Structure- and ligand-based drug design approaches for neglected tropical diseases

Drug discovery has moved toward more rational strategies based on our increasing understanding of the fundamental principles of protein-ligand interactions. Structure( SBDD) and ligand-based drug design (LBDD) approaches bring together the most powerful concepts in modern chemistry and biology, linking medicinal chemistry with structural biology. The definition and assessment of both chemical and biological space have revitalized the importance of exploring the intrinsic complementary nature of experimental and computational methods in drug design. Major challenges in this field include the identification of promising hits and the development of high-quality leads for further development into clinical candidates. It becomes particularly important in the case of neglected tropical diseases (NTDs) that affect disproportionately poor people living in rural and remote regions worldwide, and for which there is an insufficient number of new chemical entities being evaluated owing to the lack of innovation and R&D investment by the pharmaceutical industry. This perspective paper outlines the utility and applications of SBDD and LBDD approaches for the identification and design of new small-molecule agents for NTDs.State of Sao Paulo Research Foundation (FAPESP)State of Sao Paulo Research Foundation (FAPESP)National Council for Scientific and Technological Development (CNPq), BrazilNational Council for Scientific and Technological Development (CNPq), Brazi

Modern drug discovery technologies: opportunities and challenges in lead discovery

The identification of promising hits and the generation of high quality leads are crucial steps in the early stages of drug discovery projects. The definition and assessment of both chemical and biological space have revitalized the screening process model and emphasized the importance of exploring the intrinsic complementary nature of classical and\ud modern methods in drug research. In this context, the widespread use of combinatorial chemistry and sophisticated screening methods for the discovery of lead compounds has created a large demand for small organic molecules that act on specific drug targets.\ud Modern drug discovery involves the employment of a wide variety of technologies and expertise in multidisciplinary research teams. The synergistic effects between experimental and computational approaches on the selection and optimization of bioactive compounds emphasize the importance of the integration of advanced technologies in drug discovery programs. These technologies (VS, HTS, SBDD, LBDD, QSAR, and so on) are complementary in the sense that they have mutual goals, thereby the combination of both empirical and in silico efforts is feasible at many different levels of lead optimization and new chemical entity (NCE) discovery. This paper provides a brief perspective on the evolution and use of key drug design technologies, highlighting opportunities and challenges

Prêmio Nobel de Química de 2012: a transdução celular de sinais por estímulos externos

O Prêmio Nobel de Química foi concedido para 162 cientistas entre 1901 e 2012. Jacobus Henricus van't Hoff foi o primeiro laureado, em 1901, e Frederick Sanger o único premiado duas vezes, em 1958 e 1980. O de 2012 foi atribuído aos pesquisadores americanos Robert J. Lefkowitz e Brian K. Kobilka por seus estudos sobre os receptores acoplados à proteína G (GPCRs, sigla em inglês para G-protein-coupled receptors). Estas fazem parte de uma superfamília de proteínas que estão acopladas a receptores celulares e, quando ativadas, interferem na transdução de sinais, resultando em processos de ativação de importantes eventos intracelulares por estímulos externos. Este artigo explica o que são os GPCRs, como eles atuam nas células e também a contribuição dos dois laureados para o avanço do conhecimento sobre esses receptores

In silico screening strategies for novel inhibitors of parasitic diseases

Introduction: Parasitic diseases are a major global problem causing long-term disability and death, with severe medical and psychological consequences around the world. Despite the prevalence of parasitic disease, the treatment options for many of these illnesses are still inadequate and there is a dire need for new antiparasitic drugs. In silico screening techniques, which are powerful strategies for hit generation, are widely being applied in the design of new ligands for parasitic diseases.\ud Areas covered: This article analyses the application of ligand- and structure-based virtual screening strategies against a variety of parasitic diseases and discusses the benefits of the integration between computational and experimental approaches toward the discovery of new antiparasitic agents. The analysis is illustrated by recent examples, with emphasis on the strategies reported within the past 2 years.\ud Expert opinion: Virtual screening techniques are powerful tools commonly used in drug discovery against parasitic diseases, which have provided new opportunities for the identification of several novel compound classes with antiparasitic activity

Neglected tropical diseases: a new era of challenges and opportunities

In an article recently published in Química Nova, entitled “Chemistry Without Borders” (“Química Sem Fronteiras”) [Pinto, A. C.; Zucco, C.; Galembeck, F.; Andrade, J. B.; Vieira, P. C. Quim. Nova 2012, 35, 2092], the authors highlighted the important aspects of science and technology with special emphasis on the field of Chemistry and its contributions toward a more prosperous Brazil of future. As a second step in that direction, this article extends the discussion of a key issue for the country in the framework of the chemistry community through the so called position papers in strategic areas. This document is a part of the contribution of the Brazilian Chemical Society to the World Science Forum to be held in Rio de Janeiro in November 2013. In this context, the present paper provides a brief discussion on neglected tropical diseases (NTDs) with emphasis on the current challenges and opportunities towards the development and evolution of the field. NTDs leads to illness, long-term disability or death, and has severe social, economic and psychological consequences for millions of men, women, and children worldwide. In most cases, the available treatments are inadequate and extremely limited in terms of efficacy and safety, leading to an urgent demand for new drugs. In addition to the traditional challenges involved in any drug discovery process, it is widely recognized that there is an innovation gap and a lack of investment for research and development (R&D) in the area of NTDs. In the last few decades, methods toward combating, eradication, prevention, and treatment of NTDs have been repeatedly emphasized in the major international agendas. Developments in these strategies and alliances have continued to have an essential impact, particularly in the area of drug discovery, both in Brazil and globally and should be encouraged and supported. Several examples of international activities dedicated to the reduction of the devastating global impact of NTDs can be provided. Despite the beneficial developments in the past 30 years, NTDs continue to devastate poor communities in remote and vulnerable areas, in large part, due to market failures and public policies. Recent studies have shown that among 756 new drugs approved between 2000 and 2011, only four new chemical entities (NCEs) were identified for the treatment of malaria, while none were developed against NTDs or tuberculosis. Furthermore, only 1.4% of approximately 150,000 clinical trials were registered for neglected diseases, with a smaller number of trials for NCEs. Establishment and strengthening of global strategies involving the triad “government–academia–industry” is fundamental to the success in R&D of new drugs for NTDs. National and international public–private initiatives that aim to create, encourage, and invest in R&D projects have been implemented and therefore are of utmost importance to successfully integrate Brazil into this new paradigm. It is essential to lay the foundation for mechanisms that will intensify investments in infrastructure, training, and qualification of personnel with an ultimate strategic vision that foresees continuity. Our research group has made significant contributions to the development of this field with the goal of forging new frontiers while tackling both current and future challenges that include indispensable elements such as innovation and integration.FAPESPCNPqCAPESWHODrugs for Neglected Diseases initiative (DNDi)Medicines for Malaria Venture (MMV

Structural insights into the molecular basis responsible for the effects of immobilization on the kinetic parameters of glyceraldehyde-3-phosphate dehydrogenase from Trypanosoma cruzi and human

O desenvolvimento de métodos rápidos e eficazes para a identificação de novas moléculas bioativas é fundamental para o processo de descoberta e planejamento de fármacos. A integração de um sistema de cromatografia liquida de alta eficiência (CLAE), com biorreatores como fase estacionária (IMER) é uma estratégia atrativa e versátil para a triagem de coleções de compostos visando à identificação de novos agentes terapêuticos. Os parâmetros cinéticos da enzima imobilizada gliceraldeído-3-fosfato desidrogenase (GAPDH) de Trypanosoma cruzi e humana foram determinados (T. cruzi: ‘K IND. M POT. G3P’ = 0.50 mmol ‘ L POT. -1’; ‘K IND. M POT. NAD+” = 0.67 mmol ‘L POT. -1’; humana: ‘K IND. M POT. G3P’ = 3.7 mmol ‘L POT. -1’; ‘K IND. M POT. NAD+’ = 0.75 mmol ‘L POT. -1’) e comparados com aqueles observados em solução (T. cruzi: ‘K IND. M POT. G3P’ = 0.42 mmol ‘L POT. -1’; ‘K IND. M POT. NAD+’ = 0.26 mmol ‘L POT. -1’; humana: ‘K IND. M POT. G3P’ = 0.16 mmol ‘L POT. -1’; ‘K IND. M POT. NAD+” = 0.18 mmol ‘L POT. -1’). Os resultados indicaram uma diminuição na afinidade das enzimas imobilizadas, entretanto, os elementos estruturais necessários para o processo de reconhecimento molecular e atividade biológica permaneceram inalterados, aumentando a estabilidade das enzimas. Além disso, a análise estrutural forneceu dados moleculares importantes envolvidos nos efeitos da imobilização sobre as interações entre ligante e receptor e, consequentemente, sobre a atividade enzimática e parâmetros cinéticosThe development of fast and reliable methods for the identification of new bioactive compounds is of utmost importance to boost the process of drug discovery and development. Immobilized enzyme reactors (IMERs), integrated with high performance liquid chromatography (HPLC), are attractive and versatile tools for screening collections consisting of natural products and synthetic small molecules. Standard kinetic parameters of the immobilized enzyme glyceraldehyde-3-phosphate dehydrogenase (GAPDH) from both Trypanosoma cruzi de and human have been determined (T. cruzi: ‘K IND. M POT. G3P’ = 0.50 mmol ‘L POT. -1’; ‘K IND. M POT. NAD+” = 0.67 mmol ‘L POT. -1’; humana: ‘K IND. M POT. G3P’ = 3.7 mmol ‘L POT. -1’; ‘K IND. M POT. NAD+” = 0.75 mmol ‘L POT. -1’), and comparisons of these values with those of the parasite and human free enzymes indicate a decrease in the affinity for the immobilized system (T. cruzi: ‘K IND. M POT. G3P’ = 0.42 mmol ‘L POT. -1’; ‘K IND. M POT. NAD+” = 0.26 mmol ‘L POT. -1’; humana: ‘K IND. M POT. G3P’ = 0.16 mmol ‘L POY. -1’; ‘K IND. M POT. NAD+” = 0.18 mmol ‘L POT. -1’). Interestingly, despite the kinetic differences between the two systems, the immobilized GAPDHs retained the required structural requirements for molecular recognition and biological activity, increasing the stability the enzyme. In the present work, we described an integrated structural analysis which has provided important insights into the molecular basis underlying the effects of immobilization on the ligand-receptor interactions and consequent enzymatic activity and kinetics parametersFAPESPCNP

Molecular features for antitrypanosomal activity of thiosemicarbazones revealed by OPS-PLS QSAR studies

A quantitative structure-activity relationship analysis was employed to explore the relationship between the molecular structure of thiosemicarbazone analogues and the inhibition of the cysteine protease cruzain, a validated target for Chagas’ disease treatment. A data set containing 53 thiosemicarbazone derivatives was used to produce a quantitative model for activity prediction of unknown compounds. Several electronic descriptors were obtained through DFT calculations, along with a large amount of Dragon descriptors. The ordered predictor selection (OPS) algorithm was employed to select the most relevant descriptors to perform PLS regressions. With this procedure, significant correlation coefficients ('r POT. 2' = 0.85, 'q POT. 2' = 0.78) were achieved. Furthermore, predicted values for an external test set are in good agreement with the experimental results, indicating the potential of the model for untested compounds. Additional validation tests were carried out, indicating that a robust and reliable model was obtained to be used in the design of new thiosemicarbazones with improved cruzain inhibition potential.FAPESPCAPESCNP

Inhibitor design for glyceraldehyde-3-phosphate dehydrogenase enzyme from Trypanosoma cruzi: structural biology and medicinal chemistry

A Doença de Chagas, causada pelo parasita Trypanosoma cruzi, atinge cerca de um quarto da população da América Latina. Os fármacos disponíveis para o tratamento desta doença são inapropriados, apresentam baixa eficácia e sérios efeitos colaterais que limitam o seu uso. Esse grave panorama torna urgente a descoberta de novos agentes quimioterápicos para o tratamento seguro e eficaz da doença. A via glicolítica é principal forma de obtenção de energia de tripanosomatídeos. Um alvo molecular atrativo desta via bioquímica que desempenha papel essencial no controle do fluxo glicolítico do Trypanosoma cruzi, a enzima gliceraldeído-3-fosfato desidrogenase (GAPDH), foi selecionada neste trabalho de Tese para estudos em biologia estrutural e química medicinal visando à identificação e planejamento de novos inibidores enzimáticos. Neste contexto, triagens biológicas resultaram na identificação de compostos de origem natural e sintética com atividade inibitória in vitro frente à GAPDH de T. cruzi, ampliando a diversidade química de moduladores seletivos deste alvo. Estudos cinéticos e estruturais demonstraram o comportamento não cooperativo entre os sítios ativos da enzima GAPDH de T. cruzi em relação à interação com o cofator NAD+, fornecendo importantes evidências mecanísticas e estruturais para uma melhor compreensão das bases moleculares envolvidas no processo de reconhecimento molecular. Os estudos das relações quantitativas entre a estrutura e atividade (QSAR 2D e QSAR 3D) resultaram na geração de modelos com elevada consistência estatística interna e externa, além de alto poder preditivo da propriedade-alvo. Além disso, estudos de modelagem molecular e de QSAR 3D revelaram aspectos estruturais relevantes para o planejamento de inibidores seletivos da enzima GAPDH de tripanosomatídeos. Por fim, uma estratégia de triagem virtual baseado na estrutura do receptor foi empregada para a identificação de novos inibidores da GAPDH de T. cruzi, consistindo, entre outros, na aplicação de filtros hierárquicos sucessivos envolvendo restrições farmacofóricas e estudos de docagem molecular que resultaram na seleção de 35 candidatos a inibidores da enzima-alvo. Os trabalhos integrando estudos em química medicinal e biologia estrutural apresentados nessa Tese de Doutorado significam importantes contribuições no desenvolvimento de bases científicas sólidas para o planejamento de novos inibidores potentes e seletivos da enzima GAPDH de T. cruzi, um alvo molecular de alta prioridade em nosso grupo de pesquisa.Parasitic diseases are the foremost threat to human health and welfare around the world. Chagas\' disease (also called American trypanosomiasis) is a tropical parasitic disease which occurs in Latin America, particularly in South America. The currently available drugs for this parasitic disease have severe limitations, including poor efficacy and high toxicity. The crucial dependence of trypanosomatids on glycolysis as a source of energy makes the glycolytic enzymes promising targets for drug design. Glyceraldehyde-3-phosphate dehydrogenase (GAPDH) from Trypanosoma cruzi, a key enzyme in the glycolytic cascade, has been selected as an attractive drug target in this PhD Thesis work for studies in structural biology and medicinal chemistry for the identification and design of new enzyme inhibitors. In this context, compounds from both natural and synthetic sources with in vitro inhibitory activity against T. cruzi GAPDH were identified by screening assays, improving the chemical diversity of selective modulators of the target. Kinetic and structural studies have demonstrated the non-cooperative behavior between the T. cruzi active sites in the interaction with the NAD+ cofactor, shedding some light on the mechanistic and structural determinants underlying the biochemical recognition phenomenon. Quantitative structure-activity relationships (2D QSAR 2D and 3D QSAR) were successfully created, resulting in statistically significant models with good predictive ability for untested compounds. In addition, molecular modeling and 3D QSAR studies highlighted important structural aspects to assist the design of novel trypanosomatid GAPDH inhibitors. Finally, a structure-based virtual screening approach was employed for the identification of novel inhibitors of T. cruzi GAPDH, consisting of several consecutive hierarchical, fast pharmacophore matching and molecular docking, which afforded 35 inhibitor candidates for the target enzyme. The integration of structural biology and medicinal chemistry studies presented in this PhD Thesis are important contributions in the development of strong scientific basis for the design of new selective and potent inhibitors of GAPDH from T. cruzi, a molecular target of highest priority in our research group

A pharmacophore-based virtual screening approach for the discovery of Trypanosoma cruzi GAPDH inhibitors

Background: Chagas disease is a major cause of morbidity and death for millions of people in Latin America. The drugs currently available exhibit poor efficacy and severe side effects. Therefore, there is an urgent need for new, safe and effective drugs against Chagas disease. The vital dependence on glycolysis as energy source makes the glycolytic enzymes of Trypanosoma cruzi, the causative agent of Chagas disease, attractive targets for drug design. In this work, glyceraldehyde-3-phosphate dehydrogenase from T. cruzi (TcGAPDH) was employed as molecular target for the discovery of new inhibitors as hits. Results: Integrated protein-based pharmacophore and structure-based virtual screening approaches resulted in the identification of three hits from three chemical classes with moderate inhibitory activity against TcGAPDH. The inhibitors showed IC50 values in the high micromolar range. Conclusion: The new chemotypes are attractive molecules for future medicinal chemistry efforts aimed at developing new lead compounds for Chagas disease.FAPESP (13/07600-3)CNP

Classical and hologram QSAR studies on a series of inhibitors of trypanosomatid Glyceraldehyde-3-Phosphate Dehydrogenase

Leishmaniasis and trypanosomiasis are major causes of morbidity and mortality in both tropical and subtropical regions of the world. The current available drugs are limited, ineffective, and require long treatment regimens. Due to the high dependence of trypanosomatids on glycolysis as a source of energy, some glycolytic enzymes have been identified as attractive targets for drug design. In the present work, classical Two-Dimensional Quantitative Structure -Activity Relationships (2D QSAR) and Hologram QSAR (HQSAR) studies were performed on a series of adenosine derivatives as inhibitors of Leishmania mexicana Glyceraldehyde-3-Phosphate Dehydrogenase (LmGAPDH). Significant correlation coefficients (classical QSAR, r(2)=0.83 and q(2) =0.81; HQSAR, r(2)=0.91 and q(2) =0.86) were obtained for the 56 training set compounds, indicating the potential of the models for untested compounds. The models were then externally validated using a test set of 14 structurally related compounds and the predicted values were in good agreement with the experimental results (classical QSAR, r(pred)(2) = 0.94; HQSAR, r(pred)(2) = 0.92)