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Anti-parasitic effect of novel amidines against Trypanosoma cruzi: phenotypic and in silico absorption, distribution, metabolism, excretion and toxicity analysis

Published online by Cambridge University Press:  08 May 2017

ALINE SILVA DA GAMA NEFERTITI ,
MARCOS MEUSER BATISTA ,
PATRÍCIA BERNARDINO DA SILVA ,
EDUARDO CAIO TORRES-SANTOS ,
EDEZIO F. CUNHA-JÚNIOR ,
JULIUS GREEN ,
ARVIND KUMAR ,
ABDELBASSET A. FARAHAT ,
DAVID WILSON BOYKIN  and
MARIA DE NAZARE CORREIA SOEIRO
ALINE SILVA DA GAMA NEFERTITI
Affiliation:
Laboratório de Biologia Celular, Instituto Oswaldo Cruz, Fundação Oswaldo Cruz, Rio de Janeiro, Rio de Janeiro, Brazil
MARCOS MEUSER BATISTA
Affiliation:
Laboratório de Biologia Celular, Instituto Oswaldo Cruz, Fundação Oswaldo Cruz, Rio de Janeiro, Rio de Janeiro, Brazil
PATRÍCIA BERNARDINO DA SILVA
Affiliation:
Laboratório de Biologia Celular, Instituto Oswaldo Cruz, Fundação Oswaldo Cruz, Rio de Janeiro, Rio de Janeiro, Brazil
EDUARDO CAIO TORRES-SANTOS
Affiliation:
Laboratório de Bioquímica de Tripanosomatídeos, Instituto Oswaldo Cruz, Fundação Oswaldo Cruz, Rio de Janeiro, Rio de Janeiro, Brazil
EDEZIO F. CUNHA-JÚNIOR
Affiliation:
Laboratório de Bioquímica de Tripanosomatídeos, Instituto Oswaldo Cruz, Fundação Oswaldo Cruz, Rio de Janeiro, Rio de Janeiro, Brazil
JULIUS GREEN
Affiliation:
Department of Chemistry, Georgia State University, Atlanta, Georgia, USA
ARVIND KUMAR
Affiliation:
Department of Chemistry, Georgia State University, Atlanta, Georgia, USA
ABDELBASSET A. FARAHAT
Affiliation:
Department of Chemistry, Georgia State University, Atlanta, Georgia, USA Department of Pharmaceutical Organic Chemistry, Faculty of Pharmacy, Mansoura University, Mansoura 35516, Egypt
DAVID WILSON BOYKIN
Affiliation:
Department of Chemistry, Georgia State University, Atlanta, Georgia, USA
MARIA DE NAZARE CORREIA SOEIRO*
Affiliation:
Laboratório de Biologia Celular, Instituto Oswaldo Cruz, Fundação Oswaldo Cruz, Rio de Janeiro, Rio de Janeiro, Brazil
*
*Corresponding author: Laboratório de Biologia Celular, Instituto Oswaldo Cruz, Fundação Oswaldo Cruz, Av. Brasil, 4365 Manguinhos, Rio de Janeiro, Brazil. E-mail: [email protected]
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Summary

New more selective and potent drugs are urgently need to treat Chagas disease (CD). Among the many synthetic compounds evaluated against Trypanosoma cruzi, aromatic amidines (AAs) and especially arylimidamides (AIAs) have potent activity against this parasite. Presently, the effect of four mono-amidines (DB2228, DB2229, DB2292 and DB2294), four diamidines (DB2232, DB2235, DB2251 and DB2253) and one AIA (DB2255) was screened in vitro against different forms (bloodstream trypomastigotes – BT and intracellular forms) and strains from discrete typing unit (DTU) I and VI of T. cruzi and their cytotoxic profile on mammalian host cells. Except for DB2253, all molecules were as active as benznidazole (Bz), resulting in 50% of reduction in the number of alive BT, with EC50 ranging from 2·7 to 10·1 µm after 24 h of incubation. DB2255 was also the most potent against amastigotes (Tulahuen strain) showing similar activity to that of Bz (3 µm). In silico absorption, distribution, metabolism, excretion and toxicity analysis demonstrated probability of human intestinal adsorption, while mutagenicity and inhibition of hERG1 were not predicted, besides giving acceptable predicted volumes of distribution. Our findings contribute for better knowledge regarding the biological effect of this class of aromatic molecules against T. cruzi aiming to identify novel promising agent for CD therapy.

Keywords

aromatic amidinesChagas diseaseexperimental chemotherapytoxicityselectivityin silico ADMET analysis
Type
Research Article
Information
Parasitology Open , Volume 3 , 2017 , e5
Creative Commons
Creative Common License - CCCreative Common License - BYCreative Common License - NCCreative Common License - ND
This is an Open Access article, distributed under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives licence (http://creativecommons.org/licenses/by-nc-nd/4.0/), which permits non-commercial re-use, distribution, and reproduction in any medium, provided the original work is unaltered and is properly cited. The written permission of Cambridge University Press must be obtained for commercial re-use or in order to create a derivative work.
Copyright
Copyright © Cambridge University Press 2017

INTRODUCTION

Over 100 years ago, Carlos Chagas, a Brazilian researcher discovered a new disease, American trypanosimiasis or Chagas disease (CD) caused by a flagellated protozoan Trypanosoma cruzi. CD is endemic to 21 countries of Latin American, affecting more than 6 million individuals (WHO, 2016).

CD is currently emerging in non-endemic areas, such as North America, Europe and Oceania, mostly associated with the migration of infected carriers (Albajar-Viñas and Dias, Reference Albajar-Viñas and Dias2014). CD presents in two stages: an acute and a later chronic phase, which after years or decades about 30–40% of patients progress to symptomatic forms, causing heart disease and/or digestive and neurological disorders (Teixeira et al. Reference Teixeira, Nascimento and Sturm2006; Marin-Neto et al. Reference Marin-Neto, Rassi, Morillo, Avezum, Connolly, Sosa-Estani, Rosas, Yusuf and Benefit2008; Coura and Dias, Reference Coura and Dias2015). The two drugs currently available for clinical treatment are the nitroderivates, nifurtimox (Nif) and benznidazole (Bz), were introduced about four decades ago into clinical use and up to now remain the only treatment options (Patterson and Wyllie, Reference Patterson and Wyllie2014). The major limitations of these compounds include the need for long-time administration and their considerable side-effects that in some cases leads to the discontinuation of treatment, therapeutic failure at the later chronic phase and exhibition of limited effectiveness against naturally resistant strains (Wilkinson et al. Reference Wilkinson, Taylor, Horn, Kelly and Cheeseman2008). A novel candidate for CD therapy should present as drug characteristics: (i) efficacy upon the two phases of the disease, especially the later chronic stage; (ii) potency on different parasite discrete typing units (DTUs; I, II, V and VI) and forms relevant for human infection (trypomastigotes and amastigotes); (iii) low toxicity and absence of genotoxicity, mutagenicity and cardiotoxicity; (iv) be orally administrated; (v) with good stability (3–5 years in climatic zone) with (vi) low costs (Chatelain and Konar, Reference Chatelain and Konar2015; DNDi, 2016).

A recent clinical trial, which included a 5-year follow-up, seeking the benefits of the trypanocidal therapy using Bz in patients with established Chagas’ cardiomyopathy showed that although there was a significant reduction in total parasite load, this drug was not able to impair cardiac clinical deterioration (Morillo et al. Reference Morillo, Marin-Neto, Avezum, Sosa-Estani, Rassi, Rosas, Villena, Quiroz, Bonilla, Britto, Guhl, Velazquez, Bonilla, Meeks, Rao-Melacini, Pogue, Mattos, Lazdins, Rassi, Connolly, Yusuf and BENEFIT2015). These findings corroborate the need to find alternative therapies for CD. Aromatic amidines (AA) are dicationic molecules with many of them such as pentamidine (Pt) presenting DNA minor groove-binding characteristics (Soeiro et al. Reference Soeiro, Werbovetz, Boykin, Wilson, Wang and Hemphill2013). The anti-parasitic action of Pt has been known since 1937 (King et al. Reference King, Lourie and Yorke1937) and in the ensuing years many analogues and derivatives have been synthetized and screened against parasitic organisms. Several of these molecules have demonstrated a wide spectrum of activity against human and veterinary pathogens such as leishmaniasis, human African trypanosomes and T. cruzi (De Souza et al. Reference De Souza, Lansiaux, Bailly, Wilson, Hu, Boykin, Batista, Araújo-Jorge and Soeiro2004; Soeiro et al. Reference Soeiro, de Castro, de Souza, Batista, Silva and Boykin2008, Reference Soeiro, Werbovetz, Boykin, Wilson, Wang and Hemphill2013; De Araújo et al. Reference De Araújo, Da Silva, Batista, Da Silva, Meuser, Aiub, da Silva, Araújo-Lima, Banerjee, Farahat, Stephens, Kumar, Boykin and Soeiro2014). Among novel amidine molecules, the arylimidamides (AIAs) have shown very promising profiles and potent activity against intracellular parasites like Neospora caninum, Leishmania sp and T. cruzi (Soeiro et al. Reference Soeiro, Werbovetz, Boykin, Wilson, Wang and Hemphill2013). The present study investigates the anti-T. cruzi activity of additional novel amidines (four mono-amidines, four diamidines and one AIA) through phenotypic studies in vitro by assessing different forms and parasite strains besides determining their toxicity towards different host cell types (as L929 cell lines and primary cultures of cardiac cells) and their absorption, distribution, metabolism, excretion and toxicity (ADMET) properties from in silico predictions.

MATERIAL AND METHODS

Compounds

The synthesis of the four studied mono-amidines (2 – (5 – (4 – ((1 (quinolin - yl-1-1,2,3-triazol-4-yl) methoxy) phenyl) thiophen-2-yl)-1H-benzo[d]imidazole-6-carboximidamide hydrochloride (DB2228), 2-(5-(4-((1-(2-(naphthalen-1-yl) ethyl) – 1H-1,2,3–triazol-4-yl) methoxy) phenyl) thiophen-2-yl)-1H-benzo[d]imidazole–6-carboximidamide hydrochloride (DB2229), 2-(5–4-((1-(2-(2-(naphthalene–2-yloxy) ethoxy) ethyl)-1H-1,2,3-triazol-4-yl) methoxy) phenyl) thiophen- 2- yl-1H-benzo[d]imidazole – 6 - carboximidamide hydrochloride (DB2292) and 2-(5-(4-((1- (2-(2-(2-(naphthalene–2-yloxy) ethoxy) ethoxy) ethyl)-1H-1,2,3- triazol - 4-yl) methoxy) phenyl) thiophen-2-yl)-1H-benzo[d]imidazole–6-carboximidamide hydrochloride (DB2294)) has been previously described (Green, Reference Green2014). The synthetic route of the four diamidines (2,2′-((propane-1,3-diylbis (oxy)) bis (4,1-phenylene)) bis (1H-benzo[d]imidazole–6-carboximidamide) dihydrochloride (DB2232), 4,4′-(1-phenyl-1H-pyrrole-2,5-diyl) dibenzimidamide dihydrochloride (DB2235), 2,2′-((1-phenyl-1 H-pyrrole-2,5-diyl) bis (4,1-phenylene)) bis (4,5-dihydro-1H-imidazole) dihydrochloride (DB2251), 2,2′-((1-phenyl-1H-pyrrole-2,5-diyl) bis (4,1-phenylene)) bis (1, 4, 5, 6-tetrahydropyrimidine) dihydrochloride (DB2253)) was also conducted using a methodology previously reported (Ismail et al. Reference Ismail, Brun, Wenzler, Tanious, Wilson and Boykin2004; Farahat et al. Reference Farahat, Paliakov, Kumar, Barghash, Goda, Eisa, Wenzler, Brun, Liu, Wilson and Boykin2011). The synthesis of the bis-AIA N, N″-((2-oxoimidazolidine-1,3-diyl) bis (3–isopropoxy-4,1- phenylene)) dipicolinimidamide dihydrochloride (DB2255) was previously reported (Stephens et al. Reference Stephens, Tanious, Kim, Wilson, Schell, Perfect, Franzblau and Boykin2001) (Fig. 1). All compounds have been fully characterized by spectral methods (nuclear magnetic resonance [NMR] and mass spectrometry [MS]) and by satisfactory C, H, N analysis. Bz (2-nitroimidazole; Laboratório Farmacêutico do Estado de Pernambuco [LAFEPE], Brazil) was used as reference drug. Stock solutions were prepared in dimethyl sulfoxide (DMSO) with the final concentration of the solvent never exceeding 0·6% DMSO, which is not toxic to the parasite and mammalian cells.

Fig. 1. Chemical structure of the nine selected amidines assayed in this work.

Parasites

Bloodstream trypomastigote (BT) forms of the Y strain were obtained from the blood samples of infected albino Swiss mice at the peak of parasitaemia. The purified parasites were resuspended in Dulbecco's modified Eagle medium (DMEM) supplemented with 10% fetal bovine serum (FBS) as reported previously (Batista et al. Reference Batista, Batista, de Oliveira, do Amaral, Lannes-Vieira, Britto, Junqueira, Lima, Romanha, Sales Junior, Stephens, Boykin and Soeiro2010). Trypomastigotes of Tulahuen strain expressing the Escherichia coli β-galactosidase gene (Buckner et al. Reference Buckner, Verlinde, La Flamme and van Voorhis1996) were collected from the supernatant of infected cell cultures (L929 culture) as reported (Romanha et al. Reference Romanha, Castro, Soeiro, Lannes-Vieira, Ribeiro, Talvani, Bourdin, Blum, Olivieri, Zani, Spadafora, Chiari, Chatelain, Chaves, Calzada, Bustamante, Freitas-Junior, Romero, Bahia, Lotrowska, Soares, Andrade, Armstrong, Degrave and Andrade2010).

Cell cultures

For the toxicity assays on mammalian cells, primary cultures of cardiac cells were obtained from mice embryos plated onto coverslips in 96 well plates previously coated with 0·01% gelatin (Meirelles et al. Reference Meirelles, de Araujo-Jorge, Miranda, de Souza and Barbosa1986). L929 cell lineages were obtained as described and maintained in RPMI-1640 medium (pH 7·2–7·4) without phenol red (Gibco BRL) supplemented with 10% FBS and 2 mm glutamine (RPMI), as reported previously (Romanha et al. Reference Romanha, Castro, Soeiro, Lannes-Vieira, Ribeiro, Talvani, Bourdin, Blum, Olivieri, Zani, Spadafora, Chiari, Chatelain, Chaves, Calzada, Bustamante, Freitas-Junior, Romero, Bahia, Lotrowska, Soares, Andrade, Armstrong, Degrave and Andrade2010).

Cytotoxicity in vitro tests

The cardiac cells were incubated for 24 h at 37 °C with different concentrations of each compound diluted in RPMI and then, the morphology, cell density and spontaneous contractibility evaluated by light microscopy and their cellular viability determined by the Presto Blue test as reported (Timm et al. Reference Timm, da Silva, Batista, da Silva, da Silva, Tidwell, Patrick, Jones, Bakunov, Bakunova and Soeiro2014). L929 cell lineages incubated for 24 and 96 h at 37 °C, with different concentrations of each compound diluted in RPMI and their cellular viability determined by the AlamarBlue test as reported (Timm et al. Reference Timm, da Silva, Batista, da Silva, da Silva, Tidwell, Patrick, Jones, Bakunov, Bakunova and Soeiro2014). The maximum concentration of each compound was 96 µ m due to molecule precipitation. The results expressed by following the manufacturer instructions and the value of CC50 that corresponds to the concentration that reduces in 50% the cellular viability, determined. Selective index (SI) expressed by ratio between the values obtained for CC50 over the host cells and the EC50 obtained over the parasites.

Trypanocidal activity

Bloodstream trypomastigotes (BT) of the Y strain (DTU II) (Zingales et al. Reference Zingales, Andrade, Briones, Campbell, Chiari, Fernandes, Guhl, Lages-Silva, Macedo, Machado, Miles, Romanha, Sturm, Tibayrenc and Schijman2009) (5 × 106 per mL) were incubated for 2 and 24 h at 37 °C in RPMI in the presence or not of serial dilution of the compounds (up to 32 µ m). After compound incubation, the death parasite rates were determined by light microscopy through the direct quantification of the number of live parasites using a Neubauer chamber, and the EC50 concentration (the compound concentration that reduces in 50% the number of parasites) was calculated (Timm et al. Reference Timm, da Silva, Batista, da Silva, da Silva, Tidwell, Patrick, Jones, Bakunov, Bakunova and Soeiro2014). For the assay on intracellular forms, culture-derived trypomastigotes of T. cruzi (Tulahuen strain expressing β-galactosidase; DTU VI) (Zingales et al. Reference Zingales, Andrade, Briones, Campbell, Chiari, Fernandes, Guhl, Lages-Silva, Macedo, Machado, Miles, Romanha, Sturm, Tibayrenc and Schijman2009) used to infect L929 infected-cells cultures using a ratio of 10:1 (parasite: host cell). After 2 h, the cultures rinsed and further incubated for 48 h for establishment of the infection. Then, the compounds were added (initially using a fixed concentration of 10 µ m followed by other set of assays using increasing non-toxic concentrations to the mammalian host cell for determination of EC50 values) and the cultures maintained at 37 °C for 96 h. After addition of 50 µL of the substrate [(CPRG – chlorophenol red glycoside) 500 mm] in 0·5% Nonidet P40 and incubation at 37 °C for 18 h, the absorbance at 570 nm was measured, and the results expressed as per cent of parasite growth inhibition (Romanha et al. Reference Romanha, Castro, Soeiro, Lannes-Vieira, Ribeiro, Talvani, Bourdin, Blum, Olivieri, Zani, Spadafora, Chiari, Chatelain, Chaves, Calzada, Bustamante, Freitas-Junior, Romero, Bahia, Lotrowska, Soares, Andrade, Armstrong, Degrave and Andrade2010).

In all assays, at least three experiments (n ≤ 3) were done using ≤2 replicates.

Computational assessment of the drug-like properties of the tested compounds

ADMET properties of the studied amidines evaluated using the pkCSM approach, which uses graph-based signatures to develop predictive ADMET (Pires et al. Reference Pires, Blundell and Ascher2015).

Statistical analysis

Statistical analysis was performed using Student's t-test with significance set at p ≤ 0·05.

Ethics

All procedures were conducted in accordance with the guidelines established by the FIOCRUZ Committee of Ethics for the Use of Animals (CEUA LW16/14).

RESULTS

Initially, the biological assays were carried out to evaluate the activity of these molecules upon BT forms (Y strain – DTU II), and their respective toxicity towards cardiac cells. Our findings demonstrate that after a short period of incubation (2 h), six out of the nine drugs demonstrate trypanosomicidal activity against BT, exhibiting EC50 values lower than 20 µ m, while Bz was inactive (Table 1). DB2229 and DB2294 displayed an EC90 value <10 µ m after only 2 h of compound treatment (Table 1) presenting a fast activity towards these forms. After 24 h, seven molecules (DB2228, DB2229, DB2232, DB2235, DB2255, DB2292 and DB2294) were more potent (EC50 ≤ 8·3 µ m) than Bz (9·6 µ m), being DB2292 about 3-fold more active than the reference drug (Table 1). The toxicity profile assessed using cardiac cell cultures to exclude compounds and concentrations that presented cardiotoxic characteristics evaluated by morphological, contractility and density analysis besides through cellular viability approach using a colorimetric methodology (PrestoBlue). Only DB2235 and DB2251 presented detectable toxicity up to the studied concentrations (CC50 = 49 ± 21 and 62 ± 23 µ m, respectively) (Table 1).

Table 1. In vitro activity of the amidines and benznidazole on bloodstream trypomastigotes of the Y strain and on cardiac cells : EC50 and EC90 values after 2 and 24 h, CC50 values of CC after 24 h of incubation at 37 °C, respectively, and the corresponding selectivity index (SI)

a Based on EC50 24 h.

b Student's t-test statistical analysis of studied compound and Bz: (P < 0·05).

Next, further assays analysed the activity on intracellular forms of T. cruzi, using the Tulahuen strain transfected with β-galactosidase, as previous reported (Romanha et al. Reference Romanha, Castro, Soeiro, Lannes-Vieira, Ribeiro, Talvani, Bourdin, Blum, Olivieri, Zani, Spadafora, Chiari, Chatelain, Chaves, Calzada, Bustamante, Freitas-Junior, Romero, Bahia, Lotrowska, Soares, Andrade, Armstrong, Degrave and Andrade2010). The trypanocidal action after 96 h of incubation using a fixed concentration of 10 µ m showed that only the AIA DB2255 displayed a high inhibition of the parasite growth (88%), reaching similar activity to that of Bz (Table 2). Therefore, DB2255 was the only molecule selected for the next screening step, consisting of infection of L929 cells followed by incubation with non-toxic concentrations (up to 32 µ m). DB2255 and Bz presented similar potency (EC50 values of 3·6 ± 0·39 and 3 ± 1 µ m, respectively), but the reference drug exhibited higher selectivity (data not shown).

Table 2. Activity of the amidines and benznidazole on L929 cell lines infected with Trypanosoma cruzi (Tulahuen strain transfected with β-galactosidase) after 96 h of incubation with 10 µ m of each compound

Mathematic parameters of drug likeness including, absorption, distribution, metabolism, excretion and toxicity properties were calculated using the pkCSM approach that uses graph-based signatures to develop predictive of ADMET (Pires et al. Reference Pires, Blundell and Ascher2015). In silico ADMET analysis demonstrated probability of human intestinal adsorption (>90%), while mutagenicity and inhibition of hERG1 were not predicted, besides giving acceptable predicted volumes of distribution (Tables 3 and 4).

Table 3. In silico ADME

Table 4. In silico toxicity

DISCUSSION

In the last 40 years the only available treatment for CD has been two nitrohetocyclic agents, Bz and Nif, despite their severe side effects and low efficiency during the later chronic phase (Wilkinson and Kelly, Reference Wilkinson and Kelly2009; Don and Ioset, Reference Don and Ioset2013). The limitations of these therapies highlight the urgent need to find more effective and safer new compounds. Many compounds have been developed and screened with different experimental models of neglected diseases including CD (Bilbe, Reference Bilbe2015). The azole anti-fungal inhibitors posaconazole (Pos) and ravuconazole (Rav) that act on the sterol 14α-demethylase (CYP51) enzyme although were very potent in vitro and in vivo (using dog and mouse models) (Urbina et al. Reference Urbina, Payares, Contreras, Liendo, Sanoja, Molina, Piras, Piras, Perez, Wincker and Loebenberg1998; Diniz et al. Reference Diniz, Caldas, Guedes, Crepalde, de Lana, Carneiro, Talvani, Urbina and Bahia2010; Keenan and Chaplin, Reference Keenan and Chaplin2015) unfortunately failed during clinical trials performed by the Drugs for Neglected Diseases initiative (Molina et al. Reference Molina, Gómez, Salvador, Treviño, Sulleiro, Serre, Pou, Roure, Cabezos, Valerio, Blanco-Grau, Sánchez-Montalvá, Vidal and Pahissa2014). In addition, another recent clinical trial called ‘Benznidazole Evaluation for Interrupting Trypanosomiasis’ (BENEFIT) designed to evaluate the efficacy and safety of Bz compared with placebo, did not demonstrate protection by this drug against clinical outcomes among patients with chronic CD. Often, in drug development for CD, as well as for other pathologies, there is a lack of direct translation between pre-clinical in vitro and in vivo results and clinical outcomes. Experimental chemotherapy for CD presents serious challenges in part due to experimental difficulties related to reliable demonstration of a sterile cure, particularly during the chronic stage of infection when parasite burden is low and tissue distribution is not fully understood (Chatelain and Konar, Reference Chatelain and Konar2015; Francisco et al. Reference Francisco, Lewis, Jayawardhana, Taylor, Chatelain and Kelly2015).

Our group has studied the in vitro and in vivo activity of AA and analogues and the bulk of the data revealed very promising action of these cations against intracellular pathogens, including T. cruzi (Soeiro et al. Reference Soeiro, Werbovetz, Boykin, Wilson, Wang and Hemphill2013). Presently, nine aromatic compounds were evaluated by phenotypic and in silico studies. The mono-amidines (DB2228, DB2229, DB2292 and DB2294) with tethered aryl rings chosen due to previous observation that this class display potent effect against this parasite (Simões-Silva et al. Reference Simões-Silva, Nefertiti, De Araújo, Batista, Da Silva, Bahia, Menna-Barreto, Pavão, Green, Farahat, Kumar, Boykin and Soeiro2016). Three of the four diamidines (DB2235, DB2251 and DB2253) are analogues of furamidine and one (DB2232) is an extended bis-amidino benzimidazole, which represents another class of highly active diamidines. Lastly, one novel bis-AIA (DB2255) results from a simple modification of the structure of the highly active anti-T. cruzi compound DB766 (Batista et al. Reference Batista, Batista, de Oliveira, do Amaral, Lannes-Vieira, Britto, Junqueira, Lima, Romanha, Sales Junior, Stephens, Boykin and Soeiro2010). In DB2255, the central furan ring of DB766 replaced with a non-aromatic 5-membered imidazolidin-2-one ring.

Results of calculations using the pkCSM approach for estimation of ADMET and other drug-like properties are important to consider at an early stage in the drug discovery process (Pires et al. Reference Pires, Blundell and Ascher2015). The in silico estimation of ADMET properties showed that only DB2229, DB2235, DB2251 and DB2253 are likely to permeate Caco2 cells, with values near of the adopted threshold of 0·9. In addition, DB2228, DB2229, DB2251, DB2253, DB2255, DB2292 and DB2294 are predicted to show good adsorption (above 90%) by human intestines and reasonable predicted volume of distribution. Regarding the toxicity predictors, none expected to be mutagenic nor inhibitors of hERGI, whereas all compounds are expected to inhibit hERGII and have hepatotoxic profile as has also the reference drug, Bz.

Regarding the biological phenotypic assays, seven of out nine amidines presently screened against bloodstream forms resulted in parasite death rates similar to Bz including mono-amidines DB2228, DB2229, DB2292, DB2294, diamidines DB2232, DB2235 and AIA DB2255. Another important characteristic of some (DB2228, DB2229, DB2235, DB2292 and DB2294) was the ability to fast kill the parasite exhibiting anti-trypomastigote activity after 2 h of exposure while Bz was completely inactive at this time of drug exposure. When these aromatic compounds were tested against the intracellular amastigotes the bis-AIA DB2255 that was one of the best molecules against BT forms, also presented anti-parasitic effect in the same range as Bz, even using a different parasite strain and DTUs (Y and Tulahuen for BT and intracellular forms, corresponding to DTU II and VI, respectively). These data corroborate our previous findings that demonstrated the promising trypanocidal phenotypic effect of bis-AIAs (De Araujo et al. Reference De Araújo, Da Silva, Batista, Da Silva, Meuser, Aiub, da Silva, Araújo-Lima, Banerjee, Farahat, Stephens, Kumar, Boykin and Soeiro2014; Timm et al. Reference Timm, da Silva, Batista, da Silva, da Silva, Tidwell, Patrick, Jones, Bakunov, Bakunova and Soeiro2014). Data using trypomastigotes collected from infected cell lines reported EC50 values of 2·8 and 15·2 µ m for pentamidine exposure using Y and Dm28c strains, respectively (Díaz et al. Reference Díaz, Miranda, Campos-Estrada, Reigada, Maya, Pereira and López-Muñoz2014). However, DB2255 was less potent than other studied AIAs such as DB766 which gives EC50 values at <0·1 µ m (Batista et al. Reference Batista, Batista, de Oliveira, do Amaral, Lannes-Vieira, Britto, Junqueira, Lima, Romanha, Sales Junior, Stephens, Boykin and Soeiro2010). This result demonstrates that to achieve high anti-T. cruzi activity using the DB766 scaffold a central five membered hetero aromatic ring is required. In addition, is important to take into consideration that a hit compound for CD must be active against both parasite stages and upon the different DTUs in order to be given in the distinct endemic areas of this neglected disease (Chatelain, Reference Chatelain2015).

ACKNOWLEDGEMENTS

The authors acknowledge the Program for Technological Development in Tools for Health-PDTIS-FIOCRUZ for use of its facilities.

FINANCIAL SUPPORT

The present study was supported by grants from Fundação Carlos Chagas Filho de Amparo a Pesquisa do Estado do Rio de Janeiro (FAPERJ), Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) and Fundação Oswaldo Cruz, Instituto Oswaldo Cruz, PROEP/CNPq/Fiocruz. M.N.C.S. is a research fellow of CNPq and CNE research. This work was also supported, in part, by the National Institutes of Health USA Grant No. RO1AI64200 and by The Bill and Melinda Gates Foundation through a subcontract with the CPDD (to D.W.B.).

CONFLICT OF INTEREST

None.

References

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Figure 0

Fig. 1. Chemical structure of the nine selected amidines assayed in this work.

Figure 1

Table 1. In vitro activity of the amidines and benznidazole on bloodstream trypomastigotes of the Y strain and on cardiac cells : EC50 and EC90 values after 2 and 24 h, CC50 values of CC after 24 h of incubation at 37 °C, respectively, and the corresponding selectivity index (SI)

Figure 2

Table 2. Activity of the amidines and benznidazole on L929 cell lines infected with Trypanosoma cruzi (Tulahuen strain transfected with β-galactosidase) after 96 h of incubation with 10 µm of each compound

Figure 3

Table 3. In silico ADME

Figure 4

Table 4. In silico toxicity