Home  About us  Contact
 

Mucosal Pathogens (mucosal + pathogen)

Distribution by Scientific Domains
Life Sciences60%

Selected Abstracts

Glycolipid receptor depletion as an approach to specific antimicrobial therapy

FEMS MICROBIOLOGY LETTERS, Issue 1 2006
Majlis Svensson
Abstract Mucosal pathogens recognize glycoconjugate receptors at the site of infection, and attachment is an essential first step in disease pathogenesis. Inhibition of attachment may prevent disease, and several approaches have been explored. This review discusses the prevention of bacterial attachment and disease by agents that modify the glycosylation of cell surface glycoconjugates. Glycosylation inhibitors were tested in the urinary tract infection model, where P-fimbriated Escherichia coli rely on glycosphingolipid receptors for attachment and tissue attack. N -butyldeoxynojirimycin blocked the expression of glucosylceramide-derived glycosphingolipids and attachment was reduced. Bacterial persistence in the kidneys was impaired and the inflammatory response was abrogated. N -butyldeoxynojirimycin was inactive against strains which failed to engage these receptors, including type 1 fimbriated or nonadhesive strains. In vivo attachment has been successfully prevented by soluble receptor analogues, but there is little clinical experience of such inhibitors. Large-scale synthesis of complex carbohydrates, which could be used as attachment inhibitors, remains a technical challenge. Antibodies to bacterial lectins involved in attachment may be efficient inhibitors, and fimbrial vaccines have been developed. Glycosylation inhibitors have been shown to be safe and efficient in patients with lipid storage disease and might therefore be tested in urinary tract infection. This approach differs from current therapies, including antibiotics, in that it targets the pathogens which recognize these receptors. [source]

Expression screening of integral membrane proteins from Helicobacter pylori 26695

PROTEIN SCIENCE, Issue 12 2007
Georgios Psakis
Abstract The efficiency of Helicobacter pylori as a mucosal pathogen is caused by unique soluble and integral membrane proteins, which allow its survival at acidic pH and successful colonization of the gastric environment. With about one-fourth of the H. pylori's proteome comprising integral membrane proteins, the need for solution of their three-dimensional (3D) structures becomes persistent as it can potentially drive the generation of more effective drugs. This study presents a medium-throughput approach for cloning and expression screening of integral membrane proteins from H. pylori (26695) using Escherichia coli as the expression host. One-hundred sixteen H. pylori targets were cloned into two different vector systems and heterologously expressed in E. coli. Eighty-four percent of these proteins displayed medium to high expression. No clear-cut correlation was found between expression levels and number of putative transmembrane spans, predicted functionality, and molecular mass. Nonetheless, expression of transporters and hypothetical proteins ,40 kDa with two to four transmembrane spans displayed generally high expression levels. To statistically strengthen the quality of the data from the medium-throughput approach, a comparison with data derived from robotic-based methodologies was conducted. Optimization of expression and solubilization conditions for selected targets was also performed. Seventeen targets have been purified and subjected to crystallization so far. Eighteen percent of these targets (2/17) produced crystals under specific sets of crystallization conditions. [source]

Developing live Shigella vaccines using , Red recombineering

FEMS IMMUNOLOGY & MEDICAL MICROBIOLOGY, Issue 3 2006
Ryan T. Ranallo
Abstract Live attenuated Shigella vaccines have shown promise in inducing protective immune responses in human clinical trials and as carriers of heterologous antigens from other mucosal pathogens. In the past, construction of Shigella vaccine strains relied on classical allelic exchange systems to genetically engineer the bacterial genome. These systems require extensive in vitro engineering of long homologous sequences to create recombinant replication-defective plasmids or phage. Alternatively, the ,red recombination system from bacteriophage facilitates recombination with as little as 40 bp of homologous DNA. The process, referred to as recombineering, typically uses an inducible ,red operon on a temperature-sensitive plasmid and optimal transformation conditions to integrate linear antibiotic resistance cassettes flanked by homologous sequences into a bacterial genome. Recent advances in recombineering have enabled modification of genomic DNA from bacterial pathogens including Salmonella, Yersinia, enteropathogenic Escherichia coli, or enterohemorrhagic E. coli and Shigella. These advances in recombineering have been used to systematically delete virulence-associated genes from Shigella, creating a number of isogenic strains from multiple Shigella serotypes. These strains have been characterized for attenuation using both in vivo and in vitro assays. Based on this data, prototypic Shigella vaccine strains containing multiple deletions in virulence-associated genes have been generated. [source]

Carcinoembryonic antigen-related cell adhesion molecule (CEACAM)-binding recombinant polypeptide confers protection against infection by respiratory and urogenital pathogens

MOLECULAR MICROBIOLOGY, Issue 5 2005
Darryl J. Hill
Summary The human-specific pathogens Neisseria meningitidis, N. gonorrhoea, Haemophilus influenzae and Moraxella catarrhalis share the property of targeting the carcinoembryonic antigen (CEA)-related cell adhesion molecules (CEACAMs) expressed on human epithelia. CEACAMs are signalling receptors implicated in cell adhesion and regulation of several physiological functions. Their targeting by pathogens can lead to tissue invasion. Although the CEACAM-binding ligands of the bacteria are structurally diverse, they target a common site on the receptor. We have generated a recombinant polypeptide that blocks the interactions of the mucosal pathogens with human epithelial cells and antibodies against it inhibit M. catarrhalis interactions with the receptor. As such, it is a potential antimicrobial agent to prevent infection via a strategy unlikely to promote bacterial resistance and a vaccine candidate against M. catarrhalis. In addition, it could serve more widely as a novel research tool and as a potential therapeutic agent in CEACAM-based physiological disorders. [source]

Carcinoembryonic antigens are targeted by diverse strains of typable and non-typable Haemophilus influenzae

MOLECULAR MICROBIOLOGY, Issue 4 2000
Mumtaz Virji
Haemophilus influenzae (Hi), a commensal of the human respiratory mucosa, is an important cause of localized and systemic infections. We show that distinct strains belonging to typable (THi) and non-typable (NTHi) H. influenzae target human carcinoembryonic antigens (the membrane associated CEA family of cell adhesion molecules, are now termed CEACAMs). All strains of H. influenzae biogroup aegyptius (Hi-aeg) and more than 70% of THi and NTHi strains tested specifically recognize CEACAMI-Fc soluble constructs. Furthermore, transfection of Chinese hamster ovary cells with human CEACAM1 cDNA alone was sufficient for promoting Hi interactions with the transfected cells. The majority of the Hi-aeg strains tested interacted with soluble constructs containing only the N-terminal domain. In contrast, several THi and NTHi strains reacted with soluble constructs only when additional extracellular A and B domains of the receptor were present. The use of monoclonal antibodies confirmed that THi and NTHi strains also interact primarily at the N-domain. We used site-directed mutants of CEACAM1 that contained substitutions at surface exposed amino acids and a molecular model of the N-domain to identify the residues involved in interactions with Hi ligands. The studies show that a common region exposed at the CFG face of the molecule is targeted by diverse Hi strains. However, mutation at distinct sites within this area affected the interactions of distinct strains signifying the potential for tissue tropism via this receptor. Analyses of the molecular basis of interaction with human cell lines and purified CEA show that Hi strains, especially those belonging to Hi-aeg, interact with multiple CEACAMs. Because Neisseria meningitidis (Nm) strains are also known to bind at the CFG face of the receptor, we used Nm and Hi strains in co-infection experiments and demonstrate competition between these mucosal pathogens in colonization of target cells via CEACAMs. [source]