New Benzoxazole Derivatives as Antiprotozoal Agents: In Silico Studies, Synthesis, and Biological Evaluation

Mohamed A Abdelgawad,Shabana I Khan,Ohoud J Alotaibi,Amar G Chittiboyina,Mohammad M Al-Sanea,Heba A H Elshemy,Abdulsalam A M Alkhaldi,Enas I A Mohamed,Tarfah Al-Warhi,Nada Aljaeed,Mohamed A Zaki,Ikhlas A Khan,Babu L Tekwani,Teodorico C Ramalho

doi:10.1155/2021/6631868

Abstract

Background. Benzoxazole derivatives have different biological activities. In pursuit of designing novel chemical entities with antiprotozoal and antimicrobial activities, benzoxazolyl aniline was utilized as a privileged scaffold of a series of (3-benzoxazole-2-yl) phenylamine derivatives, 3-benzoxazoloyl acetamide, and butyramide derivatives. Methods. These novel analogs were synthesized in straightforward simple chemistry without any quantitative chromatographic separations in reasonable yields. The biological evaluation of all target compounds as potential antimalarial, antileishmanial, antitrypanosomal, and antimicrobial agents was performed by various well-established cell-based methods. Results. Compounds 6d and 5a showed promising biological screening data. The amidation of 3-benzoxazolyl aniline 1 with the chloroacetyl functional group resulted in a good antimalarial activity and showed moderate inhibitory activities against leishmanial and trypanosomal spp. Moreover, chloroacetyl functionalization of benzoxazolyl aniline serves as a good early goal for constructing and synthesizing new antimicrobial and antiprotozoal agents. The molecular docking study rationalizes the relative inhibitory activity of compound 5a as an antimalarial agent with the deregulation of PfPNP activity which has emerged as a major mechanism of these targets.

Highlights

Malaria is a lethal illness initiated through the spreading of parasites via the nibbles of infected female mosquitoes
In consideration of the aforementioned background and with the extension of our former investigations on benzoxazole moiety and its innate pharmacological activities [14, 29,30,31,32,33], we describe the preparation of a new series of compounds with 3-benzoxazolyl aniline scaffold (Figure 2)
Benzoxazolyl aniline 1 with appropriate benzaldehyde under reflux condition in absolute ethanol and with 4-5 drops of glacial acetic acid. Another set of triazine derivatives 4a–d was synthesized through successive nucleophilic substitution of cyanuric chloride with different aryl amines in one pot [48]

Summary

Introduction

Malaria is a lethal illness initiated through the spreading of parasites via the nibbles of infected female mosquitoes. Journal of Chemistry life-threatening neglected tropical disease, leishmaniasis, is triggered by several Leishmania parasite genus [4]. E biological evaluation of all target compounds as potential antimalarial, antileishmanial, antitrypanosomal, and antimicrobial agents was performed by various well-established cell-based methods. E amidation of 3-benzoxazolyl aniline 1 with the chloroacetyl functional group resulted in a good antimalarial activity and showed moderate inhibitory activities against leishmanial and trypanosomal spp. Chloroacetyl functionalization of benzoxazolyl aniline serves as a good early goal for constructing and synthesizing new antimicrobial and antiprotozoal agents. E molecular docking study rationalizes the relative inhibitory activity of compound 5a as an antimalarial agent with the deregulation of PfPNP activity which has emerged as a major mechanism of these targets Chloroacetyl functionalization of benzoxazolyl aniline serves as a good early goal for constructing and synthesizing new antimicrobial and antiprotozoal agents. e molecular docking study rationalizes the relative inhibitory activity of compound 5a as an antimalarial agent with the deregulation of PfPNP activity which has emerged as a major mechanism of these targets

Methods

Results

Conclusion