Topology of the membrane-bound form of complement protein C9 probed by glycosylation mapping, anti-peptide antibody binding, and disulfide modification

Rossi, Véronique; Esser, Alfred F.

doi:10.1016/j.molimm.2010.01.013

Cited by 7 publications

(6 citation statements)

References 40 publications

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“…C 3 protein is able to bind to the LPS of bacteria and provides the scaffold for the membrane attack complex [84], [85]. The binding of the C 9 protein completes the membrane attack complex, which leads to bacterial death [85], [86], [87]. Our experiments indicate that while only residual amounts of C 3 bind Sg1 (Figure 7D i), significant quantities were detected on the Sg6 surface (Figure 7D iii).…”

Section: Resultsmentioning

confidence: 67%

Comparative Genomics Reveal That Host-Innate Immune Responses Influence the Clinical Prevalence of Legionella pneumophila Serogroups

et al. 2013

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Legionella pneumophila is the primary etiologic agent of legionellosis, a potentially fatal respiratory illness. Amongst the sixteen described L. pneumophila serogroups, a majority of the clinical infections diagnosed using standard methods are serogroup 1 (Sg1). This high clinical prevalence of Sg1 is hypothesized to be linked to environmental specific advantages and/or to increased virulence of strains belonging to Sg1. The genetic determinants for this prevalence remain unknown primarily due to the limited genomic information available for non-Sg1 clinical strains. Through a systematic attempt to culture Legionella from patient respiratory samples, we have previously reported that 34% of all culture confirmed legionellosis cases in Ontario (n = 351) are caused by non-Sg1 Legionella. Phylogenetic analysis combining multiple-locus variable number tandem repeat analysis and sequence based typing profiles of all non-Sg1 identified that L. pneumophila clinical strains (n = 73) belonging to the two most prevalent molecular types were Sg6. We conducted whole genome sequencing of two strains representative of these sequence types and one distant neighbour. Comparative genomics of the three L. pneumophila Sg6 genomes reported here with published L. pneumophila serogroup 1 genomes identified genetic differences in the O-antigen biosynthetic cluster. Comparative optical mapping analysis between Sg6 and Sg1 further corroborated this finding. We confirmed an altered O-antigen profile of Sg6, and tested its possible effects on growth and replication in in vitro biological models and experimental murine infections. Our data indicates that while clinical Sg1 might not be better suited than Sg6 in colonizing environmental niches, increased bloodstream dissemination through resistance to the alternative pathway of complement mediated killing in the human host may explain its higher prevalence.

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Section: Resultsmentioning

confidence: 67%

Comparative Genomics Reveal That Host-Innate Immune Responses Influence the Clinical Prevalence of Legionella pneumophila Serogroups

et al. 2013

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“…Gundry and coworkers found one glycoprotein transmembrane orientation was inconsistent with Swiss‐Prot annotation using glycoproteomic analysis, providing complementary information to correct the protein orientation prediction . Rossi et al studied the membrane‐bound form of complement protein C9 using glycosylation mapping, anti‐peptide antibody binding, and disulfide modification analyses . By deleting two N ‐glycosites and introducing new N ‐glycosites, the authors determined the glycosylation required for human C9 activity and its membrane anchoring, which shows that the glycosite identification is a useful tool for protein orientation assignment.…”

Section: Discussionmentioning

confidence: 99%

Cardiac extracellular proteome profiling and membrane topology analysis using glycoproteomics

Tian

Koganti

Yao

et al. 2014

Proteomics Clinical Apps

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Purpose Extracellular proteins are easily accessible, which presents a sub-proteome of molecular targets that have high diagnostic and therapeutic potential. Efforts have been made to catalogue the cardiac extracellular matridome and analyze the topology of identified proteins for the design of therapeutic targets. Although many bioinformatics tools have been developed to predict protein topology, topology has been experimentally validated for only a very small portion of membrane proteins. The aim of this study was to use a glycoproteomics and mass spectrometry approach to identify glycoproteins in the extracellular matridome of the infarcted LV and provide experimental evidence for topological determination. Experimental design Glycoproteomics analysis was performed on eight biological replicates of day 7 post-MI samples from wild type mice using solid-phase extraction of glycopeptides, followed by mass spectrometric identification of N-linked glycosylation sites for topology assessment. Results We identified hundreds of glycoproteins and the identified N-glycosylation sites provide novel information on the correct topology for membrane proteins present in the infarct setting. Conclusions and clinical relevance Our data provides the foundation for future studies of the LV infarct extracellular matridome, which may facilitate the discovery of drug targets and biomarkers.

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“…Using secondary structure predictions, it was proposed that this region was a helix-turn-helix comprised of C9 residues 292–334 with 309–313 being the turn. Rossi et al [33] subsequently refuted this prediction by introducing a N-linked glycosylation site, K311N, in the middle of the predicted turn region. This mutant was shown to be glycosylated and retain hemolytic activity.…”

Section: Discussionmentioning

confidence: 99%

Membrane pore formation by human complement: Functional importance of the transmembrane β-hairpin (TMH) segments of C8α and C9

Weiland

Sodetz

2014

Molecular Immunology

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Human C8 and C9 have a key role in forming the pore-like “membrane attack complex” (MAC) of complement on bacterial cells. A possible mechanism for membrane insertion of these proteins was suggested when studies revealed a structural similarity between the MACPF domains of the C8α and C8β subunits and the pore-forming bacterial cholesterol-dependent cytolysins (CDCs). This similarity includes a pair of α-helical bundles that in the CDCs refold during pore formation to produce two transmembrane β-hairpins (TMH1 and TMH2). C9 is the major pore-forming component of the MAC and is also likely to contain two TMH segments because of its homology to C8α and C8β. To determine their potential for membrane insertion, the TMH sequences in C8α and those predicted to be in C9 were substituted for the TMH sequences in perfringolysin O (PFO), a well-characterized CDC. Only chimeric proteins containing TMH2 from C8α (PFO/αT2) or C9 (PFO/C9T2) could be expressed in soluble, active form. The PFO/αT2 and PFO/C9T2 chimeras retained significant hemolytic activity, formed pore-like structures on membranes, and could combine with PFO to form hemolytically active mixed complexes that were functionally similar to PFO alone. These results provide experimental evidence in support of the hypothesis that TMH segments in C8α and those predicted to be in C9 have a direct role in MAC membrane penetration and pore formation.

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Topology of the membrane-bound form of complement protein C9 probed by glycosylation mapping, anti-peptide antibody binding, and disulfide modification

Cited by 7 publications

References 40 publications

Comparative Genomics Reveal That Host-Innate Immune Responses Influence the Clinical Prevalence of Legionella pneumophila Serogroups

Comparative Genomics Reveal That Host-Innate Immune Responses Influence the Clinical Prevalence of Legionella pneumophila Serogroups

Cardiac extracellular proteome profiling and membrane topology analysis using glycoproteomics

Membrane pore formation by human complement: Functional importance of the transmembrane β-hairpin (TMH) segments of C8α and C9

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