Recruitment pharmacophore for interleukin 5 receptor alpha antagonism.

Interleukin-5 receptor alpha is a therapeutic target for hypereosinophilic diseases including allergic inflammations and asthma. The cyclic peptide AF17121 (Ac-VDE[CWRIIASHTWFC]AEE-CONH(2)) has been identified as a submicromolar inhibitor of interleukin 5 (IL5)-interleukin 5 receptor alpha (IL5Ralpha) interaction from a random peptide screen. However, this inhibitor has limitations as a drug lead because of its relatively large size. We used chemical synthesis of peptides with natural and non-natural amino acids along with kinetic binding and cell proliferation competition assays to expand definition of structural elements in the peptide that are important for receptor antagonism and to elucidate the underlying pharmacophore. We found that the specific steric array of hydrogen bonding groups in the Arg 6 guanido side chain is critical for receptor inhibition. We also investigated noncharged structural elements in AF17121. Screening a set of five hydrophobic residues showed that peptide function is strongly sensitive to variations in several of these residues, most prominently Ile 7 and Trp 13. We postulate that presentation of charged, hydrogen bonding and hydrophobic structural elements within the disulfide-constrained peptide drives IL5Ralpha recruitment by AF17121. We hypothesize from these results and previous receptor mutagenesis studies that Arg 6 recruitment of IL5Ralpha occurs through hydrogen bonding as well as charge-charge interactions with Asp 55 in site one of domain 1 of IL5Ralpha, and that this interaction is complemented by additional charged and hydrophobic interactions around the Asp 55 locus. Scaffolding a limited set of structural elements in the inhibitor pharmacophore may be useful for small molecule antagonist design inspired by the peptide.

5-HT(1B) receptors play a prominent role in the proliferation of T-lymphocytes.

Serotonin plays a role in T cell activation, but there is no clear consensus of which of the 14 serotonergic receptors control this activations pathway. We have used a broad range of serotonergic receptor antagonists to define the functional involvement of these receptors governing the proliferation of primary T cells as well as in T cell lines. Our data shows that antagonism of the 5-HT(1B) receptor inhibits the proliferation of both human and murine primary helper T cells and of human helper T cell lines. As a whole, our data suggest that other serotonergic receptors may contribute to the proliferative signals, but the 5-HT(1B) receptor plays the most dominant role.

New insights from the structure-function analysis of the catalytic region of human platelet phosphodiesterase 3A: a role for the unique 44-amino acid insert.

Human phosphodiesterase 3A (PDE3A) degrades cAMP, the major inhibitor of platelet function, thus potentiating platelet function. Of the 11 human PDEs, only PDE3A and 3B have 44-amino acid inserts in the catalytic domain. Their function is not clear. Incubating Sp-adenosine-3',5'-cyclic-S-(4-bromo-2,3-di-oxobutyl) monophosphorothioate (Sp-cAMPS-BDB) with PDE3A irreversibly inactivates the enzyme. High pressure liquid chromatography (HPLC) analysis of a tryptic digest yielded an octapeptide within the insert of PDE3A ((K)T(806)YNVTDDK(813)), suggesting that a substrate-binding site exists within the insert. Because Sp-cAMPS-BDB reacts with nucleophilic residues, mutants Y807A, D811A, and D812A were produced. Sp-cAMPS-BDB inactivates D811A and D812A but not Y807A. A docking model showed that Tyr(807) is 3.3 angstroms from the reactive carbon, whereas Asp(811) and Asp(812) are >15 angstroms away from Sp-cAMPS-BDB. Y807A has an altered K(m) but no change in k(cat). Activity of wild type but not Y807A is inhibited by an anti-insert antibody. These data suggest that Tyr(807) is modified by Sp-cAMPS-BDB and involved in substrate binding. Because the homologous amino acid in PDE3B is Cys(792), we prepared the mutant Y807C and found that its K(m) and k(cat) were similar to the wild type. Moreover, Sp-cAMPS-BDB irreversibly inactivates Y807C with similar kinetics to wild type, suggesting that the tyrosine may, like the cysteine, serve as a H donor. Kinetic analyses of nine additional insert mutants reveal that H782A, T810A, Y814A, and C816S exhibit an altered k(cat) but not K(m), indicating that catalysis is modulated. We document a new functional role for the insert in which substrate binding may produce a conformational change. This change would allow the substrate to bind to Tyr(807) and other amino acids in the insert to interact with residues important for catalysis in the active site cleft.

Asymmetric usage of antagonist charged residues drives interleukin-5 receptor recruitment but is insufficient for receptor activation.

The cyclic peptide AF17121 (VDECWRIIASHTWFCAEE) is a library-derived antagonist for human Interleukin-5 receptor alpha (IL5Ralpha). We have previously demonstrated that AF17121 mimics Interleukin-5 (IL5) by binding in a region of IL5Ralpha that overlaps the IL5 binding epitope. In the present study, to explore the functional importance of the amino acid residues of AF17121 required for effective binding to, and antagonism of, IL5Ralpha, each charged residue was subjected to site-directed mutagenesis and examined for IL5Ralpha interaction by using a surface plasmon resonance biosensor. One residue, Arg(6), was found to be essential for receptor antagonism; its replacement with either alanine or lysine completely abolished the interaction between AF17121 and IL5Ralpha. Other charged residues play modulatory roles. One class consists of the N-terminal acidic cluster (Asp(2) and Glu(3)) for which alanine replacement decreased the association rate. A second class consists of His(11) and the C-terminal acidic cluster (Glu(17) and Glu(18)) for which alanine replacement increased the dissociation rate. Binding model analysis of the mutants of the latter class of residues indicated the existence of conformational rearrangement during the interaction. On the basis of these results, we propose a model in which Arg(6) and N-terminal acidic residues drive the encounter complex, while Arg(6), His(11), and C-terminal acidic residues are involved in stabilizing the final complex. These data argue that the charged residues of AF17121 are utilized asymmetrically in the pathway of inhibitor-receptor complex formation to deactivate the receptor function. The results also help focus emerging models for the mechanism by which IL5 activates the IL5Ralpha-betac receptor system.

Differential activation and inhibition of human platelet thrombin receptors by structurally distinct alpha-, beta- and gamma-thrombin.

The development of drugs to neutralize the action of thrombin has to date focused on the alpha form of the protease. It is generally agreed that inactive prothrombin is proteolytically converted to active alpha-thrombin which may be further hydrolyzed to beta- and gamma-thrombin. While all three forms of the enzyme retain catalytic activities, only alpha-thrombin is presumed to be physiologically important. The beta- and gamma-thrombin are presumed to be degradation products of no physiological significance. Our demonstration that beta- and gamma-thrombin selectively activate PAR-4 in this and a previous report (J. Biol. Chem. 276, 21173-21183, 2001) necessitates a reevaluation of how we view their physiological roles and how we approach the pharmacological regulation of their actions. Beta-thrombin, like gamma-thrombin, at nM levels selectively activates PAR-4. This was demonstrated by full retention of aggregatory activity with platelets whose PAR-1 and GP Ib receptors were inactivated. Furthermore, the beta-thrombin response was abrogated by desensitizing platelets with suboptimal levels of the thrombin receptor activating peptide for PAR-4 (TRAP-4). For beta-thrombin and gamma-thrombin to have a physiological role, it is necessary to show they can be generated under physiological conditions. We demonstrate, for the first time, that alpha-thrombin is hydrolyzed in less than 1 min by activated factor X at physiological pH, in vitro. This implies that alpha-thrombin may be rapidly converted to beta-thrombin and/or gamma-thrombin in vivo in the proper microenvironment. The differential activation of the three platelet thrombin receptors by alpha-, beta- and gamma-thrombin implies selective structural variations between these thrombin species. Structural differences are likely to account for the marked differential responses observed with the antithrombotic, hirudin, which inhibits alpha-thrombin , is a slightly weaker inhibitor of beta-thrombin and a very weak inhibitor of gamma-thrombin -induced platelet aggregations. The converse order of inhibition is observed with the physiological protease inhibitor, alpha(1)-antitrypsin. Finally, a non-traditional inhibitor, histone-1, selectively inhibits only beta- and gamma-thrombin , primarily at the receptor level of PAR-4 rather than on the thrombin molecule. Trypsin, like beta- and gamma-thrombin , activates PAR-4 and is also inactive with TRAP-4 desensitized platelets. Therefore, it was reasoned that trypsin would be more structurally similar to gamma-thrombin than to alpha-thrombin. The analysis of the crystalline structures of alpha-, gamma-thrombin and trypsin from the databases confirm that this is the case. These findings should help to elucidate structure-function relationships of the different thrombins and may aid in the development of new anti-thrombotic drugs.

Systemic treatment of cerebral cortex lesions in rats with a new secreted phospholipase A2 inhibitor.

An internal fragment of the human neuroprotective polypeptide DSEP (Diffusible Survival Evasion Peptide) was delivered at 0.4 mg/kg (subcutaneously) 20-30 min after stab wound lesions in the parietal cortex of anesthetized rats. The peptide, CHEASAAQC or CHEC-9, inhibited the inflammatory response to the lesion and the degeneration of neurons adjacent to the wound. Four days after surgery, peptide-treated animals (n = 6) had 75% fewer reactive ameboid microglia/brain macrophages in the cortical parenchyma surrounding the lesion compared to vehicle-injected control rats (n = 6, p = 0.004). The cortical laminae in area 2 adjacent to the lesion were completely obscured in controls because of the increase in inflammatory cells and frank degeneration of neurons, while there was preservation of the neurons and cytoarchitecture after peptide treatment. In parallel experiments, CHEC-9 was found to inhibit the enzymatic activity of secreted phospholipase A2 (sPLA2), including activity present in the serum of peptide-injected rats. Kinetic analysis revealed the peptide increased the average Km for serum by 318% when tested 45 min after treatment (peptide-treated, n = 6; control-treated, n = 6; p = 0.0087), suggesting the principal effect of the peptide was to lower the affinity of serum sPLA2 for substrate. The sPLA2 inhibition by this particular peptide sequence appeared to be highly specific since inversion of a single pair of amino acids eliminated the inhibitory effect. Phorbol-12-myristate-13-acetate stimulated platelet aggregation, a PLA2-regulated activity, was also inhibited by the peptide. The discovery of CHEC-9 makes it possible to study in vivo the long appreciated contribution made by PLA2-directed inflammation to both acute and chronic neurodegeneration and may be helpful in designing therapies to limit neuron death in these conditions.

Temperature-sensitive mutation in yeast mitochondrial ribosome recycling factor (RRF).

The yeast protein Rrf1p encoded by the FIL1 nuclear gene bears significant sequence similarity to Escherichia coli ribosome recycling factor (RRF). Here, we call FIL1 Ribosome Recycling Factor of yeast, RRF1. Its gene product, Rrf1p, was localized in mitochondria. Deletion of RRF1 leads to a respiratory incompetent phenotype and to instability of the mitochondrial genome (conversion to rho(-)/rho(0) cytoplasmic petites). Yeast with intact mitochondria and with deleted genomic RRF1 that harbors a plasmid carrying RRF1 was prepared from spores of heterozygous diploid yeast. Such yeast with a mutated allele of RRF1, rrf1-L209P, grew on a non-fermentable carbon source at 30 but not at 36 degrees C, where mitochondrial but not total protein synthesis was 90% inhibited. We propose that Rrf1p is essential for mitochondrial protein synthesis and acts as a RRF in mitochondria.