate immune system in response to microbial DNA or immune-modulating oligodeoxynucleotides. While cell stimulation experiments demonstrate the preferential activating ability of CpG-containing nucleic acids, direct binding investigations have reached contradictory conclusions regarding the sequence-specificity of TLR9 ligand binding. To address this discrepancy the characterization of human TLR9 ligand binding properties is reported. TLR9 has a high degree of ligand specificity in being able to discriminate not only CpG dinucleotides, but also higher order six nucleotide motifs that mediate species-specific activation. However, TLR9 ligand binding is also functionally influenced by nucleic acids in a sequence-independent manner both in vitro and in cell proliferation experiments. A model is proposed in which TLR9 activation is mediated specifically by CpG-containing ligands while sensitivity of the receptor is modulated by the absolute concentration of nucleic acids in a sequence-independent fashion. <p>Host defense peptides are among the leading candidates to combat antibiotic resistant bacterial strains. Recently, HDPs have been demonstrated to function as ligands for the bacterial sensory kinase PhoQ resulting in the induction of virulence and adaptive responses. Thus, concerns have been raised regarding therapeutic applications of HDPs. Here a methodology is described that permits discrimination and quantification of the distinct, but related, peptide behaviors of direct antimicrobial activity and PhoQ ligand potential. Utilizing peptide derivatives of the model HDP Bac2A it is demonstrated that antimicrobial efficiency is significantly, and inversely, related to PhoQ ligand efficacy. This provides a rational basis for HDP selection with greater therapeutic potential and minimized potential for initiation of bacterial resistance.

immunomodulation

PhoPQ

antimicrobial peptide

host defense peptide

ODN

CpG

TLR

Host and pathogen sensory systems as targets for therapeutic intervention

Kindrachuk, K. Jason

31 July 2007

A new paradigm for the treatment of infectious disease is through the modulation of innate immune responses. In this capacity, host defense peptides (HDPs) and synthetic Toll-like receptor 9 (TLR9) ligands have the greatest demonstrated potentials. The work presented here considers mechanisms for the improvement of these treatments through optimization, or in the case of HDPs the minimization, of the interactions of these ligands with sensory receptors.<p>Toll-like Receptor 9 activates the innate immune system in response to microbial DNA or immune-modulating oligodeoxynucleotides. While cell stimulation experiments demonstrate the preferential activating ability of CpG-containing nucleic acids, direct binding investigations have reached contradictory conclusions regarding the sequence-specificity of TLR9 ligand binding. To address this discrepancy the characterization of human TLR9 ligand binding properties is reported. TLR9 has a high degree of ligand specificity in being able to discriminate not only CpG dinucleotides, but also higher order six nucleotide motifs that mediate species-specific activation. However, TLR9 ligand binding is also functionally influenced by nucleic acids in a sequence-independent manner both in vitro and in cell proliferation experiments. A model is proposed in which TLR9 activation is mediated specifically by CpG-containing ligands while sensitivity of the receptor is modulated by the absolute concentration of nucleic acids in a sequence-independent fashion. <p>Host defense peptides are among the leading candidates to combat antibiotic resistant bacterial strains. Recently, HDPs have been demonstrated to function as ligands for the bacterial sensory kinase PhoQ resulting in the induction of virulence and adaptive responses. Thus, concerns have been raised regarding therapeutic applications of HDPs. Here a methodology is described that permits discrimination and quantification of the distinct, but related, peptide behaviors of direct antimicrobial activity and PhoQ ligand potential. Utilizing peptide derivatives of the model HDP Bac2A it is demonstrated that antimicrobial efficiency is significantly, and inversely, related to PhoQ ligand efficacy. This provides a rational basis for HDP selection with greater therapeutic potential and minimized potential for initiation of bacterial resistance.

immunomodulation

PhoPQ

antimicrobial peptide

host defense peptide

ODN

CpG

TLR

Structure of an Inner Membrane Protein Required for PhoPQ-Regulated Increases in Outer Membrane Cardiolipin

Fan, Junping, Petersen, Erik M., Hinds, Thomas R., Zheng, Ning, Miller, Samuel I.

01 January 2020

The Salmonella enterica subsp. enterica serovar Typhimurium PhoPQ two-component system is activated within the intracellular phagosome environment, where it promotes remodeling of the outer membrane and resistance to innate immune antimicrobial peptides. Maintenance of the PhoPQ-regulated outer membrane barrier requires PbgA, an inner membrane protein with a transmembrane domain essential for growth, and a periplasmic domain required for PhoPQ-activated increases in outer membrane cardiolipin. Here, we report the crystal structure of cardiolipin-bound PbgA, adopting a novel transmembrane fold that features a cardiolipin binding site in close proximity to a long and deep cleft spanning the lipid bilayer. The end of the cleft extends into the periplasmic domain of the protein, which is structurally coupled to the transmembrane domain via a functionally critical C-terminal helix. In conjunction with a conserved putative catalytic dyad situated at the middle of the cleft, our structural and mutational analyses suggest that PbgA is a multifunction membrane protein that mediates cardiolipin transport, a function essential for growth, and perhaps catalysis of an unknown enzymatic reaction. IMPORTANCE Gram-negative bacteria cause many types of infections and have become increasingly resistant to available antibiotic drugs. The outer membrane serves as an important barrier that protects bacteria against antibiotics and other toxic compounds. This outer membrane barrier function is regulated when bacteria are in host environments, and the protein PbgA contributes significantly to this increased barrier function by transporting cardiolipin to the outer membrane. We determined the crystal structure of PbgA in complex with cardiolipin and propose a model for its function. Knowledge of the mechanisms of outer membrane assembly and integrity can greatly contribute to the development of new and effective antibiotics, and this structural information may be useful in this regard.

CL transport

outer membrane barrier

PbgA

PhoPQ

salmonellae

Health Sciences

Identification et caractérisation de la régulation de systèmes à deux composants impliqués dans la virulence de Salmonella Typhimurium par des ARN régulateurs

Bouchard, Marie-Pier

January 2015

Les maladies infectieuses d’origine alimentaire demeurent un enjeu d'actualité dans les pays industriels comme le Canada. Les différentes agences gouvernementales impliquées dans le suivi et la prévention de ces infections soulèvent l’importance de l'apparition de souches multi-résistantes aux antibiotiques entre autres chez la bactérie pathogène Salmonella. L’antibiothérapie classique n'étant plus une solution au problème, le développement de nouveaux traitements spécifiques aux pathogènes en commençant par une meilleure compréhension de leur virulence devient essentiel. Lors d'une infection, une bactérie du genre Salmonella modifie grandement son transcriptome pour s'adapter et proliférer grâce à des systèmes à deux composants (S2C) tels que PhoP/PhoQ, OmpR/EnvZ et SsrA/SsrB. La régulation de ces systèmes soulève encore énormément de questions principalement au niveau post-transcriptionnel. Dans le cadre de ma maîtrise, j’ai adapté une méthode me permettant d’identifier les partenaires d’interaction des ARN de système à deux composants PhoP/PhoQ et OmpR/EnvZ en plus d’établir une banque d’annotation primaire pour des petits ARN non-codants de la bactérie pathogène Salmonella Typhimurium. Les résultats obtenus m’ont permis de valider un modèle de régulation connu par un petit ARN régulateur (pARNr) pour le gène phoP ainsi que d’identifier un nouveau modèle de régulation des S2C basé sur l’expression d’un ARN antisens en cis. De plus, des données préliminaires suggèrent une double fonction pour l’ARNm ompR.

Salmonella

Système à deux composants

PhoPQ

OmpR/EnvZ

ARN régulateur

ARN antisens

Régulation

PhoPQ- and PmrAB-mediated Lipopolysaccharide Modification and Cationic Antimicrobial Peptide Resistance in <i>Salmonella enterica</i> Serovars Typhimurium and Typhi

Richards, Susan Michelle

16 December 2010

No description available.

Biomedical Research

Microbiology

Salmonella

Antimicrobial Peptides

Lipopolysaccharide

Two-Component Regulatory Systems

PhoPQ

PmrAB