Francesca Aiello

Quercetin and derivatives: useful tools in inflammation and pain management

Inflammation represents a very frequent condition in humans; it is often underestimated, making the problem an increasingly alarming phenomenon. For these reasons, conventional therapies are losing their effectiveness, leaving room for innovative therapies. In this field, natural products showed their efficacy in various diseases; and flavonoids, in particular quercetin, is known for its broad range of activities. In this review, we have highlighted its efficacy in various models of inflammation, focusing also on the activity of its semisynthetic derivatives, and those naturally present in plant extracts. Finally, the analgesic property of quercetin, intrinsically linked to its anti-inflammatory action, has been also evaluated, to investigate about an innovative approach to this interesting natural compound, such as analgesic remedial.

Synthesis and biological evaluation of novel hydrazide based cytotoxic agents

Recently, we designed and synthesized a series of pyrroloquinoxaline compounds with hydrazine moiety linking a nitrogen-containing polycyclic group to a heteroaroyl system. Several derivatives, with attractive drug-like properties, were identified as promising cytotoxic agents, showing excellent potency in a panel of cancer cell lines. In the current study, we synthesized a further 19 new analogues to optimize their physicochemical properties and assess a coherent mechanism of action. Several chemical modifications were made to the reference compounds by varying the fused-ring system and/or the heteroacyl moiety. To evaluate their in vitro activity, we tested these compounds in six human cancer cell lines derived from different origins. Among them, two compounds (Figure 1 and Figure 1) showed similar potency as the reference compounds with IC50 values in the sub-micromolar range in all cell lines tested. Furthermore, compound Figure 1 showed excellent in vivo efficacy in our preliminary human ovarian cancer mouse xenograft studies. Flow cytometric studies indicated that both derivatives interrupted cell cycle progression in colorectal cancer HCT116 cell lines and ovarian cancer SKOV-3 cells. Further mechanistic studies revealed that Figure 1 and Figure 1 were able to induce reactive oxygen species in SKOV-3 cells with apparently different kinetic patterns. Considering their cytotoxicity profiles in a variety of in vitro and in vivo cancer models, these hydrazide based compounds seem to have considerable potentials as novel chemotherapeutics.

Identification of two benzopyrroloxazines acting as selective GPER antagonists in breast cancer cells and cancer-associated fibroblasts

BACKGROUND G-protein coupled estrogen receptor (GPER) is involved in numerous intracellular physiological and pathological events including cancer cell migration and proliferation. Its characterization is yet incomplete due to the limited number of specific ligands. RESULTS Two novel selective GPER antagonists, based on a benzo[b]pyrrolo[1,2-d][1,4]oxazin-4-one structure, have been designed and synthesized. Their binding to the receptor was confirmed by a competition assay, while the antagonist effects were ascertained by their capability to prevent the ligand-stimulated action of GPER. The transcription mediated by the classical estrogen receptor was not influenced, demonstrating selectivity for GPER. CONCLUSION These novel compounds may be considered useful leads toward the dissection of the GPER signaling and the development of new pharmacological treatments in breast cancer.

Naphthoxazepine Inhibitors of HIV-1 Integrase: Synthesis and Biological Evaluation

Two sets of compounds derived from the fusion of a diversely annulated naphthoxazepinedione system with 1,3‐thiazole and 1,3‐oxazole are described. These compounds are close analogues of previously reported thiazolothiazepine inhibitors of human immunodeficiency virus type 1 integrase (HIV‐1 IN). Some of the new derivatives show potency similar to that of the reference compounds, thus gaining further insight into the structure–activity relationship of this class of IN inhibitors.

Multivariate least squares regression applied to the spectrophotometric analysis of manidipine and its main photoproduct

The simultaneous quantitative assay of 1,4-dihydropyridine calcium antagonist manidipine and its main photodegradation by-product has been defined by using a multivariate calibration on UV spectra based on a classical least squares regression. Optimization of the procedure was achieved by means of a calibration model using suitable wavelength ranges singled out from a fractionation scheme thereat defined. Recovery values of 99 and 96% for the drug and the by-product, respectively, were found either in appropriately prepared mixtures and commercial formulations. Quantification limit for the photoproduct concentration was estimated as 1.0% for the reference samples.

From Vegetable Waste to New Agents for Potential Health Applications: Antioxidant Properties and Effects of Extracts, Fractions and Pinocembrin from Glycyrrhiza glabra L. Aerial Parts on Viability of Five Human Cancer Cell Lines

Glycyrrhiza glabra cultivation and harvesting produces substantial quantities of aerial parts as waste. With the aim to prospect an innovative valorization of these byproducts, the aerial parts were harvested in May and October and analyzed for their chemical profile, antioxidant properties, and effects on viability of five cancer cell lines. Pinocembrin was the main constituent. A significant protection of lipid peroxidation was observed with the May total extract (IC50 of 4.2 ± 0.4 μg/mL at 30 min of incubation). The effects on viability of HeLa, MCF-7, MDA-MB-231, Caco-2, and PC3 human cancer cells were investigated. All samples shown a remarkable activity with IC50 values below 25 μg/mL. Samples from plants harvested in May exhibited greater activity than those harvested in October. MCF-7 and HeLa were the most sensitive cells with IC50 in the range 2.73-3.01 and 3.28-5.53 μg/mL, respectively. G. glabra aerial parts represent a good source of valuable products.

Discovery of a novel quinoxalinhydrazide with a broad-spectrum anticancer activity

Previously, we discovered a novel class of salicylhydrazide compounds with remarkable activity in hormone-dependent and -independent human cancer cells. We then designed and synthesized numerous analogues. Among these analogues, a quinoxalinhydrazide compound, SC144, exhibited desirable physicochemical and drug-like properties and therefore, was selected for further preclinical investigation. In the present study, we evaluated the in vitro activity of SC144 in a range of drug-sensitive and -resistant cancer cell lines as well as its in vivo efficacy in MDA-MB-435 and HT29 mice xenograft models. The broad-spectrum cytotoxicity of SC144 is especially highlighted by its potency in ovarian cancer cells resistant to cisplatin, breast-cancer cells resistant to doxorubicin, and colon cancer cells resistant to oxaliplatin. Furthermore, its activity was independent of p53, HER-2, estrogen and androgen receptor expressions. We also examined the effect of SC144 on cell cycle progression and apoptosis in select cell lines. Considering its cytotoxicity profile in a variety of in vitro and in vivo cancer models as well as its effects on cell cycle regulation and apoptosis, SC144 appears to represent a promising agent for further clinical development.

TRPV1–FAAH–COX: The Couples Game in Pain Treatment

Pain is a complex sensation involving the perception and transduction of diverse environmental pain stimuli with cognitive and emotional processing by the central nervous system. It can manifest as acute or chronic pain. Pain is controlled by a series of enzymes and receptors, implicated in a variety of interconnected mechanisms and pathways. In fact, several studies have shown the cannabinoid receptor 1 and the transient receptor potential vanilloid channel 1 to be new players in modulating the sophisticated pain transduction system at the central level. At the peripheral level, the perception of pain involves cyclooxygenases and fatty acid amide hydrolase, as recent studies demonstrate. This Minireview describes the physiological aspects of the receptors and enzymes mentioned above and focuses on the consideration of dual mechanisms as a new therapeutic approach in the treatment of pain.

Structure–affinity relationships and pharmacological characterization of new alkyl-resorcinol cannabinoid receptor ligands: Identification of a dual cannabinoid receptor/TRPA1 channel agonist

In our ongoing program aimed at deeply investigating the endocannabinoid system (ES), a set of new alkyl-resorcinol derivatives was prepared focusing on the nature and the importance of the carboxamide functionality. Binding studies on CB1 and CB2 receptors, monoacylglycerol lipase (MAGL) and fatty acid amide hydrolase (FAAH) showed that some of the newly developed compounds behaved as very potent cannabinoid receptor ligands (Ki in the nanomolar range) while, however, none of them was able to inhibit MAGL and/or FAAH. Derivative 11 was a potent CB1 and CB2 ligand, with Ki values similar to WIN 55,212, exhibiting a CB1 and CB2 agonist profile in vitro. In the formalin test of peripheral acute and inflammatory pain in mice, this compound showed a weak and delayed antinociceptive effect against the second phase of the nocifensive response, exhibiting, interestingly, a quite potent transient receptor potential ankyrin type-1 (TRPA1) channel agonist activity. Moreover, derivative 14, characterized by lower affinity but higher CB2 selectivity than 11, proved to behave as a weak CB2 competitive inverse agonist.

Discovery of Novel Anticancer Compounds Based on a Quinoxalinehydrazine Pharmacophore

Quinoxalinehydrazines represent a novel class of compounds with excellent potency in a panel of cancer cell lines. A prototype compound, SC144, showed significant in vivo efficacy in mice xenograft models of human breast cancer cells. The subsequent structure–activity relationship study resulted in the discovery of SC161 with better potency in cancer cell lines. Further exploring the possible conformational space by a 10 ns molecular dynamics simulation as presented herein, resulted in various pharmacophore orientations. The trajectory analysis indicated that in most of the simulation time, the molecule stays favorably in a compact planarlike orientation. We therefore built a pharmacophore model based on the cluster containing the highest number of frames to represent the most probable orientation. The model was used to screen a subset of our small molecule database containing 350,000 compounds. We selected 35 compounds for the initial cytotoxicity screen. Seventeen compounds belonging to oxadiazolopyrazine and quinoline class displayed cytotoxicity in various cancer cell lines. Five of them, compounds 2, 6, 15, 16, and 19, all bearing an oxadiazolopyrazine scaffold, showed IC50 values <3 μM in certain tumor cell lines. The most potent compound, 2, showed IC50 values <2 μM in HCT116 p53+/+, HCT116 p53−/−, and HEY cells, and 8 μM in NIH3T3 cells. This study shows that conformational sampling of a lead small molecule followed by representative pharmacophore model development is an efficient approach for the rational design of novel anticancer agents with similar or better potency than the original lead but with different physicochemical properties.