A neutralizing monoclonal antibody specific for the dimer interface region of IL-8

We have generated two mAbs, 6G4.2.5 and A5.12.14, that are similarly capable of neutralizing the biologic activity of wild-type IL-8. To characterize these antibodies further, their reactivity against a series of engineered IL-8 monomer and dimer variants was examined using a neutrophil degranulation assay. While 6G4.2.5 was found to block effectively the biologic activity of all variants regardless of their dimerization status, the results for A5.12.14 differed dramatically. A5.12.14 fully inhibited the agonist activity of one of the monomer variants, partially blocked the activity of another, and had no effect on the activity of two other variants. These results suggested that the binding epitope of A5.12.14 was being affected by the particular amino acid substitutions introduced into the dimer interface region of the variants to disfavor dimerization. If A5.12.14 indeed binds to the dimer interface region of IL-8, it could be predicted that this mAb would be unable to inhibit the activity of dimeric IL-8. This was confirmed in studies which showed that A5.12.14 had no demonstrable effect on the activity of a constitutively dimeric IL-8 variant. These studies represent the first example of a mAb specific for the dimerization status of IL-8.

International union of pharmacology. XXII. Nomenclature for chemokine receptors

Chemokine receptors comprise a large family of seven transmembrane domain G protein-coupled receptors differentially expressed in diverse cell types. Biological activities have been most clearly defined in leukocytes, where chemokines coordinate development, differentiation, anatomic distribution, trafficking, and effector functions and thereby regulate innate and adaptive immune responses. Pharmacological analysis of chemokine receptors is at an early stage of development. Disease indications have been established in human immunodeficiency virus/acquired immune deficiency syndrome and in Plasmodium vivax malaria, due to exploitation of CCR5 and Duffy, respectively, by the pathogen for cell entry. Additional indications are emerging among inflammatory and immunologically mediated diseases, but selection of targets in this area still remains somewhat speculative. Small molecule antagonists with nanomolar affinity have been reported for 7 of the 18 known chemokine receptors but have not yet been studied in clinical trials. Virally encoded chemokine receptors, as well as chemokine agonists and antagonists, and chemokine scavengers have been identified in medically important poxviruses and herpesviruses, again underscoring the importance of the chemokine system in microbial pathogenesis and possibly identifying specific strategies for modulating chemokine action therapeutically. The purpose of this review is to update current concepts of the biology and pharmacology of the chemokine system, to summarize key information about each chemokine receptor, and to describe a widely accepted receptor nomenclature system, ratified by the International Union of Pharmacology, that is facilitating clear communication in this area.

Inhibition of water permeability in the rat collecting duct: effect of imidazoline and alpha-2 compounds

Arginine vasopressin (AVP) increases water permeability in the collecting duct of the nephron via activation of adenylyl cyclase. Alpha-2 (alpha2) agonists inhibit AVP-stimulated water permeability via binding to alpha2 adrenoceptors that have been divided into 3 subtypes- alpha2A, alpha2B, and alpha2C. Some biological effects mediated by alpha2 agonists result from nonadrenergic imidazoline receptors that exist in the rat kidney. Thus, alpha2-inhibition of AVP-stimulated water permeability in the rat collecting duct could be caused by imidazoline receptors. The purpose of this study was to test agonists and antagonists selective for alpha2 and imidazoline receptors on AVP-stimulated water permeability in the rat inner medullary collecting duct (IMCD). Some experiments were conducted where water permeability was stimulated by a nonhydrolyzable analog of adenosine 3', 5'-cyclic monophosphate (cAMP). Agonists included dexmedetomidine, clonidine, oxymetazoline, agmatine and rilmenidine. The latter two are selective imidazoline agonists. Antagonists included yohimbine, RX821002, atipamezole, prazosin, WB4101, idazoxan, and BU239. Prazosin and WB4101 demonstrate selectivity for the alpha2B and alpha2C subtypes, respectively, and oxymetazoline and RX821002 are selective for the alpha2A subtype. BU239 is selective for imidazoline receptors. Wistar rat terminal IMCDs were isolated and perfused to determine the osmotic water permeability coefficient (Pf). All agonists except agmatine inhibited AVP-stimulated Pf. Inhibition by rilmenidine indicated a different mechanism of action from other agonists. Dose-response data show dexmedetomidine to be the most potent inhibitor. Oxymetazoline and clonidine inhibited cAMP-stimulated Pf indicating that the mechanism involves postcAMP cellular events. It was reported previously that dexmedetomidine inhibits cAMP-stimulated Pf (1). All antagonists except prazosin and WB4101 reversed alpha2-inhibition of AVP-stimulated Pf. BU239 was effective at 1 microM but not at 100 nM. Results suggest that alpha2A adrenoceptors modulate water permeability in the IMCD. The involvement of imidazoline receptors is inconclusive.

Distinct but overlapping epitopes for the interaction of a CC-chemokine with CCR1, CCR3 and CCR5

Chemokines play an important role in inflammation. The mechanism via which they bind to more than one receptor and activate them is not well understood. The chemokines are thought to interact with their receptors via two distinct sites, one necessary for binding and the other for activation of signal transduction. In this study we have used alanine scanning mutagenesis to identify residues on RANTES that specifically interact with its receptors CCR1, CCR3, and CCR5 for binding and activation. Residues within a potential receptor binding site known as the N-loop (residues 12-20) and near the N-terminus of RANTES were individually mutated to alanine. The results of this study show that, within the N-loop, the side chain of R17 is necessary for RANTES binding to CCR1, F12 for binding to CCR3, and F12 and I15 for binding to CCR5, thus forming distinct but overlapping binding epitopes. In addition, our finding that P2 is necessary for binding to CCR5 is the first to show that a residue near the N-terminus of a CC-chemokine is involved in binding to a receptor. We have also found that P2, D6, and T7 near the N-terminus are involved in activating signal transduction via CCR1, P2 and Y3 via CCR3, and Y3 and D6 via CCR5. These results indicate that RANTES interacts with each of its receptors in a distinct and specific manner and provide further evidence to support the two-site model of interaction between chemokines and their receptors.

IL-8 single-chain homodimers and heterodimers: interactions with chemokine receptors CXCR1, CXCR2, and DARC

Covalent single-chain dimers of the chemokine interleukin-8 (IL-8) have been designed to mimic the dimeric form of IL-8 in solution and facilitate the production of heterodimer variants of IL-8. Physical studies indicated that use of a simple peptide linker to join two subunits, while allowing receptor binding and activation, led to self-association of the tethered dimers. However, addition of a single disulfide crosslink between the tethered subunits prevented this multimer from forming, yielding a species of dimer molecular weight. Crosslinked single-chain dimers bind to both IL-8 neutrophil receptors CXCR1 and CXCR2 as well as to DARC, as does a double disulfide-linked dimer with no peptide linker. In addition, neutrophil response to these dimers as measured by chemotaxis or beta-glucuronidase release is similar to that elicited by wild-type IL-8, providing evidence that the dissociation of the dimeric species is not required for these biologically relevant activities. Finally, through construction of single-chain heterodimer mutants, we show that only the first subunit's ELR motif is the single-chain variants.

Monomeric variants of IL-8: effects of side chain substitutions and solution conditions upon dimer formation

IL-8 dimers have been observed in NMR and X-ray structures of the protein. We have engineered IL-8 monomers by mutations of residues throughout the dimer interface, which introduce hindrance determinants to dimerization. These IL-8 variants are shown by NMR to have wild-type monomer folding, but by ultracentrifugation to have a range of dimerization constants from microM to mM, as compared with a dimerization constant of about 10 microM for wild-type IL-8, under physiological salt and temperature conditions. The monomeric variants of IL-8 bind the erythrocyte chemokine receptor DARC, as well as the neutrophil IL-8 receptors CXCR1 and CXCR2 with affinities similar to that of wild-type IL-8. In addition, the monomeric variants were shown to have agonist activity, with similar potency to wild-type, in both Ca(2+)-flux assays on CXCR1 and CXCR2 transfected cells, and in chemotaxis assays on neutrophils. Thus, these variants confirm that monomeric IL-8 is functionally equivalent to wild-type in vitro assays. We have also investigated the effects of various solution conditions upon IL-8 dimer formation using analytical ultracentrifugation. At salt concentrations, temperatures, and pH conditions lower than physiological, the dimerization affinity of IL-8 is greatly enhanced. This suggests that, under some conditions, IL-8 dimer formation may occur at concentrations of IL-8 considerably lower than 10 microM, with consequences in vivo that are yet to be determined.

Chemoattractant cross-desensitization of the human neutrophil IL-8 receptor involves receptor internalization and differential receptor subtype regulation

Human neutrophils undergo rapid homologous receptor desensitization following repeated stimulation with chemoattractants such as IL-8, C5a, and FMLP. It has also been demonstrated that cross-desensitization among these chemoattractant receptors occurs. We investigated the mechanisms underlying the cross-desensitization of responses to IL-8 induced by pretreatment with FMLP or C5a. In [125I]-labeled IL-8 binding studies we found that the cross-desensitization induced by FMLP or C5a was associated with a subsequent reduction in IL-8 binding to neutrophils. There was no recovery of [125I]-labeled IL-8 binding on removal of the C5a or FMLP pretreatment. FACS analysis using mAbs specific for the two IL-8R subtypes showed differential regulation of IL-8R A and IL-8R B cell surface expression after chemoattractant pretreatment. Homologous desensitization by IL-8 resulted in internalization of IL-8R A and IL-8R B, but only IL-8R A was completely re-expressed after removal of agonist. FMLP stimulation led to a substantial loss of IL-8R B from the cell surface, whereas C5a stimulation induced only a partial loss. In both cases there was no re-expression of IL-8R B on removal of the chemoattractant stimulation. C5a and FMLP did not affect IL-8R A expression. Calcium mobilization studies using melanoma growth stimulatory activity and IL-8 suggest that a sustained loss of IL-8R B may play a part in maintaining FMLP-induced IL-8R cross-desensitization. Chemoattractant-induced cross-desensitization of neutrophils may be of importance in regulating neutrophil accumulation during the inflammatory response in vivo.

Chemoattractant cross-desensitization of the human neutrophil IL-8 receptor involves receptor internalization and differential receptor subtype regulation

Human neutrophils undergo rapid homologous receptor desensitization following repeated stimulation with chemoattractants such as IL-8, C5a, and FMLP. It has also been demonstrated that cross-desensitization among these chemoattractant receptors occurs. We investigated the mechanisms underlying the cross-desensitization of responses to IL-8 induced by pretreatment with FMLP or C5a. In [125I]-labeled IL-8 binding studies we found that the cross-desensitization induced by FMLP or C5a was associated with a subsequent reduction in IL-8 binding to neutrophils. There was no recovery of [125I]-labeled IL-8 binding on removal of the C5a or FMLP pretreatment. FACS analysis using mAbs specific for the two IL-8R subtypes showed differential regulation of IL-8R A and IL-8R B cell surface expression after chemoattractant pretreatment. Homologous desensitization by IL-8 resulted in internalization of IL-8R A and IL-8R B, but only IL-8R A was completely re-expressed after removal of agonist. FMLP stimulation led to a substantial loss of IL-8R B from the cell surface, whereas C5a stimulation induced only a partial loss. In both cases there was no re-expression of IL-8R B on removal of the chemoattractant stimulation. C5a and FMLP did not affect IL-8R A expression. Calcium mobilization studies using melanoma growth stimulatory activity and IL-8 suggest that a sustained loss of IL-8R B may play a part in maintaining FMLP-induced IL-8R cross-desensitization. Chemoattractant-induced cross-desensitization of neutrophils may be of importance in regulating neutrophil accumulation during the inflammatory response in vivo.

Identification of G-protein binding sites of the human interleukin-8 receptors by functional mapping of the intracellular loops

Interleukin 8 (IL-8) is considered to be a major mediator of the inflammatory response. Recent evidence indicates that a direct physical association occurs between IL-8 receptors and the alpha subunit of guanine nucleotide regulatory protein (Gi(alpha)2) upon stimulation of human neutrophils by IL-8. In the present study, we identified by site-directed mutagenesis key residues within the three intracellular loops of the IL-8RA receptor involved in the interaction with Gi(alpha)2. We first systematically mutated, in groups of two to four, all the residues in the three intracellular loops of the IL-8 type A receptor to alanine and analyzed the mutant receptors transiently expressed in 293 cells. Four residues in the second intracellular loop (Y136, L137, I139, V140) and one residue in the third intracellular loop (M241) were shown to be crucial for mediating calcium signaling in response to IL-8. Other residues in the second and third intracellular loops were also found to affect IL-8RA-mediated signaling, but to a lesser extent. These effects were not due to lower expression or low IL-8 binding affinities to the mutated receptors. Mutagenesis of the residues in the first intracellular loop had only weak effects on the mobilization of calcium induced by IL-8. We then used a coimmunoprecipitation protocol with anti-Gi(alpha)2 antibodies to determine the involvement of the two regions defined above in Gi(alpha)2 coupling to IL-8 type A receptors. Whereas the anti-Gi(alpha)2 antibodies coimmunoprecipitated IL-8 receptors in the wild-type cells, this interaction was lost in cells expressing mutated receptors that affected intracellular calcium mobilization. The peptides corresponding to the regions of the type A receptor found to be critical for Gi(alpha)2 coupling and induction of intracellular calcium mobilization were next introduced into cells expressing wild-type IL-8RA or IL-8RB to assess their role in coupling Gi(alpha)2 to both IL-8 receptors. The results obtained in the latter experiments suggest that the same regions of the second intracellular loop (Y136, L137, I139, V140) and of the third intracellular loop (M241) are critically involved in the coupling of both IL-8RA and IL-8 RB to Gi(alpha)2 as well as to a downstream effector (or effectors) involved in calcium mobilization.

Diverging signal transduction pathways activated by interleukin 8 (IL-8) and related chemokines in human neutrophils. IL-8 and Gro-alpha differentially stimulate calcium influx through IL-8 receptors A and B

Interleukin 8 (IL-8) and Gro-alpha are members of the CXC branch of a family of cytokines recently designated the "chemokine" superfamily. Recent evidence indicates that, contrary to previously held beliefs, IL-8 and Gro-alpha may not be perceived equivalently by neutrophils. In this study, we have evaluated the effects of IL-8 and Gro-alpha on the rate of calcium influx in human neutrophils and in 293 cells transfected with type A or type B IL-8 receptors. Of these two chemokines, only Gro-alpha induced an influx of calcium in neutrophils as judged by the sensitivity of the mobilization of calcium to the extracellular calcium chelator EGTA and to the nonselective divalent cation channel inhibitor SK&F 96365, as well as by manganese quenching experiments. IL-8 was similarly without effect on the rate of Mn2+ influx in 293 cells transfected with IL-8 receptor A (IL-8RA) or IL-8RB. On the other hand, Gro-alpha induced an SK&F 96365-sensitive increase of the rate of Mn+2 influx in IL-8RB-, but not in IL-8RA-transfected 293 cells. These results indicate not only that neutrophils respond differently to IL-8 than they do to Gro-alpha but, furthermore, that the consequences of the binding of IL-8 and Gro-alpha to IL-8RB are distinct.

Acid aspiration-induced lung injury in rabbits is mediated by interleukin-8-dependent mechanisms

Acid aspiration lung injury may be mediated primarily by neutrophils recruited to the lung by acid-induced cytokines. We hypothesized that a major acid-induced cytokine was IL-8 and that a neutralizing anti-rabbit-IL-8 monoclonal antibody (ARIL8.2) would attenuate acid-induced lung injury in rabbits. Hydrochloric acid (pH = 1.5 in 1/3 normal saline) or 1/3 normal saline (4 ml/kg) was instilled into the lungs of ventilated, anesthetized rabbits. The rabbits were studied for 6 or 24 h. In acid-instilled rabbits without the anti-IL-8 monoclonal antibody, severe lung injury developed in the first 6 h; in the long-term experiments, all rabbits died with lung injury between 12 and 14 h. In acid-instilled rabbits given the anti-IL-8 monoclonal antibody (2 mg/kg, intravenously) either as pretreatment (5 min before the acid) or as treatment (1 h after the acid), acid-induced abnormalities in oxygenation and extravascular lung water were prevented and extravascular protein accumulation was reduced by 70%; in the long-term experiments, anti-IL-8 treatment similarly protected lung function throughout the 24-h period. The anti-IL-8 monoclonal antibody also significantly reduced air space neutrophil counts and IL-8 concentrations. This study establishes IL-8 as a critical cytokine for the development of acid-induced lung injury. Neutralization of IL-8 may provide the first useful therapy for this clinically important form of acute lung injury.

Staphylococcus aureus stimulates neutrophil recruitment by stimulating interleukin-8 production in dog trachea

The present study examined whether neutrophil recruitment in dog airways by Staphylococcus aureus is mediated by interleukin-8 (IL-8). S. aureus culture supernatant was superfused into an isolated tracheal segment in six dogs, and neutrophil recruitment and IL-8 concentrations were measured in the superfusate. Dog IL-8 was cloned, expressed in Escherichia coli, purified by chromatography, and shown to be biologically active. With the use of an enzyme-linked immunoabsorbent assay (ELISA) for the measurement of dog IL-8, we showed that S. aureus supernatant induced neutrophil recruitment and increased IL-8 concentration in the superfusate in a time-dependent manner. The chemotactic activity present in the superfusate 6 h after superfusion with S. aureus was inhibited by an anti-IL-8 antibody. S. aureus supernatant also stimulated IL-8 production and gene expression by cultured canine tracheal epithelial cells. These results provide evidence that IL-8 plays a major role in S. aureus-induced neutrophil recruitment in the airways by stimulating IL-8 production in airway cells.

Monoclonal antibodies detect different distribution patterns of IL-8 receptor A and IL-8 receptor B on human peripheral blood leukocytes

mAbs previously reported to be specific for IL-8R type A (IL-8R-A) and mAbs specific for IL-8R type B (IL-8R-B), which are described in this paper, were used to investigate the expression of each receptor on various types of cells. We generated mAbs specific for IL-8R-B, 4D1, and 10H2 by immunizing mice with 293 cells that expressed IL-8R-B and by selecting hybridoma cell lines that secreted mAbs that bind to human neutrophils. Flow cytometry showed that mAbs 4D1 and 10H2 were specific for IL-8R-B, as determined by their exclusive binding to 293-27 cells that expressed IL-8R-B, but not to 293-71 cells that expressed IL-8R-A. Epitopes recognized by these IL-8R-B-specific mAbs were shown to be within the N-terminal residues 1-18 of the IL-8R-B on the basis of their binding to various N-terminal peptides, as measured by ELISA. These IL-8R-B-specific mAbs were able to inhibit up to 90 and 50% of the 125I-labeled IL-8 binding to 293-27 cells and human neutrophils, respectively. The combination of mAb 9H1 (anti-IL-8R-A) and mAb 10H2 (anti-IL-8R-B) inhibited approximately 70% of 125I-labeled IL-8 binding to human neutrophils. Flow cytometry showed a wide range of donor variation in the expression levels of IL-8R-A and IL-8R-B on various human peripheral blood leukocytes. All neutrophils, all monocytes, and 5 to 25% of total lymphocytes (CD8+ T cells and CD56+ NK cells) expressed IL-8R. Neutrophils expressed the highest level of both IL-8R-A and IL-8R-B, at an approximately equal ratio, whereas monocytes and IL-8R+ lymphocytes expressed higher levels of IL-8R-B than IL-8R-A. Double-color flow cytometric analysis showed that 7 to 42% of CD8+ T cells and 39 to 76% of CD56+ NK cells, but no CD 20+ B cells or CD4+ T cells, expressed IL-8R.

Monoclonal antibodies detect different distribution patterns of IL-8 receptor A and IL-8 receptor B on human peripheral blood leukocytes

mAbs previously reported to be specific for IL-8R type A (IL-8R-A) and mAbs specific for IL-8R type B (IL-8R-B), which are described in this paper, were used to investigate the expression of each receptor on various types of cells. We generated mAbs specific for IL-8R-B, 4D1, and 10H2 by immunizing mice with 293 cells that expressed IL-8R-B and by selecting hybridoma cell lines that secreted mAbs that bind to human neutrophils. Flow cytometry showed that mAbs 4D1 and 10H2 were specific for IL-8R-B, as determined by their exclusive binding to 293-27 cells that expressed IL-8R-B, but not to 293-71 cells that expressed IL-8R-A. Epitopes recognized by these IL-8R-B-specific mAbs were shown to be within the N-terminal residues 1-18 of the IL-8R-B on the basis of their binding to various N-terminal peptides, as measured by ELISA. These IL-8R-B-specific mAbs were able to inhibit up to 90 and 50% of the 125I-labeled IL-8 binding to 293-27 cells and human neutrophils, respectively. The combination of mAb 9H1 (anti-IL-8R-A) and mAb 10H2 (anti-IL-8R-B) inhibited approximately 70% of 125I-labeled IL-8 binding to human neutrophils. Flow cytometry showed a wide range of donor variation in the expression levels of IL-8R-A and IL-8R-B on various human peripheral blood leukocytes. All neutrophils, all monocytes, and 5 to 25% of total lymphocytes (CD8+ T cells and CD56+ NK cells) expressed IL-8R. Neutrophils expressed the highest level of both IL-8R-A and IL-8R-B, at an approximately equal ratio, whereas monocytes and IL-8R+ lymphocytes expressed higher levels of IL-8R-B than IL-8R-A. Double-color flow cytometric analysis showed that 7 to 42% of CD8+ T cells and 39 to 76% of CD56+ NK cells, but no CD 20+ B cells or CD4+ T cells, expressed IL-8R.

Interleukin-8 is a major component of pleural liquid chemotactic activity in a rabbit model of endotoxin pleurisy

Gram-negative endotoxin induces production of the potent chemotactic factor interleukin-8 (IL-8) in vitro; however, the importance of IL-8 in endotoxin-induced inflammation in vivo is unknown. We asked whether IL-8 is an important contributor to chemotactic activity in acute inflammatory liquids formed in response to endotoxin, and, if present, what concentrations of IL-8 antigen are generated. For these studies, we cloned and expressed rabbit recombinant IL-8 (rrIL-8), developed specific anti-rabbit IL-8 monoclonal antibodies (mAb), and then used these reagents to develop assays to detect rabbit IL-8 bioactivity and measure rabbit IL-8 antigen. Escherichia coli endotoxin (20 ng/ml, n = 4, or 2,000 ng/ml, n = 4) was instilled into the pleural space of eight rabbits for 6 h. Rabbit IL-8 bioactivity in the endotoxin pleurisy samples was assayed by measuring the migration of rabbit neutrophils toward the pleural liquid under two different conditions: 1) after addition of an anti-IL-8 neutralizing mAb and 2) after desensitization of the neutrophils to rrIL-8. Addition of the anti-IL-8 mAb decreased neutrophil migration toward the pleural liquid by 65 +/- 13 and 75 +/- 22% (mean +/- SE, after 20 and 2,000 ng/ml endotoxin, respectively; P < 0.01 compared with a control mAb). Desensitization of neutrophils to rrIL-8 decreased their migration toward the pleural liquid by 72 +/- 5% (P = 0.03, compared with exposure of neutrophils to buffer alone.(ABSTRACT TRUNCATED AT 250 WORDS)

Complete mutagenesis of the extracellular domain of interleukin-8 (IL-8) type A receptor identifies charged residues mediating IL-8 binding and signal transduction

We systematically converted each of the amino acids in the extracellular domain of the interleukin-8 (IL-8) type A receptor to alanine for the purpose of identifying amino acids contributing to IL-8 binding and IL-8-mediated signal transduction. We identified 20 mutations which cause a decrease in receptor affinity from a Kd of 2 nM to a Kd > or = 25 nM. We then analyzed these receptor mutants for their ability to mobilize intracellular calcium upon stimulation with 10 nM IL-8. The majority of the mutants were able to produce calcium fluxes at levels approximating that of wild-type IL-8 receptor A, with the exception of six mutants (R199A, R203A, C30A, C110A, C187A, and C277A) which showed no significant response. In addition, we performed calcium mobilization experiments to further characterize a series of previously constructed mutants which had only been characterized by their binding affinities in our previous report and found that mutant D265A showed no response upon stimulation with 10 nM IL-8. Our study shows that, besides the extracellular domain cysteines which may be critical for the overall folding of the receptor, three residues, Arg-199, Arg-203, and Asp-265, are important for IL-8 binding and IL-8-mediated signal transduction.

Neutralization of IL-8 inhibits neutrophil influx in a rabbit model of endotoxin-induced pleurisy

Although the potent neutrophil chemotaxin, IL-8, is a known product of endotoxin-stimulated cells in vitro, the contribution of IL-8 to neutrophil recruitment in Gram-negative endotoxin inflammation in vivo is unknown. To determine whether neutralization of IL-8 would decrease endotoxin-induced neutrophil influx, we generated neutralizing mAbs to rabbit rIL-8 for use in our rabbit model of endotoxin-induced pleurisy. One mAb, ARIL8.2, specifically inhibited both rabbit rIL-8-induced chemotactic activity and activation of the rabbit IL-8 receptor transfected in 293 cells. Anesthetized rabbits with in-dwelling pleural catheters received either neutralizing mAb (ARIL8.2; 1 mg/kg) or irrelevant isotype-matched mAb (anti-HIV gp120) i.v. 1 h before as well as intrapleurally (20 micrograms/ml) at the time of intrapleural instillation of Escherichia coli endotoxin (200 ng bilaterally). ARIL8.2 blocked 77% of endotoxin-induced neutrophil influx (21 +/- 2 (SE) x 10(6) (ARIL8.2) vs 91 +/- 15 x 10(6) (anti-gp120) (p &lt; 0.0001)). By Western analysis, a band corresponding to rabbit IL-8 was detected in the pleural liquid of rabbits in both groups. By ELISA, however, the concentration of free, unbound IL-8 in the pleural liquid was significantly less in the ARIL8.2 group than in the anti-gp120 group for at least 4 h, confirming that ARIL8.2 bound the IL-8 generated in vivo during that time. We conclude that neutralization of IL-8 profoundly inhibits neutrophil recruitment in endotoxin-induced pleurisy indicating that IL-8 is a major chemotactic factor in this model of acute inflammation.

Neutralization of IL-8 inhibits neutrophil influx in a rabbit model of endotoxin-induced pleurisy

Although the potent neutrophil chemotaxin, IL-8, is a known product of endotoxin-stimulated cells in vitro, the contribution of IL-8 to neutrophil recruitment in Gram-negative endotoxin inflammation in vivo is unknown. To determine whether neutralization of IL-8 would decrease endotoxin-induced neutrophil influx, we generated neutralizing mAbs to rabbit rIL-8 for use in our rabbit model of endotoxin-induced pleurisy. One mAb, ARIL8.2, specifically inhibited both rabbit rIL-8-induced chemotactic activity and activation of the rabbit IL-8 receptor transfected in 293 cells. Anesthetized rabbits with in-dwelling pleural catheters received either neutralizing mAb (ARIL8.2; 1 mg/kg) or irrelevant isotype-matched mAb (anti-HIV gp120) i.v. 1 h before as well as intrapleurally (20 micrograms/ml) at the time of intrapleural instillation of Escherichia coli endotoxin (200 ng bilaterally). ARIL8.2 blocked 77% of endotoxin-induced neutrophil influx (21 +/- 2 (SE) x 10(6) (ARIL8.2) vs 91 +/- 15 x 10(6) (anti-gp120) (p < 0.0001)). By Western analysis, a band corresponding to rabbit IL-8 was detected in the pleural liquid of rabbits in both groups. By ELISA, however, the concentration of free, unbound IL-8 in the pleural liquid was significantly less in the ARIL8.2 group than in the anti-gp120 group for at least 4 h, confirming that ARIL8.2 bound the IL-8 generated in vivo during that time. We conclude that neutralization of IL-8 profoundly inhibits neutrophil recruitment in endotoxin-induced pleurisy indicating that IL-8 is a major chemotactic factor in this model of acute inflammation.

Partial functional mapping of the human interleukin-8 type A receptor. Identification of a major ligand binding domain

We have previously demonstrated that a basic amino acid residue of interleukin (IL)-8, namely Arg-6, is critical for the binding of IL-8 to its receptor. We reasoned that this residue is likely to be poised to directly interact with a counterpart acidic residue on the receptor. To identify this key residue, we systematically mutated to Ala all acidic residues present on the ligand accessible surface of IL-8 receptor type A. Using this strategy, we demonstrate that two residues which are present in extracellular loop 3 of the receptor, namely Glu-275 and Arg-280, are critical for ligand binding. In addition, we show that although Asp-11 is critical for ligand binding, a conservative mutation of Asp-11 to Glu or a substitution of Asp-11 with Lys (the residue found at position 11 in IL-8 receptor type B) does not affect the Kd of the receptor/ligand interaction. These data suggest that Lys-11 recruits a new and favorable interaction with IL-8 (analogous to that of IL-8 receptor type B with IL-8) or that the cavity created by mutating Asp-11 to Ala is particularly deleterious. Finally, we discuss fluorescence-activated cell sorter staining data which support the hypothesis that the N-terminal region and the extracellular loop 3 of the receptor may lie in close proximity of one another and constitute a major binding domain for IL-8.

Interleukin-8: an important chemoattractant in sputum of patients with chronic inflammatory airway diseases

Sputum from patients with cystic fibrosis, bronchiectasis, and chronic bronchitis contains neutrophils and neutrophil proteases, which have been implicated in the pathophysiology of mucus hypersecretion in airways. We asked whether interleukin-8 (IL-8), a potent neutrophil chemoattractant, might be involved in recruiting neutrophils into airways of patients with cystic fibrosis, bronchiectasis, and chronic bronchitis. We found significant neutrophil chemotactic activity in sputum obtained from these patients. The IL-8 concentrations that we measured in sputum of patients with cystic fibrosis (7.1 +/- 1.0 x 10(-9) M, mean +/- SE), bronchiectasis (9.6 +/- 2.9 x 10(-9) M), and chronic bronchitis (2.8 +/- 1.0 x 10(-9) M) have been reported to cause significant chemotaxis in vitro and in airways in vivo, whereas concentrations measured in induced sputum from healthy subjects (1.1 +/- 0.3 x 10(-10) M) do not. A monoclonal antibody to IL-8 significantly inhibited the chemotactic activity in patients' sputum by 75-98%, but not in induced sputum from healthy subjects (9%). We conclude that IL-8 is an important chemotactic factor in sputum of patients with cystic fibrosis, bronchiectasis, and chronic bronchitis, and we suggest that IL-8 accounts, at least in part, for neutrophil recruitment into airways of patients with these diseases.

Modulation of airway inflammation in cystic fibrosis. In vivo suppression of interleukin-8 levels on the respiratory epithelial surface by aerosolization of recombinant secretory leukoprotease inhibitor

Based on the knowledge that neutrophil elastase (NE) in cystic fibrosis (CF) epithelial lining fluid (ELF) can induce human bronchial epithelial cells to express the gene for interleukin 8 (IL-8), an 8.5-kD neutrophil chemoattractant, we have evaluated CF ELF for the presence of IL-8, and investigated the ability of aerosolized recombinant secretory leukoprotease inhibitor (rSLPI) to suppress NE, and hence IL-8, levels on the respiratory epithelial surface in CF. Enzyme-linked immunoassay revealed 21.9 +/- 4.8 nM IL-8 in CF ELF compared with none in normals. Active NE was detectable in ELF of all individuals with CF and was significantly decreased (P < 0.03) after aerosolization of rSLPI. Human bronchial epithelial cells exposed to CF ELF recovered before rSLPI therapy expressed IL-8 mRNA transcripts, but ELF recovered after rSLPI therapy induced far less bronchial epithelial cell IL-8 gene expression. Consistent with this, rSLPI aerosol therapy caused a marked reduction in CF ELF IL-8 levels (P < 0.05) and neutrophil number (P < 0.02). There was also a clear association between CF ELF active NE and IL-8 levels (r = 0.94). These data suggest that rSLPI therapy not only suppresses respiratory epithelial NE levels, but also breaks a cycle of inflammation on the CF epithelial surface.

Interleukin-8 is a major neutrophil chemotactic factor in pleural liquid of patients with empyema

Interleukin-8 (IL-8), a potent neutrophil chemotactic peptide, has been found in association with human disease, but its contribution to chemotactic activity in humans is not yet known. We asked whether IL-8 is present in inflammatory human pleural effusions, and to what extent it contributes to pleural liquid neutrophil chemotactic activity. Because tumor necrosis factor alpha (TNF-alpha) is a strong inducer of IL-8, we also asked whether TNF-alpha was present. For this prospective study, we collected pleural liquid from 51 patients (empyema, 14; parapneumonic, four; tuberculous, eight; malignant, nine; miscellaneous exudative, seven; and transudative, nine), counted pleural neutrophils, and measured IL-8 and TNF-alpha concentrations in the supernatant. To determine the contribution of IL-8 to chemotactic activity in empyema, we measured the neutrophil migration induced by empyemic liquids before and after addition of anti-IL-8 F(ab')2 antibody fragments or control anti-IL-6 F(ab')2. We found that IL-8 concentrations were higher in empyema (61.3 +/- 21.0 ng/ml [SEM]) than in all other effusions (1.1 +/- 0.5 ng/ml) (p = 0.0001). All empyema liquids had IL-8 concentrations above 2.5 ng/ml, which was true for only three of the other 37 effusions (two parapneumonic, one tuberculous). IL-8 levels correlated with the pleural neutrophil count (r = 0.46; p = 0.007) and the neutrophil chemotactic activity of pleural liquid (r = 0.43; p = 0.008). Anti-IL-8 antibodies decreased chemotactic activity in empyema liquids by 65 +/- 5%, whereas the control antibody had no effect (0 +/- 5% decrease) (p = 0.0005).(ABSTRACT TRUNCATED AT 250 WORDS)

In vitro inhibitory effect of IL-8 and other chemoattractants on neutrophil-endothelial adhesive interactions

We have previously reported that cytokine- or LPS-activated human umbilical vein endothelial cell (HUVEC) monolayers secrete IL-8 that can act as a neutrophil-selective adhesion inhibitor. In our study we investigated the mechanisms involved in the leukocyte adhesion inhibitory action of IL-8. The leukocyte adhesion inhibitory effect appears to be mediated by the action of IL-8 on the neutrophil, does not involve down-regulation of relevant endothelial adhesion molecules such as endothelial-leukocyte adhesion molecule-1 or intercellular adhesion molecule-1, and is quantitatively similar in different endothelial activation states that are predominantly endothelial-leukocyte adhesion molecule-1 dependent or intercellular adhesion molecule-1 dependent. In addition to inhibiting the attachment of freshly isolated peripheral blood neutrophils to cytokine-activated HUVEC monolayers, IL-8 also promoted a rapid detachment of tightly adherent neutrophils from activated HUVEC, and abolished neutrophil transendothelial migration. Certain other chemoattractants, including FMLP and C5a, had similar inhibitory actions, indicating IL-8 was not unique in its ability to inhibit various neutrophil-endothelial interactions. In contrast, two other neutrophil agonists 1-0-alkyl-2-acetyl sn-glycero-3-phosphocholine and granulocyte-macrophage-CSF, which, like IL-8, are produced by activated HUVEC, as well as the leukocyte-derived chemoattractant leukotriene B4, exerted minimal inhibitory effects on adhesion. Regardless of their ability to modulate neutrophil-endothelial cell adhesion, all these agents induced altered leukocyte surface expression of functionally important adhesion molecules, including loss of L-selectin (leukocyte adhesion molecule-1, LECAM-1) and increase in CD11b/CD18. Thus, although the above agonists have been characterized primarily as chemoattractants, our findings demonstrate that these agents can exert a wide range of modulatory effects on neutrophil-endothelial adhesive interactions.

In vitro inhibitory effect of IL-8 and other chemoattractants on neutrophil-endothelial adhesive interactions

We have previously reported that cytokine- or LPS-activated human umbilical vein endothelial cell (HUVEC) monolayers secrete IL-8 that can act as a neutrophil-selective adhesion inhibitor. In our study we investigated the mechanisms involved in the leukocyte adhesion inhibitory action of IL-8. The leukocyte adhesion inhibitory effect appears to be mediated by the action of IL-8 on the neutrophil, does not involve down-regulation of relevant endothelial adhesion molecules such as endothelial-leukocyte adhesion molecule-1 or intercellular adhesion molecule-1, and is quantitatively similar in different endothelial activation states that are predominantly endothelial-leukocyte adhesion molecule-1 dependent or intercellular adhesion molecule-1 dependent. In addition to inhibiting the attachment of freshly isolated peripheral blood neutrophils to cytokine-activated HUVEC monolayers, IL-8 also promoted a rapid detachment of tightly adherent neutrophils from activated HUVEC, and abolished neutrophil transendothelial migration. Certain other chemoattractants, including FMLP and C5a, had similar inhibitory actions, indicating IL-8 was not unique in its ability to inhibit various neutrophil-endothelial interactions. In contrast, two other neutrophil agonists 1-0-alkyl-2-acetyl sn-glycero-3-phosphocholine and granulocyte-macrophage-CSF, which, like IL-8, are produced by activated HUVEC, as well as the leukocyte-derived chemoattractant leukotriene B4, exerted minimal inhibitory effects on adhesion. Regardless of their ability to modulate neutrophil-endothelial cell adhesion, all these agents induced altered leukocyte surface expression of functionally important adhesion molecules, including loss of L-selectin (leukocyte adhesion molecule-1, LECAM-1) and increase in CD11b/CD18. Thus, although the above agonists have been characterized primarily as chemoattractants, our findings demonstrate that these agents can exert a wide range of modulatory effects on neutrophil-endothelial adhesive interactions.

Evidence of a role for mesothelial cell-derived interleukin 8 in the pathogenesis of asbestos-induced pleurisy in rabbits

Although acute asbestos-induced pleurisy is characterized by an influx of neutrophils, the identity of the factors that attract these cells to the pleural space and the source of the factors are unknown. We found that instillation of crocidolite asbestos into the pleural space of rabbits led to the appearance in pleural liquid of chemotactic activity for neutrophils, and that this chemotactic activity was inhibited significantly by a neutralizing antibody to human interleukin 8 (IL-8). Cultured rabbit pleural mesothelial cells incubated with crocidolite asbestos also released chemotactic activity for neutrophils, which was inhibited significantly by the anti-IL-8 antibody. To determine whether rabbit pleural mesothelial cells synthesize IL-8, we generated a probe for rabbit IL-8 mRNA by amplifying cDNA prepared from stimulated pleural mesothelial cells using the polymerase chain reaction (PCR) and primers based on homologous sequences in human and sheep IL-8 cDNAs. Homology-based PCR yielded a single cDNA fragment with a nucleotide sequence 88% identical to that of a corresponding region of human IL-8 cDNA. With the radiolabeled PCR product as a probe, we demonstrated rapid induction of IL-8 mRNA expression in pleural mesothelial cells exposed to asbestos. As expected, tumor necrosis factor-alpha also led to the appearance of IL-8 in the rabbit pleural space and stimulated cultured pleural mesothelial cells to synthesize and release IL-8. We conclude that asbestos directly stimulates pleural mesothelial cells to synthesize IL-8 and that mesothelial cell-derived IL-8 may play an important role in mediating asbestos-induced pleural inflammation.

Effects of intravenous IL-8 administration in nonhuman primates

IL-8, a cytokine known for its potent and specific neutrophil activation and chemoattractant properties, has been recently detected in the circulation during septic shock, endotoxemia, and after IL-1 alpha administration. Because of its observed in vitro actions, it has been hypothesized that IL-8 may contribute to the dynamics of circulating granulocytes and to the pathologic sequelae seen in sepsis. Here, human rIL-8 is administered to healthy nonhuman primates as a single i.v. injection or as a continuous 8-h i.v. infusion. We demonstrate that both methods of i.v. administration result in a rapid but transient, severe granulocytopenia, followed by a granulocytosis that persists as long as IL-8 levels are detectable in the circulation. There were no hemodynamic changes after IL-8 administration, and animals remained clinically stable during the 24-h observation period. No detectable circulating TNF-alpha, IL-1 beta, or IL-6 response was induced by either IL-8 administration regimen. Histopathologic examination revealed mild to moderate neutrophilic margination in lung, liver, and spleen, of greater severity in baboons receiving the 8-h infusion. There was no associated neutrophilic infiltration or tissue injury. Thus, IL-8 modulates circulating granulocyte dynamics and likely directs their actions, but when administered i.v. to healthy animals, either as a bolus dose or as a continuous infusion for up to 8 h, does not induce the hemodynamic and metabolic aberrations or the acute organ damage seen during sepsis.

Effects of intravenous IL-8 administration in nonhuman primates

IL-8, a cytokine known for its potent and specific neutrophil activation and chemoattractant properties, has been recently detected in the circulation during septic shock, endotoxemia, and after IL-1 alpha administration. Because of its observed in vitro actions, it has been hypothesized that IL-8 may contribute to the dynamics of circulating granulocytes and to the pathologic sequelae seen in sepsis. Here, human rIL-8 is administered to healthy nonhuman primates as a single i.v. injection or as a continuous 8-h i.v. infusion. We demonstrate that both methods of i.v. administration result in a rapid but transient, severe granulocytopenia, followed by a granulocytosis that persists as long as IL-8 levels are detectable in the circulation. There were no hemodynamic changes after IL-8 administration, and animals remained clinically stable during the 24-h observation period. No detectable circulating TNF-alpha, IL-1 beta, or IL-6 response was induced by either IL-8 administration regimen. Histopathologic examination revealed mild to moderate neutrophilic margination in lung, liver, and spleen, of greater severity in baboons receiving the 8-h infusion. There was no associated neutrophilic infiltration or tissue injury. Thus, IL-8 modulates circulating granulocyte dynamics and likely directs their actions, but when administered i.v. to healthy animals, either as a bolus dose or as a continuous infusion for up to 8 h, does not induce the hemodynamic and metabolic aberrations or the acute organ damage seen during sepsis.

Scanning mutagenesis of interleukin-8 identifies a cluster of residues required for receptor binding

In order to identify residues required for the binding of interleukin-8 (IL-8) to its receptor, mutants were constructed in which clusters of charged amino acids were systematically replaced with alanine along the entire IL-8 sequence. The mutants were tested for their ability to induce a receptor-mediated rise in cytosolic free Ca2+, a property of wild-type IL-8 which can readily be detected by flow cytometry using neutrophils loaded with the calcium probe Indo-1. Eleven of the 12 mutants caused neutrophil calcium mobilization at 5 nM; the exception being a triple alanine mutant at positions K3, E4, and R6, which was inactive at all concentrations tested (150 nM maximum). A second set of mutants was generated in which residues 1-15 were individually mutated to alanine. Mutants E4A, L5A, or R6A were all inactive in the Ca2+ assay at 5 nM and competed poorly with 125I-IL-8 for neutrophil receptor binding; I10A, E4A, L5A, and R6A had approximately 30-, 100-, 100-, and 1000-fold reduced affinity, as compared with control IL-8, respectively. The nuclear magnetic resonance structure of IL-8 indicates that, in solution, the side chains of E4, L5, R6, and I10 point away from the core of the protein and do not participate in any intramolecular hydrogen bonds or salt bridges (Clore, G. M., and Gronenborn, A. M. (1991) J. Mol. Biol. 217, 611-620).

Red blood cells are a sink for interleukin 8, a leukocyte chemotaxin

IL-8 (also known as neutrophil-activating peptide 1) is recognized as a potent effector of neutrophil functions. Several different cell types that contact blood, namely T lymphocytes, monocytes, and endothelial cells, secrete this polypeptide following stimulation by cytokines, or lipopolysaccharide. Here we show that when IL-8 is added to blood it rapidly partitions from the plasma fluid to the blood cells and that erythrocytes account for the vast majority of this binding. Analysis of 125I-IL-8 binding [( ala-IL-8]77 form) to human red cells indicates a single, 5 nM Kd affinity class of binding sites, present at approximately 2,000 per red cell representing approximately 15 nmol of red cell IL-8 binding sites per liter of blood. These sites are protease sensitive. Their binding of IL-8 is rapidly reversible and does not result in receptor internalization, although bound IL-8 is resistant to extraction by pH 3 buffer at 5 degrees C. 125I-IL-8 binding to red cells was not inhibited by epidermal growth factor or interleukin 1, but was inhibited by monocyte chemotactic peptide-1, which is not a neutrophil chemotaxin, but is a member of the same family of polypeptides as IL-8. FACS analysis of IL-8-mediated mobilization of Ca2+ in neutrophils indicates that the IL-8 bound to red cells is incapable of stimulating neutrophils. Thus, red cell absorption of IL-8 may function to limit stimulation of leukocytes by IL-8 released into blood.

Endothelial and leukocyte forms of IL-8. Conversion by thrombin and interactions with neutrophils

We have recently shown that endothelial cell-derived IL-8 inhibits neutrophil adhesion to IL1-beta-activated human umbilical vein endothelial cell monolayers. IL-8 secreted by T lymphocytes or monocytes has been characterized as a promoter of neutrophil degranulation and chemotaxis. The IL-8 isolated from each of these cell types is a mixture of two IL-8 polypeptides, one consisting of 72 amino acids (herein called [ser-IL-8]72) and the other 77 amino acids (an N-terminal extended form herein called [ala-IL-8]77). IL-8 derived from T lymphocytes and monocytes is predominantly [ser-IL-8]72, whereas endothelial-derived IL-8 is highly enriched (greater than 80%) in [ala-IL-8]77. We address the relationship and activities of these two forms of IL-8 using recombinant proteins expressed by both mammalian cells and Escherichia coli. Thrombin was found to efficiently convert [ala-IL-8]77 to [ser-IL-8]72. In contrast, urokinase and tissue-type plasminogen activator were unable to cleave [ala-IL-8]77, and trypsin generated multiple IL-8 cleavage fragments. In competitive binding assays using 125I[ala-IL-8]77 neutrophils exhibited a twofold preference for [ser-IL-8]72 over [ala-IL-8]77. Both forms of IL-8 inhibited neutrophil adhesion to IL-1-beta-activated HUVEC monolayers by up to 90%. However, [ser-IL-8]72 was approximately 10-fold more potent than [ala-IL-8]77 in these assays (ED50 approximately 0.3 nM for [ser-IL-8]72 vs approximately 3 nM for [ala-IL-8]77. Both forms of IL-8 promoted degranulation of cytochalasin B-treated neutrophils [[ser-IL-8]72 (ED50 greater than 10 nM) was two- to three-fold more potent than [ala-IL-8]77], although in this regard they were less active than FMLP. Our data suggest that [ala-IL-8]77 and [ser-IL-8]72 have qualitatively similar and potentially complex biological activities, and that full activation of IL-8 requires cleavage to the [ser-IL-8]72 form. In the case of inflamed endothelial cells this activation could be mediated by thrombin generated in the procoagulant environment associated with these cells.

Endothelial and leukocyte forms of IL-8. Conversion by thrombin and interactions with neutrophils

We have recently shown that endothelial cell-derived IL-8 inhibits neutrophil adhesion to IL1-beta-activated human umbilical vein endothelial cell monolayers. IL-8 secreted by T lymphocytes or monocytes has been characterized as a promoter of neutrophil degranulation and chemotaxis. The IL-8 isolated from each of these cell types is a mixture of two IL-8 polypeptides, one consisting of 72 amino acids (herein called [ser-IL-8]72) and the other 77 amino acids (an N-terminal extended form herein called [ala-IL-8]77). IL-8 derived from T lymphocytes and monocytes is predominantly [ser-IL-8]72, whereas endothelial-derived IL-8 is highly enriched (greater than 80%) in [ala-IL-8]77. We address the relationship and activities of these two forms of IL-8 using recombinant proteins expressed by both mammalian cells and Escherichia coli. Thrombin was found to efficiently convert [ala-IL-8]77 to [ser-IL-8]72. In contrast, urokinase and tissue-type plasminogen activator were unable to cleave [ala-IL-8]77, and trypsin generated multiple IL-8 cleavage fragments. In competitive binding assays using 125I[ala-IL-8]77 neutrophils exhibited a twofold preference for [ser-IL-8]72 over [ala-IL-8]77. Both forms of IL-8 inhibited neutrophil adhesion to IL-1-beta-activated HUVEC monolayers by up to 90%. However, [ser-IL-8]72 was approximately 10-fold more potent than [ala-IL-8]77 in these assays (ED50 approximately 0.3 nM for [ser-IL-8]72 vs approximately 3 nM for [ala-IL-8]77. Both forms of IL-8 promoted degranulation of cytochalasin B-treated neutrophils [[ser-IL-8]72 (ED50 greater than 10 nM) was two- to three-fold more potent than [ala-IL-8]77], although in this regard they were less active than FMLP. Our data suggest that [ala-IL-8]77 and [ser-IL-8]72 have qualitatively similar and potentially complex biological activities, and that full activation of IL-8 requires cleavage to the [ser-IL-8]72 form. In the case of inflamed endothelial cells this activation could be mediated by thrombin generated in the procoagulant environment associated with these cells.

Endothelial interleukin-8: a novel inhibitor of leukocyte-endothelial interactions

Certain inflammatory stimuli render cultured human vascular endothelial cells hyperadhesive for neutrophils. This state is transient and reversible, in part because activated endothelial cells secrete a leukocyte adhesion inhibitor (LAI). LAI was identified as endothelial interleukin-8 (IL-8), the predominant species of which is an extended amino-terminal IL-8 variant. At nanomolar concentrations, purified endothelial IL-8 and recombinant human IL-8 inhibit neutrophil adhesion to cytokine-activated endothelial monolayers and protect these monolayers from neutrophil-mediated damage. These findings suggest that endothelial-derived IL-8 may function to attenuate inflammatory events at the interface between vessel wall and blood.

Linkage of extracellular plasminogen activator to the fibroblast cytoskeleton: colocalization of cell surface urokinase with vinculin

Several cell types display binding sites for [125I]urokinase (Vassalli, J.-D., D. Baccino, D. Belin. 1985. J. Cell Biol. 100:86-92) which in certain cases are occupied with endogenous urokinase. These sites appear to focus urokinase at cell surfaces and hence may participate in tissue matrix destruction and cell invasion. Recently Pöllänen et al. (1987) demonstrated that the cell surface urokinase of human fibroblasts and fibrosarcoma cells is deposited underneath the cells in strands, apparently at sites of cell-to-substratum contact. Here, using immunofluorescence double labeling, we show that the urokinase strands present on human foreskin fibroblasts are colocalized with strands of vinculin, an intracellular actin-binding protein that is deposited at cell-to-substratum focal adhesion sites. Thus, this indicates linkage of the plasminogen/plasmin system both to sites of cell adhesion and to the cytoskeleton. The urokinase strands on HT 1080 fibrosarcoma cells are more numerous and have shapes that are more tortuous than those on normal fibroblasts. In intact HT 1080 cells, colocalized vinculin strands are obscured by an intense background of soluble vinculin but are apparent on isolated ventral plasma membranes. Certain properties of the urokinase strands suggest that they are related to the [125I]urokinase-binding sites that have been described by several groups: (a) incubating fibroblasts with dexamethasone for 48 h or at pH 3 at 5 degrees C for 10 min greatly decreases the number and intensity of the urokinase strands; (b) strands reappear when glucocorticoid-treated cells are incubated with exogenous 54-kD (but not 35-kD) urokinase, and this process is inhibited by a previously described 16-amino acid peptide that blocks [125I]urokinase binding to the cells.