Design and synthesis of capsaicin analogues and evaluation of antitumor activity.

O número de casos de câncer tem aumentado significativamente em todo o mundo, principalmente a partir do século passado. Dessa forma, a busca por novas moléculas capazes de combater esta doença é cada vez maior, visto que muitos fármacos utilizados na terapêutica mostram-se tóxicos e pouco seletivos para células tumorais, causando efeitos adversos que muitas vezes alteram a qualidade de vida do paciente drasticamente. Muitos fármacos antineoplásicos tiveram sua origem relacionada aos produtos naturais. A capsaicina é o principal componente pungente das pimentas vermelhas do gênero Capsicum, e seu efeito antitumoral é extensivamente discutido devido a sua capacidade de induzir apoptose seletivamente em diferentes linhagens de células cancerígenas. Este trabalho teve como objetivo utilizar a estratégia de modificação molecular para o planejamento racional de análogos funcionais da capsaicina, visando à obtenção de moléculas com atividade citotóxica superior. Os análogos foram sintetizados utilizando reações de uma única etapa baseadas em metodologias clássicas de acilação e caracterizados através de metodologias analíticas como espectroscopia de RMN de 1H e 13C, análise elementar e ponto de fusão. Posteriormente, foram avaliadas as atividades biológicas contra quatro linhagens tumorais (PC3, MACL-1, H1299, U138MG) e fibroblastos (3T3), utilizando o método de redução do MTT 3-(4,5-dimetil-tiazol-2-il)-2,5-difeniltetrazólio. Três compostos (RPF306, 452 e 404) inibiram seletivamente o crescimento celular na faixa de concentração de micromolar (µM). Estudos teóricos adicionais revelaram que propriedades topológicas e eletrônicas influenciaram na discriminação de amostras e podem ser importantes no processo de reconhecimento molecular e, subsequentemente, na resposta biológica. Tais resultados indicam que amidas e ésteres aromáticos, como o RPF306 e 404 podem ser modelos interessantes para o planejamento de novas séries de moléculas seletivas e pouco tóxicas, que representem uma alternativa interessante no tratamento do câncer.Over the past century, the number of cancer cases has increased significantly worldwide. Therefore, the quest for discovery of new molecules able to treat the disease is increasing, since many drugs used in therapy are poorly selective and toxic to normal cells, causing adverse effects that often change dramatically the patient\'s quality of life. Many chemotherapeutic agents had its origin related to natural products. Capsaicin is the main component of pungent red peppers of the genus Capsicum, and its antitumor effect is extensively discussed, due to its ability to selectively induce apoptosis in several cancer cell lines. In this context, our research aims to use the strategy of molecular modification to the rational design of capsaicin functional analogues, in order to obtain molecules with superior cytotoxic activity. The analogues were synthesized using an one-step reaction, based on classical acylation methods and characterized by analytical methods such as 1H and 13C NMR spectroscopy, elemental analysis and melting point. Subsequently, their cytotoxicity were evaluated against four human cancer cell lines (PC3, MACL-1, H1299 and U138MG) and fibroblast (3T3) using the MTT - 3-(4,5 dimethyl thiazole-2-yl)-2,5 diphenyltetrazolium assay. Three compounds (RPF306, 452 and 404) selectively inhibited the growth of cancer cell lines at micromolar (µM) range. In silico studies revealed that topological and electronic properties mostly influenced the samples discrimination and also might be important for the molecular recognition process and, subsequently, biological response or function. The results indicate that aryl amides and esters, such as RPF306 and 404 might be interesting scaffolds to develop a novel series of compounds with higher selective and low toxicity that could represent an alternative in the treatment of cancer

Bicyclic-Capped Histone Deacetylase 6 Inhibitors with Improved Activity in a Model of Axonal Charcot-Marie-Tooth Disease

Charcot-Marie-Tooth (CMT) disease is a disorder of the peripheral nervous system where progressive degeneration of motor and sensory nerves leads to motor problems and sensory loss and for which no pharmacological treatment is available. Recently, it has been shown in a model for the axonal form of CMT that histone deacetylase 6 (HDAC6) can serve as a target for the development of a pharmacological therapy. Therefore, we aimed at developing new selective and activity-specific HDAC6 inhibitors with improved biochemical properties. By utilizing a bicyclic cap as the structural scaffold from which to build upon, we developed several analogues that showed improved potency compared to tubastatin A while maintaining excellent selectivity compared to HDAC1. Further screening in N2a cells examining both the acetylation of α-tubulin and histones narrowed down the library of compounds to three potent and selective HDAC6 inhibitors. In mutant HSPB1-expressing DRG neurons, serving as an in vitro model for CMT2, these inhibitors were able to restore the mitochondrial axonal transport deficits. Combining structure-based development of HDAC6 inhibitors, screening in N2a cells and in a neuronal model for CMT2F, and preliminary ADMET and pharmacokinetic profiles, resulted in the selection of compound 23d that possesses improved biochemical, functional, and druglike properties compared to tubastatin A.status: publishe

Bicyclic-Capped Histone Deacetylase 6 Inhibitors with Improved Activity in a Model of Axonal Charcot–Marie–Tooth Disease

Charcot–Marie–Tooth (CMT) disease is a disorder of the peripheral nervous system where progressive degeneration of motor and sensory nerves leads to motor problems and sensory loss and for which no pharmacological treatment is available. Recently, it has been shown in a model for the axonal form of CMT that histone deacetylase 6 (HDAC6) can serve as a target for the development of a pharmacological therapy. Therefore, we aimed at developing new selective and activity-specific HDAC6 inhibitors with improved biochemical properties. By utilizing a bicyclic cap as the structural scaffold from which to build upon, we developed several analogues that showed improved potency compared to tubastatin A while maintaining excellent selectivity compared to HDAC1. Further screening in N2a cells examining both the acetylation of α-tubulin and histones narrowed down the library of compounds to three potent and selective HDAC6 inhibitors. In mutant HSPB1-expressing DRG neurons, serving as an in vitro model for CMT2, these inhibitors were able to restore the mitochondrial axonal transport deficits. Combining structure-based development of HDAC6 inhibitors, screening in N2a cells and in a neuronal model for CMT2F, and preliminary ADMET and pharmacokinetic profiles, resulted in the selection of compound <b>23d</b> that possesses improved biochemical, functional, and druglike properties compared to tubastatin A

Dillapiole as Antileishmanial Agent: Discovery, Cytotoxic Activity and Preliminary SAR Studies of Dillapiole Analogues

In this paper, the isolation of dillapiole (1) from Piper aduncum was reported as well as the semi-synthesis of two phenylpropanoid derivatives [di-hydrodillapiole (2), isodillapiole (3)], via reduction and isomerization reactions. Also, the compounds' molecular properties (structural, electronic, hydrophobic, and steric) were calculated and investigated to establish some preliminary structureactivity relationships (SAR). Compounds were evaluated for in vitro antileishmanial activity and cytotoxic effects on fibroblast cells. Compound 1 presented inhibitory activity against Leishmania amazonensis (IC50?=?69.3 mu M) and Leishmania brasiliensis (IC50?=?59.4 mu M) and induced cytotoxic effects on fibroblast cells mainly in high concentrations. Compounds 2 (IC50?=?99.9 mu M for L. amazonensis and IC50?=?90.5 mu M for L. braziliensis) and 3 (IC50?=?122.9 mu M for L. amazonensis and IC50?=?109.8 mu M for L. brasiliensis) were less active than dillapiole (1). Regarding the molecular properties, the conformational arrangement of the side chain, electronic features, and the hydrophilic/hydrophobic balance seem to be relevant for explaining the antileishmanial activity of dillapiole and its analogues.MackpesquisaMackpesquis