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Rapid test for the evaluation of the activity of the prodrug hydroxymethylnitrofurazone in the processing of Trypanosoma cruzi messenger RNAs

Abstract

No fully effective treatment has been developed since the discovery of Chagas' disease by Carlos Chagas in 1909. Since drug-resistant Trypanosoma cruzi strains are occurring and the current therapy is effectiveness in the acute phase but with various adverse side effects, more studies are needed to characterize the susceptibility of T. cruzi to new drugs. Many natural and/or synthetic substances showing trypanocidal activity have been used, even though they are not likely to be turned into clinically approved drugs. Originally, drug screening was performed using natural products, with only limited knowledge of the molecular mechanism involved in the development of diseases. Trans-splicing, which is unusual RNA processing reaction and occurs in nematodes and trypanosomes, implies the processing of polycistronic transcription units into individual mRNAs; a short transcript spliced leader (SL RNA) is trans-spliced to the acceptor pre-mRNA, giving origin to the mature mRNA. In the present study, permeable cells of T. cruzi epimastigote forms (Y, BOL and NCS strains) were treated to evaluate the interference of two drugs (hydroxymethylnitrofurazone - NFOH-121 and nitrofurazone) in the trans-splicing reaction using silver-stained PAGE analysis. Both drugs induced a significant reduction in RNA processing at concentrations from 5 to 12.5 µM. These data agreed with the biological findings, since the number of parasites decreased, especially with NFOH-121. This proposed methodology allows a rapid and cost-effective screening strategy for detecting drug interference in the trans-splicing mechanism of T. cruzi.

Trypanosoma cruzi; Trans-splicing; Trypanocidal drugs; Permeable cells; RNA processing; Hydroxymethylnitrofurazone


Braz J Med Biol Res, January 2007, Volume 40(1) 33-39

Rapid test for the evaluation of the activity of the prodrug hydroxymethylnitrofurazone in the processing of Trypanosoma cruzi messenger RNAs

C.F. Barbosa1, E.S. Okuda1, M.C. Chung2, E.I. Ferreira3 and Correspondence and Footnotes R.M.B. Cicarelli1

1Departamento de Ciências Biológicas, 2Departamento de Fármacos e Medicamentos, Faculdade de Ciências Farmacêuticas, Universidade Estadual Paulista, Araraquara, SP, Brasil

3Departamento de Farmácia, Faculdade de Ciências Farmacêuticas, Universidade de São Paulo, São Paulo, SP, Brasil

References

Correspondence and Footnotes Correspondence and Footnotes Correspondence and Footnotes

Abstract

No fully effective treatment has been developed since the discovery of Chagas' disease by Carlos Chagas in 1909. Since drug-resistant Trypanosoma cruzi strains are occurring and the current therapy is effectiveness in the acute phase but with various adverse side effects, more studies are needed to characterize the susceptibility of T. cruzi to new drugs. Many natural and/or synthetic substances showing trypanocidal activity have been used, even though they are not likely to be turned into clinically approved drugs. Originally, drug screening was performed using natural products, with only limited knowledge of the molecular mechanism involved in the development of diseases. Trans-splicing, which is unusual RNA processing reaction and occurs in nematodes and trypanosomes, implies the processing of polycistronic transcription units into individual mRNAs; a short transcript spliced leader (SL RNA) is trans-spliced to the acceptor pre-mRNA, giving origin to the mature mRNA. In the present study, permeable cells of T. cruzi epimastigote forms (Y, BOL and NCS strains) were treated to evaluate the interference of two drugs (hydroxymethylnitrofurazone - NFOH-121 and nitrofurazone) in the trans-splicing reaction using silver-stained PAGE analysis. Both drugs induced a significant reduction in RNA processing at concentrations from 5 to 12.5 µM. These data agreed with the biological findings, since the number of parasites decreased, especially with NFOH-121. This proposed methodology allows a rapid and cost-effective screening strategy for detecting drug interference in the trans-splicing mechanism of T. cruzi.

Key words: Trypanosoma cruzi, Trans-splicing, Trypanocidal drugs, Permeable cells, RNA processing, Hydroxymethylnitrofurazone

Introduction

American trypanosomiasis (Chagas' disease) is a major health problem in Central and South America. Approximately 2 to 3 million of about 20 million infected people can develop the characteristic clinical symptoms of the chronic stage of Chagas' disease and 45,000 die every year (1).

Trypanosoma cruzi, the etiological agent of Chagas' disease, shows a pathogenicity pattern that may be influenced by the characteristics of both the human host and the lineage of the T. cruzi strain (2). Thus, the course of infection in susceptible vertebrates is influenced not only by factors such as environmental temperature and the age, sex and genetic constitution of the human host, but also by morphological characteristics of the infecting strains, as well as of therapeutic agents. Treatment of infected people in endemic areas has been recommended by the National Health Foundation of Brazil for acute or recent chronic cases as well as for congenital and accidental infections and for children with positive serology. It is also indicated for patients with acquired immunodeficiency syndrome and for those undergoing organ transplantation or receiving immunosuppressive drugs, who are at risk for reactivation of latent infection with T. cruzi (3,4). However, successful treatment with currently used drugs (nifurtimox or benznidazole) is limited by the prevalence of T. cruzi strains resistant to these chemotherapeutics (5). It has been shown that resistance is correlated with biological characteristics of the parasite due to the occurrence of various sub-populations of the parasite leading to different host tissue's tropism (6).

Current therapy is based on nifurtimox and benznidazole, which are mostly effective in the acute phase of the disease but may cause serious adverse side effects (5). In Brazil, benznidazole is the only drug available on the market because of the claim that Brazilian T. cruzi strains are resistant to nifurtimox. In addition, several investigators have demonstrated that geographic differences might interfere with the efficacy of therapeutic regimens (5,7). It is urgent to find new and more effective drugs in order to treat patients with chronic disease.

Nitrofurazone (NF), a 5-nitro-furfurylidene- semicarbazone, is primarily an active antimicrobial agent against Gram-positive microorganisms but, due to its side effects, it has been used only for tropical infection (8,9). Nevertheless, a trypanocidal activity of that drug was observed by Andrade and Brener (9). Henderson and co-workers (10) found that its effect could be attributed to inhibition of a trypanothione-reductase, a key enzyme in the oxidative metabolism of the parasite. Despite their toxicity, nitroaromatic compounds are generally very active against T. cruzi and have been considered to be important targets for molecular modification (11,12).

Hydroxymethylnitrofuran (NFOH-121), an NF prodrug, showed better trypanocidal activity on all the parasitic forms than its parental drug, NF and/or benznidazole (13, 14), and demonstrated lower mutagenic activity (15). These findings suggested that NFOH-121 might be a very promising compound for in vivo toxicological studies, and for studies directed at establishing its mechanism of action (14).

The objective of the present study was to utilize this novel approach with permeable epimastigote cells of different T. cruzi strains to screen and investigate the activity of NFOH-121 and NF on mRNA processing. The method of analysis was standardized using silver-stained gels instead of the traditional radiolabeled nucleotide-based analysis in order to obtain a rapid evaluation of drug interference in the mRNA processing of each strain. Moreover, the biological effects of these drugs were studied against the three developmental stages of the T. cruzi Y strain. The activity of these compounds against different parasite strains leads us to propose NFOH-121 as a candidate drug for the treatment of Chagas' disease patients.

Material and Methods

Culture of Trypanosoma cruzi epimastigotes

T. cruzi epimastigote forms of the Y, NCS and Bolivia (BOL) strains were maintained in culture at 28ºC in LIT medium, with passages every 15 days. For the trans-splicing reaction with permeable cells, approximately 105-106 parasites were transferred to 50 mL LIT and incubated for 7 days at 28ºC. The Y strain was considered to be the standard (16). The BOL strain has being maintained in the laboratory for some years after isolation from triatominae (17). The NCS strain was isolated from a Chagas' disease patient (Buainain A, personal communication). The NCS and BOL strains are classified as T. cruzi II b/e, but the BOL strain showed different growth features in culture.

In vitro biological assays

The parasites (T. cruzi Y strain) were maintained in continuous culture in Dulbecco's modified Eagle's medium (DMEM) supplemented with NaHCO3 (1.2 g/L), penicillin (500,000 U/L) and streptomycin (100 mg/L), containing 10% heat-inactivated fetal bovine serum at 37ºC.

The assay was performed in 24-well tissue culture plates with 2 x 104/2 mL LLMCK2 (cell lineage provided by Adolfo Lutz Institute, São Paulo, SP, Brazil) maintained in DMEM medium (Gibco-BRL, Rockville, MD, USA), supplemented with 2 mM L-glutamine, 10 mM NaHCO3, 100 U/mL penicillin, 100 µg/mL streptomycin, and 5% heat-inactivated fetal calf serum. The cultures were incubated at 37ºC in an atmosphere containing 5% CO2 and 95% humidity until the occurrence of cell confluence. Drugs (NFOH-121 and NF) were dissolved in DMSO and water and diluted in medium to the desired concentrations, with the final DMSO concentrations not exceeding 0.1% (v/v). Trypomastigotes (1 x 106/mL) were inoculated 24 h after the cell layers were seeded. Fresh medium with or without drugs at concentrations of 5 and 10 µM was added to the cells every 24 h during the incubation period. In vitro activity was determined by counting the number of organisms 6, 7, 8, 12, 14, and 15 days after infection. The organisms were counted in a Neubauer chamber as trypomastigotes, amastigotes, or epimastigote-like forms. To facilitate evaluation, only the counts for the 8th and 15th days are reported in this paper.

In vitro trans-splicing reaction using Trypanosoma cruzi permeable cells

The permeable cell reactions were carried out according to Ullu and Tschudi (18) and Ambrosio et al. (19). In the experiments, 1.25 x 108T. cruzi epimastigote forms (Y, NCS and BOL strains) were washed and resuspended in TB (1X) solution (20 mM KGlu, 3 mM MgCl2, 1 mM DTT, 10 µg/mL leupeptin) and treated with 100 µg L-a-lysophosphatidylcholine and palmitoyl (Lysolecithin, Sigma, St. Louis, MO, USA). To initiate the trans-splicing reaction, a solution containing 2 mM ATP, 1 mM GTP, 1 mM CTP, 1 mM UTP (Gibco-BRL), 0.5X TB, 0.6 mg/mL creatine kinase (Roche, Basel, Switzerland), and 25 mM creatine phosphate (Sigma) was added. The drugs, NFOH-121 and NF, were added separately. After incubation at 28ºC for 20 min, the parasites were immediately lysed with Trizol (Life Technologies, Rockville, MD, USA) and RNA was recovered by extraction with chloroform and precipitation with isopropanol. The RNA was resuspended in 50% formamide/5X SET solution and electrophoresed on a 10% polyacrylamide-7 M urea gel followed by silver staining (30 min, 40% methanol/10% acetic acid; 2 x 15 min, 10% ethanol/5% acetic acid; 5 min, deionized water; 20 min, 12 mM AgNO3; 1 min, deionized water; 0.28 M Na2CO3 + 0.0185% formaldehyde until bands became visible).

Quantitation of RNA using Multi Analyst software

After gel staining, the bands were detected with Fluor-S Image software (BioRad, Hercules, CA, USA) and absorbance was quantified using the Multi Analyst software (BioRad). The values were compared to those obtained with controls without drugs and the percentages of each RNA were calculated.

Results

The biological tests on cell cultures showed that NFOH-121 was more effective than NF on the trypomastigotes, amastigotes and epimastigote-like forms of T. cruzi. These results, shown in Figure 1, demonstrate that the activity of 5 µM NFOH-121 was as effective as double the concentration of the parental drug NF (10 µM) for all parasite stages (P < 0.05) and NFOH-121 (5 µM) was even more effective after 15 days of treatment (data not shown).

The prodrug NFOH-121 itself reduced the intensities of the small nuclear (snRNA) bands (Figure 2, band 4: U4 snRNA; Figure 3, bands 1-3 and 6: U2, U1, U4 snRNAs and unrelated U snRNA, respectively) at concentrations between 5 and 12.5 µM. Figure 2 shows these results for the three T. cruzi strains (Y, NCS and BOL). All six RNA bands analyzed in the gel decreased when higher concentrations of NFOH-121 were used, suggesting that the drug did affect RNA processing mainly in the Y and NCS parasite strains. However, the drug showed no effect on the BOL strain (a higher concentration of the bands compared to the control). Figure 4 presents the absorbance readings of each band.

The activity of NFOH-121 compared with the parental drug NF was evaluated either by direct biological activity on the parasites (Figure 1) or by reducing RNA processing (Figures 2 through 5 Figure 5. Absorbance values of the bands obtained in Figure 3. NF = nitrofurazone; NFOH-121 = hydroxymethylnitrofuran. ), showing that NFOH-121 drug's activity is dose-dependent. The RNA bands were quantified by absorbance (Figures 4 and 5 Figure 5. Absorbance values of the bands obtained in Figure 3. NF = nitrofurazone; NFOH-121 = hydroxymethylnitrofuran. ), which confirmed the variation of RNA concentrations.

Both compounds (NF and NFOH-121) were also tested only on Y strain permeable cells using the same concentrations. The results are presented in Figures 3 and 5 Figure 5. Absorbance values of the bands obtained in Figure 3. NF = nitrofurazone; NFOH-121 = hydroxymethylnitrofuran. . The activity of NFOH-121 was higher than that of NF at 12.5 µM, supporting the in vitro findings.

Figure 1.
Inhibition of Trypanosoma cruzi growth in culture. Tryp = trypomastigotes; Amast = amastigotes; Epi-like = epimastigote-like forms; NF = nitrofurazone; NFOH-121 = hydroxymethylnitrofuran.

Figure 2.
RNAs from Trypanosoma cruzi permeable epimastigote cells of the Y, NCS, and BOL strains. Cells were treated with the hydroxymethylnitrofuran (NFOH-121) and electrophoresed on 10% polyacrylamide-7 M urea gel. A, Control without NFOH-121; B, 2 µM NFOH-121; C, 5 µM NFOH-121; D, 12.5 µM NFOH-121. 1) Unrelated small nuclear RNA; 2) U2; 3) U1; 4) U4; 5) U5; 6) U6 small nuclear RNAs. Molecular weights in base pairs are given on the left. Silver-stained gel.

Figure 3.
RNAs from Trypanosoma cruzi permeable epimastigote cells of the Y strain. Cells were treated with hydroxymethylnitrofuran (NFOH-121) and nitrofuran (NF) and electrophoresed on 10% polyacrylamide-7 M urea gel. A, Control without drugs; B, 2 µM NF; C, 2 µM NFOH-121; D, 12.5 µM NF; E, 12.5 µM NFOH-121. 1) U2; 2) U1; 3) U4; 4) U5; 5) U6 small nuclear RNAs; 6) unrelated small nuclear RNA. Molecular weights in base pairs are given on the left. Silver-stained gel.

Figure 4.
Absorbance values of the bands obtained in Figure 2. Y, NCS and BOL = Trypanosoma cruzi strains; NFOH-121 = hydroxymethylnitrofuran.

Discussion

The study of new trypanocidal drugs involves specific objectives related to the structure and metabolism of T. cruzi, which should be first studied in in vitro experiments (3). Three T. cruzi strains were used in this study. Although all of them belong to parasite lineage II, the BOL strain showed distinct features either under culture or in terms of drug influence. In all experiments, the Y strain was the most sensitive when compared with the other two strains, NCS and BOL. However, the BOL strain showed the same RNA band pattern even though higher drug concentrations (12.5 µM) were used (data not shown). These data also demonstrate that both strains (Y and NCS) were more susceptible to the effect of the drugs, reinforcing the idea that trypanocidal drugs should be tested on different strains, since the strains may behave differently when challenged.

When T. cruzi cells are treated with lysolecithin, the parasites become permeable to small molecules (18). Trans-splicing participates in the processing of polycistronic transcription units into individual mRNAs in which a short transcript spliced leader (SL RNA) is trans-spliced to the acceptor pre-mRNA, giving origin to the mature mRNA. We showed that NFOH-121 affected the RNA processing and the trans-splicing reaction, even though at lower intensity (19).

The decrease in the concentration of the small RNAs suggests that the drug interferes with RNA processing. However, the results obtained thus far show that this interference still promotes the trans-splicing reaction in the cells but at a lower rate than observed in the control, indicating that the drug activity did not completely abolish the trans-splicing reaction (19).

In the experiments in which the NF and NFOH-121 activities were compared under the same conditions and at the same concentrations, the higher solubility of NFOH-121 might have been decisive regarding the penetration and toxicity enhancement in all cells tested. Consequently, the higher activity of NFOH-121 than NF also suggests that the effectiveness of the drug can be improved after transformation into the hydroxymethyl derivative. Thus, NFOH-121 activity on the permeable cells was more intense at 12.5 µM, in agreement with the in vitro biological data.

Because 20 min of incubation of the drug with the permeable cells was probably insufficient to transform all the NFOH-121 molecules, the drug might have interfered mainly with the steps of RNA transcription, promoting a reduction of RNA bands and suggesting that NFOH-121 may be not only a prodrug, but mainly a new agent with trypanocidal activity. These results are compatible with those reported by Ambrosio et al. (19) and in addition suggest that somehow trans-splicing can also be affected in these parasites, since some RNA bands in the gels are related to the small nuclear RNAs involved in this mechanism (20).

It should be pointed out that in the present study RNA analysis was standardized using silver-stained polyacrylamide gels instead of radioactive gels, allowing a rapid, easier and less expensive screening of drug interference with the mRNA processing of parasite cells of different strains and/or different drug concentration simultaneously and using the same cell batch. The results indicate that this methodology is helpful to evaluate drug interference with the transcription/trans-splicing machinery by using the small RNA band pattern.

In addition, these results, taken together, appear to be very relevant for the study of NF/NFOH-121 drug activity in T. cruzi mRNA processing, suggesting that the latter compound is a very good candidate as a novel trypanocidal drug.

Acknowledgments

The authors gratefully acknowledge Dr. O.H. Thiemann (Departamento de Física e Informática, Grupo de Cristalografia, Instituto de Física, USP, São Carlos, SP, Brazil) and Dr. W. Colli (Departamento de Bioquímica, Instituto de Química, USP, São Paulo, SP, Brazil) for suggestions and discussion of the experiments.

Address for correspondence: R.M.B. Cicarelli, Faculdade de Ciências Farmacêuticas, UNESP, Rod. Araraquara-Jaú, km 01, 14801-902 Araraquara, SP, Brasil. Fax: +55-16-3301-6940. E-mail: cicarell@fcfar.unesp.br

Research supported by FAPESP (Nos. 99/11393-4, 01/01192-3, 03/05791-4, and 04/01630-9) and PADC/FCF-UNESP (Nos. 2002/12-I and 2004/01-I). E.S. Okuda was the recipient of a fellowship from PIBIC/CNPq. Received February 16, 2006. Accepted October 27, 2006.

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  • Figure 5. Absorbance values of the bands obtained in Figure 3. NF = nitrofurazone; NFOH-121 = hydroxymethylnitrofuran.
  • Correspondence and Footnotes

  • Publication Dates

    • Publication in this collection
      13 Dec 2006
    • Date of issue
      Jan 2007

    History

    • Accepted
      27 Oct 2006
    • Received
      16 Feb 2006
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