A key event in inflammatory disease is the transendothelial recruitment of leukocytes from the circulation to the site of inflammation. Intense research in the past decades indicates that the polyanionic carbohydrate heparan sulphate (HS) modulates multiple steps in the leukocyte recruitment cascade. Leukocyte recruitment is initiated by endothelial cell activation and presentation of chemokines to rolling leukocytes, which, via integrin activation, results in adhesion and diapedesis through the vessel wall. Heparan sulfate proteoglycans (HSPGs) immobilize the chemokines on the luminal endothelial cells, rendering them more robust against mechanical or hydrodynamic perturbations. During inflammation, endothelial HSPGs serve as ligands to L-selectin on leukocytes, transport chemokines in a basolateral to apical direction across the endothelium, and present chemokines at the luminal surface of the endothelium to circulating cells. HSPGs also promote chemokine oligomerization, which influences chemokine receptor signaling. Furthermore, proteoglycans of the syndecan family are involved in modulating integrin-mediated tight adhesion of leukocytes to the endothelium. Creation of a chemokine gradient by a localized chemokine release influences the speed of leukocyte recruitment from the blood to the tissue by attracting crawling neutrophils to optimal sites for transmigration. The directionality of intraluminal crawling is thought to be influenced by both mechanotactic and haptotactic signals, which are modulated by HS-dependent signaling processes. Finally, diapedesis is influenced by HS regarding transendothelial chemokine gradient formation and integrin- CAM interactions, and further enhanced by heparanase-mediated degradation of the endothelial basement membrane. Overall, the multifunctional role of HS in inflammation marks it as a potential target of glycan-centered therapeutic approaches.
Background:The dermatan sulfate proteoglycan decorin modulates delayed-type hypersensitivity, leading to reduced edema. Results: Decorin deficiency leads to a reduced infiltration of CD8 ϩ leukocytes and deregulated cytokine expression. Decorin can
Background Endogenous Peptide Inhibitor of CXCR4 (EPI-X4) is a natural antagonist of the CXC chemokine receptor 4 (CXCR4). EPI-X4 is a 16-mer peptide that is released from human serum albumin (HSA) by acidic aspartic proteases such as Cathepsin D and E. Since human serum albumin (HSA) is an important medicinal substance we asked whether different pharmaceutical HSA products contain EPI-X4 which could have been generated during manufacturing and whether HSA can serve as a substrate for cathepsins despite of the presence of stabilizers like caprylate. Methods Eight pharmaceutical HSA preparations representing all currently used fractionation technologies were analyzed. The previously described specific EPI-X4 ELISA was used for quantification; in vitro EPI-X4 generation by acidification in the presence or absence of cathepsins was followed by quantification with ELISA. Results None of the pharmaceutical HSA preparations tested contained EPI-X4. Acidification of HSA did not generate EPI-X4. Addition of cathepsins D and E to acidified HSA yielded high concentrations of EPI-X4 in all HSA preparations, indistinguishable between individual products. Conclusion Medicinal HSA preparations per se do not contain EPI-X4, but will replenish its precursor which can be cleaved to EPI-X4 in vivo, environmental conditions permitting.
Background: Endogenous Peptide Inhibitor of CXCR4 (EPI-X4) is a natural antagonist of the CXC chemokine receptor 4 (CXCR4). EPI-X4 is a 16-mer peptide that is released from human serum albumin (HSA) by acidic aspartic proteases such as Cathepsin D and E. Since human serum albumin (HSA) is an important medicinal substance we asked whether different pharmaceutical HSA products contain EPI-X4 which could have been generated during manufacturing and whether HSA can serve as a substrate for cathepsins despite of the presence of stabilizers like caprylate. Methods: Eight pharmaceutical HSA preparations representing all currently used fractionation technologies were analyzed. The previously described specific EPI-X4 ELISA was used for quantification; in vitro EPI-X4 generation by acidification in the presence or absence of cathepsins was followed by quantification with ELISA. Results: None of the pharmaceutical HSA preparations tested contained EPI-X4. Acidification of HSA did not generate EPI-X4. Addition of cathepsins D and E to acidified HSA yielded high concentrations of EPI-X4 in all HSA preparations, indistinguishable between individual products. Conclusion: Medicinal HSA preparations per se do not contain EPI-X4, but will replenish its precursor which can be cleaved to EPI-X4 in vivo, environmental conditions permitting.
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