Isolation and Characterization of Heparan Sulfate from Human Lung Tissues.

Glycosaminoglycans are a class of linear, highly negatively charged, O-linked polysaccharides that are involved in many (patho)physiological processes. In vitro experimental investigations of such processes typically involve porcine-derived heparan sulfate (HS). Structural information about human, particularly organ-specific heparan sulfate, and how it compares with HS from other organisms, is very limited. In this study, heparan sulfate was isolated from human lung tissues derived from five donors and was characterized for their overall size distribution and disaccharide composition. The expression profiles of proteoglycans and HS-modifying enzymes was quantified in order to identify the major core proteins for HS. In addition, the binding affinities of human HS to two chemokines-CXCL8 and CCL2-were investigated, which represent important inflammatory mediators in lung pathologies. Our data revealed that syndecans are the predominant proteoglycan class in human lungs and that the disaccharide composition varies among individuals according to sex, age, and health stage (one of the donor lungs was accidentally discovered to contain a solid tumor). The compositional difference of the five human lung HS preparations affected chemokine binding affinities to various degrees, indicating selective immune cell responses depending on the relative chemokine-glycan affinities. This represents important new insights that could be translated into novel therapeutic concepts for individually treating lung immunological disorders via HS targets.

Development of Molecules Antagonizing Heparan Sulfate Proteoglycans.

Heparan sulfate proteoglycans (HSPGs) occur in almost every tissue of the human body and consist of a protein core, with covalently attached glycosaminoglycan polysaccharide chains. These glycosaminoglycans are characterized by their polyanionic nature, due to sulfate and carboxyl groups, which are distributed along the chain. These chains can be modified by different enzymes at varying positions, which leads to huge diversity of possible structures with the complexity further increased by varying chain lengths. According to their location, HSPGs are divided into different families, the membrane bound, the secreted extracellular matrix, and the secretory vesicle family. As members of the extracellular matrix, they take part in cell-cell communication processes on many levels and with different degrees of involvement. Of particular therapeutic interest is their role in cancer and inflammation as well as in infectious diseases. In this review, we give an overview of the current status of medical approaches to antagonize HSPG function in pathology.

Preparation and Characterization of Glycosaminoglycan Chemokine Coreceptors.

Interactions between chemokines and glycosaminoglycans (GAGs) are crucial for the physiological and pathophysiological activities of chemokines. GAGs are therefore commonly designated as chemokine coreceptors which are deeply involved in the chemokine-signaling network. Studying the interaction of chemokines with GAGs is therefore a major prerequisite to fully understand the biological function of chemokines. GAGs are, however, a very complex class of biomacromolecules which cannot be produced by conventional recombinant methods and which, if purchased from commercial suppliers, are often not subjected to rigorous quality control and therefore frequently differ in batch characteristics. This naturally impacts chemokine-GAG interaction studies. In order to standardize the quality of our GAG ligands, we have therefore established protocols for the preparation and characterization of GAGs from various cells and tissues, for which we give practical examples relating to the major GAG classes heparin, heparan sulfate, and chondroitin sulfate. We will also outline robust and sensitive protocols for chemokine-GAG interaction studies. By this means, a better and more common understanding of the involvement of GAGs in chemokine-signaling networks can be envisaged.

The Positively Charged COOH-terminal Glycosaminoglycan-binding CXCL9(74-103) Peptide Inhibits CXCL8-induced Neutrophil Extravasation and Monosodium Urate Crystal-induced Gout in Mice.

The ELR(-)CXC chemokine CXCL9 is characterized by a long, highly positively charged COOH-terminal region, absent in most other chemokines. Several natural leukocyte- and fibroblast-derived COOH-terminally truncated CXCL9 forms missing up to 30 amino acids were identified. To investigate the role of the COOH-terminal region of CXCL9, several COOH-terminal peptides were chemically synthesized. These peptides display high affinity for glycosaminoglycans (GAGs) and compete with functional intact chemokines for GAG binding, the longest peptide (CXCL9(74-103)) being the most potent. The COOH-terminal peptide CXCL9(74-103) does not signal through or act as an antagonist for CXCR3, the G protein-coupled CXCL9 receptor, and does not influence neutrophil chemotactic activity of CXCL8 in vitro. Based on the GAG binding data, an anti-inflammatory role for CXCL9(74-103) was further evidenced in vivo. Simultaneous intravenous injection of CXCL9(74-103) with CXCL8 injection in the joint diminished CXCL8-induced neutrophil extravasation. Analogously, monosodium urate crystal-induced neutrophil migration to the tibiofemural articulation, a murine model of gout, is highly reduced by intravenous injection of CXCL9(74-103). These data show that chemokine-derived peptides with high affinity for GAGs may be used as anti-inflammatory peptides; by competing with active chemokines for binding and immobilization on GAGs, these peptides may lower chemokine presentation on the endothelium and disrupt the generation of a chemokine gradient, thereby preventing a chemokine from properly performing its chemotactic function. The CXCL9 peptide may serve as a lead molecule for further development of inhibitors of inflammation based on interference with chemokine-GAG interactions.

Designing a mutant CCL2-HSA chimera with high glycosaminoglycan-binding affinity and selectivity.

Chemokines like CCL2 mediate leukocyte migration to inflammatory sites by binding to G-protein coupled receptors on the target cell as well as to glycosaminoglycans (GAGs) on the endothelium of the inflamed tissue. We have recently shown that the dominant-negative Met-CCL2 mutant Y13A/S21K/Q23R with improved GAG binding affinity is highly bio-active in several animal models of inflammatory diseases. For chronic indications, we have performed here a fusion to human serum albumin (HSA) in order to extend the serum half-life of the chemokine mutant. To compensate a potential drop in GAG-binding affinity due to steric hindrance by HSA, a series of novel CCL2 mutants was generated with additional basic amino acids which were genetically introduced at sites oriented towards the GAG ligand. From this set of mutants, the Met-CCL2 variant Y13A/N17K/S21K/Q23K/S34K exhibited high GAG-binding affinity and a similar selectivity as wild type (wt) CCL2. From a set of different HSA-chemokine chimeric constructs, the linked HSA(C34A)(Gly)4Ser-Met-CCL2(Y13A/N17K/S21K/Q23K/S34K) fusion protein was found to show the best overall GAG-binding characteristics. Molecular modeling demonstrated an energetically beneficial fold of this novel protein chimera. This was experimentally supported by GdmCl-induced unfolding studies, in which the fusion construct exhibited a well-defined secondary structure and a transition point significantly higher than both the wt and the unfused CCL2 mutant protein. Unlike the wt chemokine, the quaternary structure of the HSA-fusion protein is monomeric according to size-exclusion chromatography experiments. In competition experiments, the HSA-fusion construct displaced only two of seven unrelated chemokines from heparan sulfate, whereas the unfused CCL2 mutant protein displaced five other chemokines. The most effective concentration of the HSA-fusion protein in inhibiting CCL2-mediated monocyte attachment to endothelial cells, as detected in the flow chamber, was 8.6 µg/ml. This novel HSA-fusion protein exhibits not only high affinity but also selective displacement of chemokines from GAGs binding. HSA is therefore proposed to be a highly promising scaffold candidate for therapeutic, GAG-targeting chemokine mutants.