Gaussian field-based 3D-QSAR and molecular simulation studies to design potent pyrimidine-sulfonamide hybrids as selective BRAFV600E inhibitors

Ankit Kumar Singh; Jurica Novak; Adarsh Kumar; Harshwardhan Singh; Suresh Thareja; Prateek Pathak; Maria Grishina; Amita Verma; Jagat Pal Yadav; Habibullah Khalilullah; Vikas Pathania; Hemraj Nandanwar; Mariusz Jaremko; Abdul-Hamid Emwas; Pradeep Kumar

doi:10.1039/d2ra05751d

Gaussian field-based 3D-QSAR and molecular simulation studies to design potent pyrimidine-sulfonamide hybrids as selective BRAF^V600E inhibitors

RSC Adv. 2022 Oct 21;12(46):30181-30200. doi: 10.1039/d2ra05751d. eCollection 2022 Oct 17.

Authors

Ankit Kumar Singh¹, Jurica Novak^{2

3

4}, Adarsh Kumar¹, Harshwardhan Singh¹, Suresh Thareja¹, Prateek Pathak⁵, Maria Grishina⁵, Amita Verma⁶, Jagat Pal Yadav^{6

7}, Habibullah Khalilullah⁸, Vikas Pathania⁹, Hemraj Nandanwar⁹, Mariusz Jaremko¹⁰, Abdul-Hamid Emwas¹¹, Pradeep Kumar¹

Affiliations

¹ Department of Pharmaceutical Sciences and Natural Products, Central University of Punjab Ghudda Bathinda 151401 India ankitsinghpbh12195@gmail.com adarshkumar5198@gmail.com harshwardhansingh371995@gmail.com suresh.thareja@cup.edu.in pradeepyadav27@gmail.com pradeep.kumar@cup.edu.in.
² Department of Biotechnology, University of Rijeka Rijeka 51000 Croatia jurica.novak@biotech.uniri.hr.
³ Center for Artificial Intelligence and Cybersecurity, University of Rijeka Rijeka 51000 Croatia.
⁴ Scientific and Educational Center 'Biomedical Technologies' School of Medical Biology, South Ural State University Chelyabinsk RU-454080 Russia.
⁵ Laboratory of Computational Modeling of Drugs, Higher Medical and Biological School, South Ural State University Chelyabinsk 454008 Russia patkhakp@susu.ru grishinama@susu.ru.
⁶ Department of Pharmaceutical Sciences, Bioorganic and Medicinal Chemistry Research Laboratory, Sam Higginbottom University of Agriculture, Technology and Sciences Prayagraj 211007 India amita.verma@shiats.edu.in j.p.yaduvansi@gmail.com.
⁷ Department of Pharmacology, Kamla Nehru Institute of Management and Technology Faridipur Sultanpur 228118 India.
⁸ Department of Pharmaceutical Chemistry and Pharmacognosy, Unaizah College of Pharmacy, Qassim University Unayzah 51911 Saudi Arabia h.abdulaziz@qu.edu.sa.
⁹ Clinical Microbiology & Bioactive Screening Laboratory, Council of Scientifc & Industrial Research -Institute of Microbial Technology Sector-39A Chandigarh 160036 India vikasp2311@gmail.com hemraj@imtech.res.in.
¹⁰ Smart-Health Initiative (SHI) and Red Sea Research Center (RSRC), Division of Biological and Environmental Sciences and Engineering (BESE), King Abdullah University of Science and Technology (KAUST) Thuwal 23955-6900 Saudi Arabia mariusz.jaremko@kaust.edu.sa.
¹¹ Core Labs, King Abdullah University of Science and Technology (KAUST) Thuwal 23955-6900 Saudi Arabia abdelhamid.emwas@kaust.edu.sa.

Abstract

The "RAS-RAF-MEK-ERK" pathway is an important signaling pathway in melanoma. BRAF^V600E (70-90%) is the most common mutation in this pathway. BRAF inhibitors have four types of conformers: type I (αC-IN/DFG-IN), type II (αC-IN/DFG-OUT), type I_1/2 (αC-OUT/DFG-IN), and type I/II (αC-OUT/DFG-OUT). First- and second-generation BRAF inhibitors show resistance to BRAF^V600E and are ineffective against malignancies induced by dimer BRAF mutants causing 'paradoxical' activation. In the present study, we performed molecular modeling of pyrimidine-sulfonamide hybrids inhibitors using 3D-QSAR, molecular docking, and molecular dynamics simulations. Previous reports reveal the importance of pyrimidine and sulfonamide moieties in the development of BRAF^V600E inhibitors. Analysis of 3D-QSAR models provided novel pyrimidine sulfonamide hybrid BRAF^V600E inhibitors. The designed compounds share similarities with several structural moieties present in first- and second-generation BRAF inhibitors. A total library of 88 designed compounds was generated and molecular docking studies were performed with them. Four molecules (T109, T183, T160, and T126) were identified as hits and selected for detailed studies. Molecular dynamics simulations were performed at 900 ns and binding was calculated. Based on molecular docking and simulation studies, it was found that the designed compounds have better interactions with the core active site [the nucleotide (ADP or ATP) binding site, DFG motif, and the phospho-acceptor site (activation segment) of BRAF^V600E protein than previous inhibitors. Similar to the FDA-approved BRAF^V600E inhibitors the developed compounds have [αC-OUT/DFG-IN] conformation. Compounds T126, T160 and T183 interacted with DIF (Leu505), making them potentially useful against BRAF^V600E resistance and malignancies induced by dimer BRAF mutants. The synthesis and biological evaluation of the designed molecules is in progress, which may lead to some potent BRAF^V600E selective inhibitors.