Recent developments in modulating chemokine networks

Cellular assays of chemokine receptor activation

This unit describes procedures for measuring the activation of chemokine receptors by their ligands. Chemokines are chemoattractant proteins and two assays are described for analyzing the chemoattractant properties (chemotaxis) of these proteins. Chemokine receptors are coupled to G proteins, and activation of the receptors results in the mobilization of intracellular Ca²⁺ stores. Two assays for the measurement of this activity are described which employ calcium-sensitive dyes, one for adherent and one for non-adherent cells. In addition, an assay for quantitating chemokine receptor downmodulation and subsequent recycling events is described. The assays are applicable to both purified leukocytes and stably expressed recombinant chemokine receptors.This unit describes procedures for measuring the activation of chemokine receptors by their ligands.

Diaryl substituted pyrazoles as potent CCR2 receptor antagonists

We have identified and synthesized a series of diaryl substituted pyrazoles as potent antagonists of the chemokine receptor subtype 2. Structure-activity relationship studies directed toward improving the potency led to the discovery of 23 (IC50 = 6 nM).

The biological relevance of chemokine–proteoglycan interactions

Chemokines exert their biological activity through high-affinity interactions with cell-surface receptors, thereby activating specific signalling pathways, and a second low-affinity interaction with proteoglycans. Proteoglycans consist of a protein core, to which GAG (glycosaminoglycan) chains are attached. The GAGs are long, linear, sulphated and highly charged heterogeneous polysaccharides that are expressed throughout the body in different forms depending on the developmental or pathological state of the organ/organism. Mechanistically, the GAG interaction is thought to facilitate the retention of chemokines on cell surfaces, thereby forming a high local concentration required for cell activation. Recently, we demonstrated that certain chemokines require interactions with GAGs for their in vivo function. Additionally we have shown that chemokines oligomerize on immobilized GAGs, and this ability to form higher order oligomers has also been shown to be essential for the activity of certain chemokines in vivo. We believe that interference with the chemokine–GAG interaction provides a novel anti-inflammatory strategy, exemplified by a variant of RANTES (regulated upon activation, normal T-cell expressed and secreted) that has abrogated GAG binding and oligomerization properties.

Chemokines in acute respiratory distress syndrome

A characteristic feature of all inflammatory disorders is the excessive recruitment of leukocytes to the site of inflammation. The loss of control in trafficking these cells contributes to inflammatory diseases. Leukocyte recruitment is a well-orchestrated process that includes several protein families including the large cytokine subfamily of chemotactic cytokines, the chemokines. Chemokines and their receptors are involved in the pathogenesis of several diseases. Acute lung injury that clinically manifests as acute respiratory distress syndrome (ARDS) is caused by an uncontrolled systemic inflammatory response resulting from clinical events including major surgery, trauma, multiple transfusions, severe burns, pancreatitis, and sepsis. Systemic inflammatory response syndrome involves activation of alveolar macrophages and sequestered neutrophils in the lung. The clinical hallmarks of ARDS are severe hypoxemia, diffuse bilateral pulmonary infiltrates, and normal intracardiac filling pressures. The magnitude and duration of the inflammatory process may ultimately determine the outcome in patients with ARDS. Recent evidence shows that activated leukocytes and chemokines play a key role in the pathogenesis of ARDS. The expanding number of antagonists of chemokine receptors for inflammatory disorders may hold promise for new medicines to combat ARDS.

Syntheses and SAR studies of 4-(heteroarylpiperdin-1-yl-methyl)-pyrrolidin-1-yl-acetic acid antagonists of the human CCR5 chemokine receptor

Efforts toward the exploration of the title compounds as CCR5 antagonists are disclosed. The basis for such work stems from the fact that cellular proliferation of HIV-1 requires the cooperative assistance of both CCR5 and CD4 receptors. The synthesis and SAR of pyrrolidineacetic acid derivatives as CCR5 antagonists displaying potent binding and antiviral properties in a HeLa cell-based HIV-1 infectivity assay are discussed.

Syntheses and biological evaluation of 5-(piperidin-1-yl)-3-phenyl-pentylsulfones as CCR5 antagonists

Cellular proliferation of HIV-1 requires the cooperative assistance of both the CCR5 and CD4 receptors. Our medicinal chemistry efforts in this area have resulted in the identification of N-alkyl piperidine sulfones as CCR5 antagonists. These compounds display potent binding and show antiviral properties in HIV-1 spread cell-based assays.

New therapeutics that modulate chemokine networks

Chemokines are small cytokines that control a wide variety of biological and pathological processes, from immunosurveillance to inflammation, and from viral infection to cancer. The numerous known chemokine receptors have given hope that selective receptor antagonism might be possible, which could allow us to control which cells are recruited and activated at any time and in any place. As chemokine receptors are G-protein-coupled receptors, which are classical targets for the pharmaceutical industry, it is hoped that chemokines could be the first cytokines for which small-molecule receptor antagonists could be developed. Recently, reports of chemokine-receptor antagonists, both in vitro and in animal models of disease, have been published. It is anticipated that this field could produce clinically useful therapies in the next few years.

Characterization of chemokine receptors

This unit describes the procedures for measuring binding of a radiolabeled chemokine to chemokine receptors in cells or cell membranes. The whole-cell binding assay can be used for both purified leukocytes as well as transfected cell lines expressing chemokine receptors. Two basic protocols are described. The first is applicable to all cells expressing chemokine receptors, both primary cultures as well as recombinantly transfected cell lines expressing a single chemokine receptor. The second is used principally for transfected cell lines and measures chemokine binding to cell membranes using scintillation proximity assay (SPA) methodology, but does not require washing steps and thus is applicable to automated high-throughput screening strategies. An alternative procedure is also described which also uses SPA methodology to measure GTP-gamma-S binding to chemokine receptors in cell membranes. The two basic protocols can be used to determine the binding of compounds to chemokine receptors, while the alternate protocol determines the effects of compounds on the chemokine-stimulated activation of the receptor.

Discovery of potent and selective phenylalanine derived CCR3 antagonists. Part 1

The discovery of a series of phenylalanine derived CCR3 antagonists is reported. Parallel, solution-phase library synthesis has been utilized to delineate the structure-activity relationship leading to the synthesis of highly potent, CCR3-selective antagonists.

Asthma: where beyond steroids?

The prevalence of asthma is increasing dramatically despite major changes in monitoring and treatment of this disease. Currently available bronchodilators and anti-inflammatory drugs are effective in most patients, although these can have side effects and are mainly symptomatic. Many drugs are now in development for the treatment of asthma. Most of these new therapies are aimed at inhibition of the inflammatory components, with better safety profiles than steroids.