Vemuri B. Reddy

Cowhage-Evoked Itch Is Mediated by a Novel Cysteine Protease: A Ligand of Protease-Activated Receptors

Cowhage spicules provide an important model for histamine-independent itch. We determined that the active component of cowhage, termed mucunain, is a novel cysteine protease. We isolated mucunain and demonstrate that both native and recombinant mucunain evoke the same quality of itch in humans. We also show that mucunain is a ligand for protease-activated receptors two and four. These results support and expand the relationship between proteases, protease-activated receptors, and itch.

Maxadilan, a PAC1 receptor agonist from sand flies

In 1991, a potent 61 amino acid vasodilator peptide, named maxadilan, was isolated from the salivary glands of the sand fly. Subsequently, it was shown that this peptide specifically and potently activated the mammalian PAC1 receptor, one of the three receptors for PACAP. These studies and the link between maxadilan and leishmaniasis are discussed.

Redefining the concept of protease-activated receptors: cathepsin S evokes itch via activation of Mrgprs

Sensory neurons expressing Mas-related G protein coupled receptors (Mrgprs) mediate histamine-independent itch. We show that the cysteine protease cathepsin S activates MrgprC11 and evokes receptor-dependent scratching in mice. In contrast to its activation of conventional protease-activated receptors, cathepsin S mediated activation of MrgprC11 did not involve the generation of a tethered ligand. We demonstrate further that different cysteine proteases selectively activate specific mouse and human Mrgpr family members. This expansion of our understanding by which proteases interact with GPCRs redefines the concept of what constitutes a protease-activated receptor. The findings also implicate proteases as ligands to members of this orphan receptor family while providing new insights into how cysteine proteases contribute to itch.

Chrysoptin Is a Potent Glycoprotein IIb/IIIa Fibrinogen Receptor Antagonist Present in Salivary Gland Extracts of the Deerfly

Salivary gland lysates of the deerfly (genusChrysops) contain chrysoptin, an inhibitor of ADP-induced platelet aggregation, which presumably assists the fly in obtaining a blood meal. Chrysoptin has now been isolated, and its cDNA has been cloned and expressed. Chrysoptin was purified to homogeneity using anion exchange and hydrophobic interaction chromatography and found to be a protein with a molecular mass of 65 kDa as determined by gel electrophoresis. N-terminal amino acid sequencing allowed for the synthesis of degenerate oligonucleotides that led to cloning, from salivary gland specific mRNA, of the cDNA encoding this platelet inhibitor. No RGD sites are present in the predicted sequence. A search of GenBankTM did not reveal significant sequence homology between chrysoptin and other proteins. The molecular mass predicted from the cDNA was 59 kDa. Predicted glycosylation and phosphorylation sites may account for this difference in molecular mass, as recombinant chrysoptin expressed in Sf21 cells had a molecular mass of 65 kDa, matching that of the natural protein. Chrysoptin functions by inhibiting the binding of fibrinogen to the fibrinogen/glycoprotein IIb/IIIa receptor on platelets with an IC50 of 95 pmol. These results reveal that insect salivary glands are a source of fibrinogen receptor antagonists.

Cathepsin S Signals via PAR2 and Generates a Novel Tethered Ligand Receptor Agonist

Protease-activated receptor-2 is widely expressed in mammalian epithelial, immune and neural tissues. Cleavage of PAR2 by serine proteases leads to self-activation of the receptor by the tethered ligand SLIGRL. The contribution of other classes of proteases to PAR activation has not been studied in detail. Cathepsin S is a widely expressed cysteine protease that is upregulated in inflammatory conditions. It has been suggested that cathepsin S activates PAR2. However, cathepsin S activation of PAR2 has not been demonstrated directly nor has the potential mechanism of activation been identified. We show that cathepsin S cleaves near the N-terminus of PAR2 to expose a novel tethered ligand, KVDGTS. The hexapeptide KVDGTS generates downstream signaling events specific to PAR2 but is weaker than SLIGRL. Mutation of the cathepsin S cleavage site prevents receptor activation by the protease while KVDGTS retains activity. In conclusion, the range of actions previously ascribed to cysteine cathepsins in general, and cathepsin S in particular, should be expanded to include molecular signaling. Such signaling may link together observations that had been attributed previously to PAR2 or cathepsin S individually. These interactions may contribute to inflammation.

Plant cysteine proteases that evoke itch activate protease‐activated receptors

Background  Bromelain, ficin and papain are cysteine proteases from plants that produce itch upon injection into skin. Their mechanism of action has not been considered previously.

Dual action of neurokinin-1 antagonists on Mas-related GPCRs.

The challenge of translating findings from animal models to the clinic is well known. An example of this challenge is the striking effectiveness of neurokinin-1 receptor (NK-1R) antagonists in mouse models of inflammation coupled with their equally striking failure in clinical investigations in humans. Here, we provide an explanation for this dichotomy: Mas-related GPCRs (Mrgprs) mediate some aspects of inflammation that had been considered mediated by NK-1R. In support of this explanation, we show that conventional NK-1R antagonists have off-target activity on the mouse receptor MrgprB2 but not on the homologous human receptor MRGPRX2. An unrelated tripeptide NK-1R antagonist has dual activity on MRGPRX2. This tripeptide both suppresses itch in mice and inhibits degranulation from the LAD-2 human mast cell line elicited by basic secretagogue activation of MRGPRX2. Antagonists of Mrgprs may fill the void left by the failure of NK-1R antagonists.

Substance P activates Mas-related G protein–coupled receptors to induce itch

Background Substance P (SP) is linked to itch and inflammation through activation of receptors on mast cells and sensory neurons. There is increasing evidence that SP functions through Mas‐related G protein–coupled receptors (Mrgprs) in addition to its conventional receptor, neurokinin‐1. Objective Because Mrgprs mediate some aspects of inflammation that had been considered mediated by neurokinin‐1 receptor (NK‐1R), we sought to determine whether itch induced by SP can also be mediated by Mrgprs. Methods Genetic and pharmacologic approaches were used to evaluate the contribution of Mrgprs to SP‐induced scratching behavior and activation of cultured dorsal root ganglion neurons from mice. Results SP‐induced scratching behavior and activation of cultured dorsal root ganglion neurons was dependent on Mrgprs rather than NK‐1R. Conclusion We deduce that SP activates MrgprA1 on sensory neurons rather than NK‐1R to induce itch.

Functional Analysis of Recombinant Mutants of Maxadilan with a PAC1 Receptor-expressing Melanophore Cell Line

Maxadilan, a 61-amino-acid vasodilatory peptide, was initially isolated from the salivary glands of the sand fly Lutzomyia longipalpis. Although its primary sequence has no homology to that of pituitary adenylate cyclase-activating peptide, maxadilan is an agonist for the PAC1 receptor. A total of 58 substitution and deletion mutants was engineered in an effort to determine which residues were important for receptor activation. The mutants were characterized functionally using an assay based on pigment granule translocation in PAC1-expressing Xenopus laevis melanophores. Substitution of charged residues and proline 43 could alter (but not eliminate) the agonist activity of the mutants. In contrast, we found that several multiple substitution mutants of the predicted β-strand threonine residues became antagonists at the PAC1 receptor. The results suggest that these threonine residues are cooperatively involved in PAC1 activation.

Maxadilan, the PAC1 receptor, and leishmaniasis.

Maxadilan is a vasodilator peptide isolated from sand fly salivary glands. The vasodilator effects of maxadilan are mediated by the PAC1 receptor, although maxadilan and PACAP do not share sequence homology. Sand flies are the vector of the parasitic disease leishmaniasis. The peptide aids the sand fly in obtaining a blood meal while enhancing the infectivity of leishmania parasites transmitted by this arthropod vector. Aspects of maxadilan, PAC1, and leishmaniasis are discussed.