Giovanni Appendino

The Molecular Receptive Ranges of Human TAS2R Bitter Taste Receptors

Humans perceive thousands of compounds as bitter. In sharp contrast, only approximately 25 taste 2 receptors (TAS2R) bitter taste receptors have been identified, raising the question as to how the vast array of bitter compounds can be detected by such a limited number of sensors. To address this issue, we have challenged 25 human taste 2 receptors (hTAS2Rs) with 104 natural or synthetic bitter chemicals in a heterologous expression system. Thirteen cognate bitter compounds for 5 orphan receptors and 64 new compounds for previously identified receptors were discovered. Whereas some receptors recognized only few agonists, others displayed moderate or extreme tuning broadness. Thus, 3 hTAS2Rs together were able to detect approximately 50% of the substances used. Conversely, though 63 bitter substances activated only 1-3 receptors, 19 compounds stimulated up to 15 hTAS2Rs. Our data suggest that the detection of the numerous bitter chemicals is related to the molecular receptive ranges of hTAS2Rs.

Pharmacology of Vanilloid Transient Receptor Potential Cation Channels

Depending on their primary structure, the 28 mammalian transient receptor potential (TRP) cation channels identified so far can be sorted into 6 subfamilies: TRPC (“Canonical”), TRPV (“Vanilloid”), TRPM (“Melastatin”), TRPP (“Polycystin”), TRPML (“Mucolipin”), and TRPA (“Ankyrin”). The TRPV subfamily (vanilloid receptors) comprises channels critically involved in nociception and thermosensing (TRPV1, TRPV2, TRPV3, and TRPV4), whereas TRPV5 and TRPV6 are involved in renal Ca2+ absorption/reabsorption. Apart from TRPV1, the pharmacology of these channels is still insufficiently known. Furthermore, only few small-molecule ligands for non-TRPV1 vanilloid receptors have been identified, and little is known of their endogenous ligands, resulting in a substantial “orphan” state for these channels. In this review, we summarize the pharmacological properties of members of the TRPV subfamily, highlighting the critical issues and challenges facing their “deorphanization” and clinical exploitation.

Antibacterial Cannabinoids from Cannabis sativa: A Structure−Activity Study

Marijuana (Cannabis sativa) has long been known to contain antibacterial cannabinoids, whose potential to address antibiotic resistance has not yet been investigated. All five major cannabinoids (cannabidiol (1b), cannabichromene (2), cannabigerol (3b), Delta (9)-tetrahydrocannabinol (4b), and cannabinol (5)) showed potent activity against a variety of methicillin-resistant Staphylococcus aureus (MRSA) strains of current clinical relevance. Activity was remarkably tolerant to the nature of the prenyl moiety, to its relative position compared to the n-pentyl moiety (abnormal cannabinoids), and to carboxylation of the resorcinyl moiety (pre-cannabinoids). Conversely, methylation and acetylation of the phenolic hydroxyls, esterification of the carboxylic group of pre-cannabinoids, and introduction of a second prenyl moiety were all detrimental for antibacterial activity. Taken together, these observations suggest that the prenyl moiety of cannabinoids serves mainly as a modulator of lipid affinity for the olivetol core, a per se poorly active antibacterial pharmacophore, while their high potency definitely suggests a specific, but yet elusive, mechanism of activity.

Comparative Absorption of a Standardized Curcuminoid Mixture and Its Lecithin Formulation

The relative absorption of a standardized curcuminoid mixture and its corresponding lecithin formulation (Meriva) was investigated in a randomized, double-blind, crossover human study. Clinically validated dosages were used for both products, and plasma levels of all three major curcuminoids [curcumin (1a), demethoxycurcumin (1b), and bisdemethoxycurcumin (1c)] were evaluated. Total curcuminoid absorption was about 29-fold higher for Meriva than for its corresponding unformulated curcuminoid mixture, but only phase-2 metabolites could be detected, and plasma concentrations were still significantly lower than those required for the inhibition of most anti-inflammatory targets of curcumin. Remarkably, phospholipid formulation increased the absorption of demethoxylated curcuminoids much more than that of curcumin (1a), with significant differences in plasma curcuminoid profile between Meriva and its corresponding unformulated curcuminoid mixture. Thus, the major plasma curcuminoid after administration of Meriva was not curcumin (1a), but demethoxycurcumin (1b), a more potent analogue in many in vitro anti-inflammatory assays. The improved absorption, and possibly also a better plasma curcuminoid profile, might underlie the clinical efficacy of Meriva at doses significantly lower than unformulated curcuminoid mixtures.

Euphorbium: Modern research on its active principle, resiniferatoxin, revives an ancient medicine

Resiniferatoxin, an ultrapotent capsaicin analog present in the latex of Euphorbia resinifera, interacts at a specific membrane recognition site (referred to as the vanilloid receptor), expressed by primary sensory neurons mediating pain perception as well as neurogenic inflammation. Desensitization to resiniferatoxin is a promising approach to mitigate neuropathic pain and other pathological conditions in which sensory neuropeptides released from capsaicin-sensitive neurons play a crucial role. Clinical trials to evaluate the potential of topical resiniferatoxin treatment to relieve pain associated with diabetic polyneuropathy and postherpetic neuralgia are in progress. Though resiniferatoxin was isolated only two decades ago, the dried latex of Euphorbia resinifera, called Euphorbium, has been in medicinal use since the time of recorded history. This review highlights the most important events in the history of this ancient medicine, from the first written record of the therapeutic potential of Euphorbium (at the time of the reign of the Roman Emperor Augustus) to the identification of its active principle as resiniferatoxin in 1975. A brief overview of the enormous contribution of resiniferatoxin to our current understanding of the anatomical localization, function, and pharmacology of vanilloid receptors is provided. Lastly, the mechanisms are summarized by which capsaicin and resiniferatoxin, despite sharing receptors, may have dissimilar biological actions.

Plant volatiles: Production, function and pharmacology

Plant volatiles typically occur as a complex mixture of low-molecular weight lipophilic compounds derived from different biosynthetic pathways, and are seemingly produced as part of a defense strategy against biotic and abiotic stress, as well as contributing to various physiological functions of the producer organism. The biochemistry and molecular biology of plant volatiles is complex, and involves the interplay of several biochemical pathways and hundreds of genes. All plants are able to store and emit volatile organic compounds (VOCs), but the process shows remarkable genotypic variation and phenotypic plasticity. From a physiological standpoint, plant volatiles are involved in three critical processes, namely plant–plant interaction, the signaling between symbiotic organisms, and the attraction of pollinating insects. Their role in these ‘‘housekeeping’’ activities underlies agricultural applications that range from the search for sustainable methods for pest control to the production of flavors and fragrances. On the other hand, there is also growing evidence that VOCs are endowed with a range of biological activities in mammals, and that they represent a substantially under-exploited and still largely untapped source of novel drugs and drug leads. This review summarizes recent major developments in the study of biosynthesis, ecological functions and medicinal applications of plant VOCs.

Noladin ether, a putative novel endocannabinoid: inactivation mechanisms and a sensitive method for its quantification in rat tissues

The occurrence of the novel proposed endocannabinoid, noladin ether (2‐arachidonyl glyceryl ether, 2‐AGE) in various rat organs and brain regions, and its inactivation by intact C6 glioma cells, were studied. 2‐AGE was measured by isotope dilution liquid chromatography‐atmospheric pressure chemical ionization‐mass spectrometry, with a detection limit of 100 fmol. A compound with the same mass and chromatographic/chemical properties as 2‐AGE was found in whole brain, with the highest amounts in the thalamus and hippocampus. Synthetic [3H]2‐AGE was inactivated by intact rat C6 glioma cells by a time‐ and temperature‐dependent process consisting of cellular uptake and partial incorporation into phospholipids. Further data suggested that 2‐AGE is taken up by cells via the anandamide/2‐arachidonoyl glycerol (2‐AG) membrane transporter(s), and biosynthesized in a different way as compared to 2‐AG.

An NMR Spectroscopic Method to Identify and Classify Thiol‐Trapping Agents: Revival of Michael Acceptors for Drug Discovery?

Although Michael acceptors are traditionally shunned in modern drug discovery, trapping of thiols by covalent coupling represents an important mechanism of bioactivity, and many biologically relevant and druggable pathways are targeted by thiol-reactive compounds. Research on Michael acceptors, long confined to the realm of toxicology, was rekindled by the development of the antioxidant inflammation modulator (AIM) homo-triterpenoid bardoxolone methyl (RTA402, 1). This orally bioavailable biological

Functional characterization of transient receptor potential channels in mouse urothelial cells.

The bladder urothelium is currently believed to be a sensory structure, contributing to mechano- and chemosensation in the bladder. Transient receptor potential (TRP) cation channels act as polymodal sensors and may underlie some of the receptive properties of urothelial cells. However, the exact TRP channel expression profile of urothelial cells is unclear. In this study, we have performed a systematic analysis of the molecular and functional expression of various TRP channels in mouse urothelium. Urothelial cells from control and trpv4-/- mice were isolated, cultured (12-48 h), and used for quantitative real-time PCR, immunocytochemistry, calcium imaging, and whole cell patch-clamp experiments. At the mRNA level, TRPV4, TRPV2, and TRPM7 were the most abundantly expressed TRP genes. Immunohistochemistry showed a clear expression of TRPV4 in the plasma membrane, whereas TRPV2 was more prominent in the cytoplasm. TRPM7 was detected in the plasma membrane as well as cytoplasmic vesicles. Calcium imaging and patch-clamp experiments using TRP channel agonists and antagonists provided evidence for the functional expression of TRPV4, TRPV2, and TRPM7 but not of TRPA1, TRPV1, and TRPM8. In conclusion, we have demonstrated functional expression of TRPV4, TRPV2, and TRPM7 in mouse urothelial cells. These channels may contribute to the (mechano)sensory function of the urothelial layer and represent potential targets for the treatment of bladder dysfunction.

Immunosuppressive activity of capsaicinoids: capsiate derived from sweet peppers inhibits NF-κB activation and is a potent antiinflammatory compound in vivo

Capsiate and its dihydroderivatives are the major capsaicinoids of sweet pepper. These new capsaicinoids do not activate the vanilloid receptor type 1 (VR1) but they share with capsaicin (CPS)some biological activities mediated in a VR1‐independent fashion. In this study we show that CPS and nordihydrocapsiate (CPT) inhibit early and late events in T cell activation, including CD69, CD25 and ICAM‐1 cell surface expression, progression to the S phase of the cell cycle and proliferation in response to TCR and CD28 co‐engagement. Moreover, both CPS and CPT inhibit NF‐κB activation in response to different agents including TNF‐α. CPS itself does not affect the DNA‐binding ability of NF‐κB but it prevents IκB kinase activation and IκBα degradation in a dose‐dependent manner, without inhibiting the activation of the mitogen‐activated protein kinases, p38, extracellular regulated kinase and c‐Jun N‐terminal protein kinase. Moreover, intraperitoneal pretreatment with CPT prevented mice from lethal septic shock induced by lipopolysaccharide. In a second model of inflammation CPT pretreatment greatly reduced the extensive damage in the glandular epithelium observed in the bowel of DSS‐treated mice. Taken together, these results suggest that CPT and related synthetic analogues target specific pathways involved in inflammation, and hold considerable potential for dietary health benefits as well as for pharmaceutical development.