Coumarin-based derivatives targeting Trypanosoma cruzi cruzain and Trypanosoma brucei cathepsin L-like proteases

Coumarin-based derivatives targeting Trypanosoma cruzi cruzain and Trypanosoma brucei cathepsin L-like proteases

The protozoa, Trypanosoma cruzi (etiological agent of Chagas diseases – also named American trypanosomiasis) and T. brucei (causative agent of human African trypanosomiasis – HAT), negatively impact public health, being endemic in several countries and leading to thousands of deaths per year. Moreov...

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Veröffentlicht in:New journal of chemistry 2023-05, Vol.47 (21), p.10127-10146
Hauptverfasser: Nunes, Jéssica Alves, Silva, Fabrícia Nunes da, Silva, Elany Barbosa da, Costa, Clara Andrezza Crisóstomo Bezerra, Freitas, Johnnatan Duarte de, Mendonça-Junior, Francisco Jaime Bezerra, Giardini, Miriam Aparecida, Siqueira-Neto, Jair Lage de, McKerrow, James H., Rodrigues Teixeira, Thaiz, Odeesho, Louis William, Caffrey, Conor R., Cardoso, Sílvia Helena, Silva-Júnior, Edeildo Ferreira da
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Analogs
Biological activity
Complex formation
Coumarin
Cysteine
Dynamic stability
Mathematical analysis
Molecular dynamics
Protease inhibitors
Protozoa
Public health
Side effects
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container_end_page 10146
container_issue 21
container_start_page 10127
container_title New journal of chemistry
container_volume 47
creator Nunes, Jéssica Alves
Silva, Fabrícia Nunes da
Silva, Elany Barbosa da
Costa, Clara Andrezza Crisóstomo Bezerra
Freitas, Johnnatan Duarte de
Mendonça-Junior, Francisco Jaime Bezerra
Giardini, Miriam Aparecida
Siqueira-Neto, Jair Lage de
McKerrow, James H.
Rodrigues Teixeira, Thaiz
Odeesho, Louis William
Caffrey, Conor R.
Cardoso, Sílvia Helena
Silva-Júnior, Edeildo Ferreira da
description The protozoa, Trypanosoma cruzi (etiological agent of Chagas diseases – also named American trypanosomiasis) and T. brucei (causative agent of human African trypanosomiasis – HAT), negatively impact public health, being endemic in several countries and leading to thousands of deaths per year. Moreover, the pharmacological treatment of diseases has several limitations, such as parasitic resistance and several side effects in patients, which decrease therapeutic adherence. Two cysteine proteases, cruzain (CRZ) from T. cruzi and a cathepsin L-like enzyme ( Tbr CATL) from T. brucei , are considered promising targets of these protozoa since they are responsible for many key biological processes in their life cycles. Coumarin analogs have been reported in diverse studies targeting the development of trypanocidal agents, and have shown activity against different evolutionary forms of these parasites. In this study, we report a virtual fragment-based drug design (vFBDD) approach to develop coumarin-based analogs capable of inhibiting these main cysteine proteases. Also, their experimental validation involved enzymatic inhibition, in vitro infected-cell-based, and antitrypomastigote assays. One compound, FN-27, a coumarin-thiosemicarbazone analog, inhibited both CRZ (IC 50 : 14.4 μM ± 0.02) and Tbr CATL (IC 50 : 2.0 μM ± 0.6), and exhibited trypanocidal activity against T. cruzi amastigote-infected cells (EC 50 : 5.5 μM), but had no effect on T. brucei trypomastigotes. These results suggest that FN-27 probably exerts its mechanism of action against the T. cruzi parasite via inhibition of CRZ, although other targets could be involved. In parallel, FN-10, a coumarin-chalcone analog, was active against T. brucei trypomastigotes (EC 50 : 4.8 μM ± 0.15) but it did not inhibit CRZ or Tbr CATL. Accordingly, FN-10 may exhibit its effects via a different macromolecular target(s) in each parasite. For FN-27, molecular dynamics (MD) simulations were performed to gain insights into the stability of its final complexes with both proteases within 200 ns, and the parameters RMSD, RMSF, R g , and SASA were determined, through which it was verified that FN-27 adopts various binding modes in the catalytic site for both proteases, corroborating our experimental data. MM/PBSA calculations suggested that the most relevant stabilizing interactions for the complex formation were van der Waals interactions. Also, it was noted that the binding energy (Δ E MM ) for Tbr CATL is more favorabl
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Moreover, the pharmacological treatment of diseases has several limitations, such as parasitic resistance and several side effects in patients, which decrease therapeutic adherence. Two cysteine proteases, cruzain (CRZ) from T. cruzi and a cathepsin L-like enzyme ( Tbr CATL) from T. brucei , are considered promising targets of these protozoa since they are responsible for many key biological processes in their life cycles. Coumarin analogs have been reported in diverse studies targeting the development of trypanocidal agents, and have shown activity against different evolutionary forms of these parasites. In this study, we report a virtual fragment-based drug design (vFBDD) approach to develop coumarin-based analogs capable of inhibiting these main cysteine proteases. Also, their experimental validation involved enzymatic inhibition, in vitro infected-cell-based, and antitrypomastigote assays. One compound, FN-27, a coumarin-thiosemicarbazone analog, inhibited both CRZ (IC 50 : 14.4 μM ± 0.02) and Tbr CATL (IC 50 : 2.0 μM ± 0.6), and exhibited trypanocidal activity against T. cruzi amastigote-infected cells (EC 50 : 5.5 μM), but had no effect on T. brucei trypomastigotes. These results suggest that FN-27 probably exerts its mechanism of action against the T. cruzi parasite via inhibition of CRZ, although other targets could be involved. In parallel, FN-10, a coumarin-chalcone analog, was active against T. brucei trypomastigotes (EC 50 : 4.8 μM ± 0.15) but it did not inhibit CRZ or Tbr CATL. Accordingly, FN-10 may exhibit its effects via a different macromolecular target(s) in each parasite. For FN-27, molecular dynamics (MD) simulations were performed to gain insights into the stability of its final complexes with both proteases within 200 ns, and the parameters RMSD, RMSF, R g , and SASA were determined, through which it was verified that FN-27 adopts various binding modes in the catalytic site for both proteases, corroborating our experimental data. MM/PBSA calculations suggested that the most relevant stabilizing interactions for the complex formation were van der Waals interactions. Also, it was noted that the binding energy (Δ E MM ) for Tbr CATL is more favorable than for CRZ, again corroborating the enzymatic inhibition assays. 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Moreover, the pharmacological treatment of diseases has several limitations, such as parasitic resistance and several side effects in patients, which decrease therapeutic adherence. Two cysteine proteases, cruzain (CRZ) from T. cruzi and a cathepsin L-like enzyme ( Tbr CATL) from T. brucei , are considered promising targets of these protozoa since they are responsible for many key biological processes in their life cycles. Coumarin analogs have been reported in diverse studies targeting the development of trypanocidal agents, and have shown activity against different evolutionary forms of these parasites. In this study, we report a virtual fragment-based drug design (vFBDD) approach to develop coumarin-based analogs capable of inhibiting these main cysteine proteases. Also, their experimental validation involved enzymatic inhibition, in vitro infected-cell-based, and antitrypomastigote assays. One compound, FN-27, a coumarin-thiosemicarbazone analog, inhibited both CRZ (IC 50 : 14.4 μM ± 0.02) and Tbr CATL (IC 50 : 2.0 μM ± 0.6), and exhibited trypanocidal activity against T. cruzi amastigote-infected cells (EC 50 : 5.5 μM), but had no effect on T. brucei trypomastigotes. These results suggest that FN-27 probably exerts its mechanism of action against the T. cruzi parasite via inhibition of CRZ, although other targets could be involved. In parallel, FN-10, a coumarin-chalcone analog, was active against T. brucei trypomastigotes (EC 50 : 4.8 μM ± 0.15) but it did not inhibit CRZ or Tbr CATL. Accordingly, FN-10 may exhibit its effects via a different macromolecular target(s) in each parasite. For FN-27, molecular dynamics (MD) simulations were performed to gain insights into the stability of its final complexes with both proteases within 200 ns, and the parameters RMSD, RMSF, R g , and SASA were determined, through which it was verified that FN-27 adopts various binding modes in the catalytic site for both proteases, corroborating our experimental data. MM/PBSA calculations suggested that the most relevant stabilizing interactions for the complex formation were van der Waals interactions. Also, it was noted that the binding energy (Δ E MM ) for Tbr CATL is more favorable than for CRZ, again corroborating the enzymatic inhibition assays. 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Moreover, the pharmacological treatment of diseases has several limitations, such as parasitic resistance and several side effects in patients, which decrease therapeutic adherence. Two cysteine proteases, cruzain (CRZ) from T. cruzi and a cathepsin L-like enzyme ( Tbr CATL) from T. brucei , are considered promising targets of these protozoa since they are responsible for many key biological processes in their life cycles. Coumarin analogs have been reported in diverse studies targeting the development of trypanocidal agents, and have shown activity against different evolutionary forms of these parasites. In this study, we report a virtual fragment-based drug design (vFBDD) approach to develop coumarin-based analogs capable of inhibiting these main cysteine proteases. Also, their experimental validation involved enzymatic inhibition, in vitro infected-cell-based, and antitrypomastigote assays. One compound, FN-27, a coumarin-thiosemicarbazone analog, inhibited both CRZ (IC 50 : 14.4 μM ± 0.02) and Tbr CATL (IC 50 : 2.0 μM ± 0.6), and exhibited trypanocidal activity against T. cruzi amastigote-infected cells (EC 50 : 5.5 μM), but had no effect on T. brucei trypomastigotes. These results suggest that FN-27 probably exerts its mechanism of action against the T. cruzi parasite via inhibition of CRZ, although other targets could be involved. In parallel, FN-10, a coumarin-chalcone analog, was active against T. brucei trypomastigotes (EC 50 : 4.8 μM ± 0.15) but it did not inhibit CRZ or Tbr CATL. Accordingly, FN-10 may exhibit its effects via a different macromolecular target(s) in each parasite. For FN-27, molecular dynamics (MD) simulations were performed to gain insights into the stability of its final complexes with both proteases within 200 ns, and the parameters RMSD, RMSF, R g , and SASA were determined, through which it was verified that FN-27 adopts various binding modes in the catalytic site for both proteases, corroborating our experimental data. MM/PBSA calculations suggested that the most relevant stabilizing interactions for the complex formation were van der Waals interactions. Also, it was noted that the binding energy (Δ E MM ) for Tbr CATL is more favorable than for CRZ, again corroborating the enzymatic inhibition assays. 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source Royal Society Of Chemistry Journals 2008-; Alma/SFX Local Collection
subjects Analogs
Biological activity
Complex formation
Coumarin
Cysteine
Dynamic stability
Mathematical analysis
Molecular dynamics
Protease inhibitors
Protozoa
Public health
Side effects
title Coumarin-based derivatives targeting Trypanosoma cruzi cruzain and Trypanosoma brucei cathepsin L-like proteases
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