IsoQC (QPCTL) knock-out mice suggest differential substrate conversion by glutaminyl cyclase isoenzymes

Secretory peptides and proteins are frequently modified by pyroglutamic acid (pE, pGlu) at their N-terminus. This modification is catalyzed by the glutaminyl cyclases QC and isoQC. Here, we decipher the roles of the isoenzymes by characterization of IsoQC(-/-) mice. These mice show a significant reduction of glutaminyl cyclase activity in brain and peripheral tissue, suggesting ubiquitous expression of the isoQC enzyme. An assay of substrate conversion in vivo reveals impaired generation of the pGlu-modified C-C chemokine ligand 2 (CCL2, MCP-1) in isoQC(-/-) mice. The pGlu-formation was also impaired in primary neurons, which express significant levels of QC. Interestingly, however, the formation of the neuropeptide hormone thyrotropin-releasing hormone (TRH), assessed by immunohistochemistry and hormonal analysis of hypothalamic-pituitary-thyroid axis, was not affected in isoQC(-/-), which contrasts to QC(-/-). Thus, the results reveal differential functions of isoQC and QC in the formation of the pGlu-peptides CCL2 and TRH. Substrates requiring extensive prohormone processing in secretory granules, such as TRH, are primarily converted by QC. In contrast, protein substrates such as CCL2 appear to be primarily converted by isoQC. The results provide a new example, how subtle differences in subcellular localization of enzymes and substrate precursor maturation might influence pGlu-product formation

Role of C-reactive protein in complement-mediated hemolysis in Malaria

HumanC-reactive protein (CRP) is a clinically important classical acute phase protein. Although CRP has been reported to bind with many nucleated cells, the direct binding of CRP to erythrocytes in diseases remains largely unexplored. The main focus of the present studywas to investigate the binding of disease-specific CRP to erythrocytes of same patients. Distinct molecular variant of disease-specific CRP was affinity purified from sera of malaria patients (CRPMal). This CRP showed strong binding with malaria erythrocytes (RBCMal) as confirmed by flow cytometric analysis (FACS), enzyme-linked immunosorbent assays (ELISA), and radio binding assays. Calcium and phosphoryl choline (PC) were found to be essential for this interaction.A2.3-fold increased binding of induced CRP to RBCMal as compared to normal erythrocytes (RBCN) confirmed disease-specificity. Preincubation of RBCMal with unconjugated CRP showed 3–5 fold inhibition. The association constant of CRP and RBCMal was 4.7 × 106 cpm/μg with the corresponding number of receptors/ cell being 4.3 × 105. The effector function of CRPMal has been demonstrated by its potency to activate the complement pathway. An optimal dose of 10 μg/ml of CRP induced three-fold higher hemolysis of patient erythrocytes as compared to RBCN. These studies provide direct evidence for an important phagocytic functional interaction of this acutephase protein by triggering the CRP-complement pathway after the binding of CRPMal with RBCMal. Hemolysis as triggered by this pathway may be one of the causative factors of anemia, a common clinical manifestation of this diseas

The antimicrobial properties of C-reactive protein (CRP)

10.1179/096805105X37402Journal of Endotoxin Research114249-256JENR

Complement regulation in innate immunity and the acute-phase response: inhibition of mannan-binding lectin-initiated complement cytolysis by C-reactive protein (CRP)

Mannan-binding lectin (MBL) is an acute-phase protein which activates complement at the level of C4 and C2. We recently reported that the alternative pathway also is required for haemolysis via this ‘lectin pathway’ in human serum. CRP is another acute-phase reactant which activates the classical pathway, but CRP also inhibits the alternative pathway on surfaces to which it binds. Since serum levels of both proteins generally increase with inflammation and tissue necrosis, it was of interest to determine the effect of CRP on cytolysis via the lectin pathway. We report here that although CRP increases binding of C4 to MBL-sensitized erythrocytes, which in turn enhances lectin pathway haemolysis, it inhibits MBL-initiated cytolysis by its ability to inhibit the alternative pathway. This inhibition is characterized by increased binding of complement control protein H and decreased binding of C3 and C5 to the indicator cells, which in turn is attributable to the presence of CRP. Immunodepletion of H leads to greatly enhanced cytolysis via the lectin pathway, and this cytolysis is no longer inhibited by CRP. These results indicate that CRP regulates MBL-initiated cytolysis on surfaces to which both proteins bind by modulating alternative pathway recruitment through H, pointing to CRP as a complement regulatory protein, and suggesting a co-ordinated role for these proteins in complement activation in innate immunity and the acute-phase response