Apoptosis and its relevance in cancer therapy.

In the majority of human tumors the ability to induce programmed cell death (apoptosis) is frequently lost, suggesting that disruption of the apoptotic function contributes significantly to the transformation of a normal cell into a tumor cell. Apoptosis is regulated by two major pathways, the death receptor-induced and the stress-mediated pathway. While the former depends on the activation of death receptors such as Fas-R, the latter is induced by various stress signals. Stimulation of the death receptor pathway directly triggers the proteolytic activation of caspases via the formation of a death receptor- induced signalling complex (DISC). In contrast, caspase activation via the stress-induced pathway is mediated by the formation of a protein complex called apoptosome which forms upon release of cytochrome c regulated by members of the Bcl-2 protein family. Ultimately, both pathways disembogue into cellular changes, eventually causing the cell death. Mutation of many different genes involved in the regulation of apoptosis have been identified in human cancer, resulting in the development of novel therapeutic approaches such as activation of death receptors using recombinant ligand or inhibition of Bcl-2 expression by antisense reagents. Although based on different targets and delivery methods, all these approaches have the common goal to eliminate tumor cells by restoration of the apoptotic function.

The CXC chemokine receptor 2, CXCR2, is the putative receptor for ELR+ CXC chemokine-induced angiogenic activity.

We have previously shown that members of the ELR(+) CXC chemokine family, including IL-8; growth-related oncogenes alpha, beta, and gamma; granulocyte chemotactic protein 2; and epithelial neutrophil-activating protein-78, can mediate angiogenesis in the absence of preceding inflammation. To date, the receptor on endothelial cells responsible for chemotaxis and neovascularization mediated by these ELR(+) CXC chemokines has not been determined. Because all ELR(+) CXC chemokines bind to CXC chemokine receptor 2 (CXCR2), we hypothesized that CXCR2 is the putative receptor for ELR(+) CXC chemokine-mediated angiogenesis. To test this postulate, we first determined whether cultured human microvascular endothelial cells expressed CXCR2. CXCR2 was detected in human microvascular endothelial cells at the protein level by both Western blot analysis and immunohistochemistry using polyclonal Abs specific for human CXCR2. To determine whether CXCR2 played a functional role in angiogenesis, we determined whether this receptor was involved in endothelial cell chemotaxis. We found that microvascular endothelial cell chemotaxis in response to ELR(+) CXC chemokines was inhibited by anti-CXCR2 Abs. In addition, endothelial cell chemotaxis in response to ELR(+) CXC chemokines was sensitive to pertussis toxin, suggesting a role for G protein-linked receptor mechanisms in this biological response. The importance of CXCR2 in mediating ELR(+) CXC chemokine-induced angiogenesis in vivo was also demonstrated by the lack of angiogenic activity induced by ELR(+) CXC chemokines in the presence of neutralizing Abs to CXCR2 in the rat corneal micropocket assay, or in the corneas of CXCR2(-/-) mice. We thus conclude that CXCR2 is the receptor responsible for ELR(+) CXC chemokine-mediated angiogenesis.

Down-regulation of neutrophil functions by the ELR(+) CXC chemokine platelet basic protein.

The platelet-derived neutrophil-activating peptide 2 (NAP-2, 70 amino acids) belongs to the ELR(+) CXC subfamily of chemokines. Similar to other members of this group, such as IL-8, NAP-2 activates chemotaxis and degranulation in neutrophils (polymorphonuclear [PMN]) through chemokine receptors CXCR-1 and CXCR-2. However, platelets do not secrete NAP-2 as an active chemokine but as the C-terminal part of several precursors that lack PMN-stimulating capacity. As we have previously shown, PMN themselves may liberate NAP-2 from the precursor connective tissue-activating peptide III (CTAP-III, 85 amino acids) by proteolysis. Instead of inducing cell activation, continuous accumulation of the chemokine in the surroundings of the processing cells results in the down-regulation of specific surface-expressed NAP-2 binding sites and in the desensitization of chemokine-induced PMN degranulation. Thus, NAP-2 precursors may be regarded as indirect mediators of functional desensitization in neutrophils. In the current study we investigated the biologic impact of another major NAP-2 precursor, the platelet basic protein (PBP, 94 amino acids). We show that PBP is considerably more potent than CTAP-III to desensitize degranulation and chemotaxis in neutrophils. We present data suggesting that the high desensitizing capacity of PBP is based on its enhanced proteolytic cleavage into NAP-2 by neutrophil-expressed cathepsin G and that it involves efficient down-regulation of surface-expressed CXCR-2 while CXCR-1 is hardly affected. Correspondingly, we found PBP and, less potently, CTAP-III to inhibit CXCR-2- but not CXCR-1- dependent chemotaxis of neutrophils toward NAP-2. Altogether our findings demonstrate that the anti-inflammatory capacity of NAP-2 is governed by the species of its precursors.

Identification of distinct surface-expressed and intracellular CXC-chemokine receptor 2 glycoforms in neutrophils: N-glycosylation is essential for maintenance of receptor surface expression.

The G protein-coupled CXC-chemokine receptor CXCR-2 mediates activation of neutrophil effector functions in response to multiple ligands, including IL-8 and neutrophil-activating peptide 2 (NAP-2). Although CXCR-2 has been successfully cloned and expressed in several cell lines, the molecular properties of the native neutrophil-expressed receptor have remained largely undefined. Here we report on the identification and characterization of distinct CXCR-2 glycoforms and their subcellular distribution in neutrophils. Immunoprecipitation and Western blot analyses of surface-expressed receptors covalently linked to IL-8 or NAP-2 as well as in their unloaded state revealed the occurrence of a single CXCR-2 variant with an apparent size of 56 kDa. According to deglycosylation experiments surface-expressed CXCR-2 carries two N-linked 9-kDa carbohydrate moieties that are both of complex structure. In addition, two other CXCR-2 variants of 38 and 40 kDa were found to occur exclusively intracellular and to carry N-glycosylations of high mannose or hybrid type. These receptors did not participate in ligand-induced receptor trafficking, while surface-expressed CXCR-2 was internalized and re-expressed following stimulation with NAP-2. By enzymatic removal of one 9-kDa carbohydrate moiety in surface-expressed CXCR-2 we can show that neither NAP-2-induced trafficking nor signaling of the receptor is dependent on its full glycosylation. Instead, glycosylation was found to protect CXCR-2 from proteolytic attack, as even partial deglycosylation is associated with serine protease-mediated disappearance of the receptor from the neutrophil surface. Thus, although not directly involved in signaling, glycosylation appears to be required to maintain neutrophil responsiveness to CXC-chemokines during inflammation.

CXC chemokines in angiogenesis.

A variety of factors have been identified that regulate angiogenesis, including the CXC chemokine family. The CXC chemokines are a unique family of cytokines for their ability to behave in a disparate manner in the regulation of angiogenesis. CXC chemokines have four highly conserved cysteine amino acid residues, with the first two cysteine amino acid residues separated by one non-conserved amino acid residue (i.e., CXC). A second structural domain within this family determines their angiogenic potential. The NH2 terminus of the majority of the CXC chemokines contains three amino acid residues (Glu-Leu-Arg: the ELR motif), which precedes the first cysteine amino acid residue of the primary structure of these cytokines. Members that contain the ELR motif (ELR+) are potent promoters of angiogenesis. In contrast, members that are inducible by interferons and lack the ELR motif (ELR-) are potent inhibitors of angiogenesis. This difference in angiogenic activity may impact on the pathogenesis of a variety of disorders.

Thrombocidins, microbicidal proteins from human blood platelets, are C-terminal deletion products of CXC chemokines.

Antibacterial proteins are components of the innate immune system found in many organisms and produced by a variety of cell types. Human blood platelets contain a number of antibacterial proteins in their alpha-granules that are released upon thrombin activation. The present study was designed to purify these proteins obtained from human platelets and to characterize them chemically and biologically. Two antibacterial proteins were purified from platelet granules in a two-step protocol using cation exchange chromatography and continuous acid urea polyacrylamide gel electrophoresis and were designated thrombocidin (TC)-1 and TC-2. Characterization of these proteins using mass spectrometry and N-terminal sequencing revealed that TC-1 and TC-2 are variants of the CXC chemokines neutrophil-activating peptide-2 and connective tissue-activating peptide-III, respectively. TC-1 and TC-2 differ from these chemokines by a C-terminal truncation of 2 amino acids. Both TCs, but not neutrophil-activating peptide-2 and connective tissue-activating peptide-III, were bactericidal for Bacillus subtilis, Escherichia coli, Staphylococcus aureus, and Lactococcus lactis and fungicidal for Cryptococcus neoformans. Killing of B. subtilis by either TC appeared to be very rapid. Because TCs were unable to dissipate the membrane potential of L. lactis, the mechanism of TC-mediated killing most probably does not involve pore formation.

The beta-thromboglobulins and platelet factor 4: blood platelet-derived CXC chemokines with divergent roles in early neutrophil regulation.

The recruitment of neutrophil granulocytes to sites of tissue injury is one of the earliest events during host defense. Several chemotactic cytokines belonging to the CXC subfamily of chemokines are thought to be implicated in this kind of response. Especially those CXC chemokines that are stored in blood platelets and become immediately released upon activation are likely to dominate neutrophil-dependent host defense at the onset of inflammation. The major platelet-derived CXC chemokines are the beta-thromboglobulins and platelet factor 4 (PF-4), which are both released into the blood at micromolar concentrations. The availability as well as the functional activity of these mediators appear to be subject to tight control by diverse regulatory mechanisms. These include proteolytic processing of chemokine precursors, oligomer formation, and the differential usage of neutrophil-expressed receptors. Herein we review our work on early neutrophil regulation by PF-4, the beta-thromboglobulin neutrophil-activating peptide 2 (NAP-2) and its major precursor connective tissue-activating peptide III (CTAP-III). We moreover propose a model to assess the contribution by either of these chemokines to coordinated recruitment and activation of neutrophils in response to acute tissue injury.

Chemokines and chemokine receptors: disease targets for therapeutic development. November 15-16, 1999, McLean, VA, USA.

About a decade after discovery of IL-8, the first designated member of the protein family of chemotactic cytokines, about 50 of these so called 'chemokines' and about 15 receptors have been discovered in humans. Experimental as well as clinical data have identified many of the players in this network to be associated with various pathological phenomena. This conference discussed how research is closing in on chemokines as therapeutic targets as well as how chemokine functions might be exploited to design useful therapeutic tools.

Novel C-terminally truncated isoforms of the CXC chemokine beta-thromboglobulin and their impact on neutrophil functions.

The neutrophil agonist neutrophil-activating peptide-2 (NAP-2) arises through proteolytic processing of platelet-derived N-terminally extended inactive precursors, the most abundant one being connective tissue-activating peptide-III (CTAP-III). Apart from N-terminal processing, C-terminal processing also appears to participate in the functional regulation of NAP-2, as indicated by our recent identification of an isoform missing four C-terminal amino acids, NAP-2 (1-66), which was about threefold more potent than full-size NAP-2. In the present study, we report on the discovery and identification of natural NAP-2 (1-63), an isoform truncated by seven C-terminal residues. Functional and receptor-binding analyses demonstrated that NAP-2 (1-63) represents the most active isoform, being about fivefold more potent than full-size NAP-2. Analyses of rNAP-2 isoforms successively truncated at the C terminus by up to eight residues suggest functionally important roles for acidic residues and for the leucine at position 63, a residue highly conserved within CXC chemokines. Finally, we report on a novel C-terminally truncated isoform of CTAP-III (CTAP-III (1-81)) representing the potential precursor of NAP-2 (1-66). We show that C-terminal truncation in CTAP-III enhances its potency to desensitize chemokine-induced neutrophil activation, indicating that C-terminal processing might not only serve to enhance neutrophil activation, but might as well participate in the down-regulation of an inflammatory response.

Limited and defined truncation at the C terminus enhances receptor binding and degranulation activity of the neutrophil-activating peptide 2 (NAP-2). Comparison of native and recombinant NAP-2 variants.

We have previously described a C-terminally truncated variant of the chemokine neutrophil-activating peptide 2 (NAP-2) that exhibited higher neutrophil-stimulating capacity than the full-size polypeptide. To investigate the impact of the NAP-2 C terminus on biological activity and receptor binding, we have now purified the novel molecule to homogeneity. Furthermore, we have cloned, expressed in Escherichia coli, and purified full-size recombinant NAP-2 (rNAP-2-(1-70)) and a series of C-terminally deleted variants (rNAP-2-(1-69) to rNAP-2-(1-64)). Biochemical and immunochemical analyses revealed that the natural NAP-2 variant was structurally identical to the rNAP-2-(1-66) isoform. As compared with their respective native and recombinant full-size counterparts, both molecules exhibited approximately 3-4-fold enhanced potency in the induction of neutrophil degranulation as well as 3-fold enhanced binding affinity for specific receptors on these cells. All other variants were considerably less active. The natural occurrence of a NAP-2 variant truncated by exactly four residues at the C terminus suggests that limited and defined proteolysis at this site plays a role in the regulation of the biological function of the chemokine.