Your search keyword '"computer-aided drug design"' showing total 1,274 results

1. Identification of natural compounds as potential antiviral drug candidates against Hepatitis E virus through molecular docking and dynamics simulations

Author

Uddin, Mohammad Borhan, Praseetha, P.K., Ahmed, Rony, Shaheen, Mir Md, Kaouche, Farah Chafika, Bairagi, Rahul Dev, Jawi, Motasim, Alharbi, Hanan M., Khojah, Alaa A., Hassan, Hesham M., and Al-Emam, Ahmed

Published

2024

2. AURA: Accelerating drug discovery with accuracy, utility, and rank-order assessment for data-driven decision making

Author

Price, Edward, Saulnier, Virginia, Kalvass, John Cory, Doktor, Stella, Weinheimer, Manuel, Hassan, Majdi, Scholz, Spencer, Nijsen, Marjoleen, and Jenkins, Gary

Published

2024

3. Identification of potential MMP-8 inhibitors through virtual screening of natural product databases.

Author

Wang, Yi and Chen, Xiushan

Abstract

Matrix metalloproteinase-8 (MMP-8), a type II collagenase, is a key enzyme in the degradation of collagens and is implicated in various pathological processes, making it a promising target for drug discovery. Despite advancements in the development of MMP-8 inhibitors, concerns over potential adverse effects persist. This study aims to address these concerns by focusing on the development of novel compounds with improved safety profiles while maintaining efficacy. In this study, we employed a computational approach to screen potent and safe inhibitors of MMP-8 from the Natural Product Activity and Species Source Database (NPASS). Initially, we constructed a pharmacophore model based on the crystal structure of the MMP-8-FIN complex (PDB ID: 4EY6) utilizing the Pharmit tool. This model then guided the selection of 44 promising molecules from NPASS, setting the stage for further analysis and evaluation. We comprehensively evaluated their drug-likeness and toxicity profiles. Molecules 21, 4, and 44 were identified as potentially effective MMP-8 inhibitors through a robust pipeline that included ADMET profiling, molecular docking, and molecular dynamics simulations. Notably, molecule 21 stood out for its low toxicity, high binding stability, and favorable ADMET profile, while molecule 44 demonstrated excellent affinity. These compounds offer structural novelty compared to known MMP-8 inhibitors. These computational results can be combined with in vitro experiments in the future to validate their activity and safety. These findings provide an important reference for drug design of MMP-8 inhibitors. [ABSTRACT FROM AUTHOR]

Published

2025

4. CSearch: chemical space search via virtual synthesis and global optimization.

Author

Kim, Hakjean, Ryu, Seongok, Jung, Nuri, Yang, Jinsol, and Seok, Chaok

Subjects

*GRAPH neural networks, *COMPUTER-assisted drug design, *OPTIMIZATION algorithms, *CHEMICAL libraries, *GLOBAL optimization

Abstract

The two key components of computational molecular design are virtually generating molecules and predicting the properties of these generated molecules. This study focuses on an effective method for molecular generation through virtual synthesis and global optimization of a given objective function. Using a pre-trained graph neural network (GNN) objective function to approximate the docking energies of compounds for four target receptors, we generated highly optimized compounds with 300–400 times less computational effort compared to virtual compound library screening. These optimized compounds exhibit similar synthesizability and diversity to known binders with high potency and are notably novel compared to library chemicals or known ligands. This method, called CSearch, can be effectively utilized to generate chemicals optimized for a given objective function. With the GNN function approximating docking energies, CSearch generated molecules with predicted binding poses to the target receptors similar to known inhibitors, demonstrating its effectiveness in producing drug-like binders. Scientific Contribution We have developed a method for effectively exploring the chemical space of drug-like molecules using a global optimization algorithm with fragment-based virtual synthesis. The compounds generated using this method optimize the given objective function efficiently and are synthesizable like commercial library compounds. Furthermore, they are diverse, novel drug-like molecules with properties similar to known inhibitors for target receptors. [ABSTRACT FROM AUTHOR]

Published

2024

5. Targeting serotonin receptors with phytochemicals – an in-silico study.

Author

Elalouf, Amir, Rosenfeld, Amit Yaniv, and Maoz, Hanan

Subjects

*COMPUTER-assisted drug design, *RECEPTOR-ligand complexes, *SEROTONIN receptors, *MOLECULAR dynamics, *MOLECULAR docking

Abstract

The potential of natural phytochemicals in mitigating depression has been supported by substantial evidence. This study evaluated a total of 88 natural phytochemicals with potential antidepressant properties by targeting serotonin (5-HT) receptors (5-HT1A, 5-HT4, and 5-HT7) using molecular docking, ADMET (Absorption, Distribution, Metabolism, Excretion, and Toxicity) analysis, internal coordinates normal mode analysis (NMA), molecular dynamics simulation (MDS), and free energy calculation. Five evaluated compounds (Genistein, Kaempferol, Daidzein, Peonidin, and glycitein) exhibited favorable pharmacokinetic properties and improved binding scores, indicating their potential as effective antidepressants. Redocking and superimposition analysis of 5-HT with cocrystal structures validated these findings. Furthermore, NMA, MDS, and free energy calculations confirmed the stability and deformability of the ligand-receptor complexes, suggesting that these phytochemicals can effectively interact with 5-HT receptors to modulate depressive symptoms. These powerful phytochemicals, abundantly found in soybeans, fruits, vegetables, and herbs, represent a promising avenue for developing natural treatments for depression. Further in vitro and in vivo studies are warranted to explore their efficacy in alleviating stress and depression through their interactions with 5-HT receptors. [ABSTRACT FROM AUTHOR]

Published

2024

6. Protein language models are performant in structure-free virtual screening.

Author

Lam, Hilbert Yuen In, Guan, Jia Sheng, Ong, Xing Er, Pincket, Robbe, and Mu, Yuguang

Subjects

*VIRTUAL high-throughput screening (Drug development), *COMPUTER-assisted drug design, *LANGUAGE models, *MOLECULAR graphs, *PROTEIN models, *DRUG design

Abstract

Hitherto virtual screening (VS) has been typically performed using a structure-based drug design paradigm. Such methods typically require the use of molecular docking on high-resolution three-dimensional structures of a target protein—a computationally-intensive and time-consuming exercise. This work demonstrates that by employing protein language models and molecular graphs as inputs to a novel graph-to-transformer cross-attention mechanism, a screening power comparable to state-of-the-art structure-based models can be achieved. The implications thereof include highly expedited VS due to the greatly reduced compute required to run this model, and the ability to perform early stages of computer-aided drug design in the complete absence of 3D protein structures. [ABSTRACT FROM AUTHOR]

Published

2024

7. Targeting serotonin receptors with phytochemicals – an in-silico study

Author

Amir Elalouf, Amit Yaniv Rosenfeld, and Hanan Maoz

Subjects

Computer-aided drug design, Serotonin receptors, Phytochemicals, Antidepressants, Medicine, Science

Abstract

Abstract The potential of natural phytochemicals in mitigating depression has been supported by substantial evidence. This study evaluated a total of 88 natural phytochemicals with potential antidepressant properties by targeting serotonin (5-HT) receptors (5-HT1A, 5-HT4, and 5-HT7) using molecular docking, ADMET (Absorption, Distribution, Metabolism, Excretion, and Toxicity) analysis, internal coordinates normal mode analysis (NMA), molecular dynamics simulation (MDS), and free energy calculation. Five evaluated compounds (Genistein, Kaempferol, Daidzein, Peonidin, and glycitein) exhibited favorable pharmacokinetic properties and improved binding scores, indicating their potential as effective antidepressants. Redocking and superimposition analysis of 5-HT with cocrystal structures validated these findings. Furthermore, NMA, MDS, and free energy calculations confirmed the stability and deformability of the ligand-receptor complexes, suggesting that these phytochemicals can effectively interact with 5-HT receptors to modulate depressive symptoms. These powerful phytochemicals, abundantly found in soybeans, fruits, vegetables, and herbs, represent a promising avenue for developing natural treatments for depression. Further in vitro and in vivo studies are warranted to explore their efficacy in alleviating stress and depression through their interactions with 5-HT receptors.

Published

2024

8. CSearch: chemical space search via virtual synthesis and global optimization

Author

Hakjean Kim, Seongok Ryu, Nuri Jung, Jinsol Yang, and Chaok Seok

Subjects

Chemical space search, Computer-aided drug design, Global optimization, Virtual synthesis, Information technology, T58.5-58.64, Chemistry, QD1-999

Abstract

Abstract The two key components of computational molecular design are virtually generating molecules and predicting the properties of these generated molecules. This study focuses on an effective method for molecular generation through virtual synthesis and global optimization of a given objective function. Using a pre-trained graph neural network (GNN) objective function to approximate the docking energies of compounds for four target receptors, we generated highly optimized compounds with 300–400 times less computational effort compared to virtual compound library screening. These optimized compounds exhibit similar synthesizability and diversity to known binders with high potency and are notably novel compared to library chemicals or known ligands. This method, called CSearch, can be effectively utilized to generate chemicals optimized for a given objective function. With the GNN function approximating docking energies, CSearch generated molecules with predicted binding poses to the target receptors similar to known inhibitors, demonstrating its effectiveness in producing drug-like binders. Scientific Contribution We have developed a method for effectively exploring the chemical space of drug-like molecules using a global optimization algorithm with fragment-based virtual synthesis. The compounds generated using this method optimize the given objective function efficiently and are synthesizable like commercial library compounds. Furthermore, they are diverse, novel drug-like molecules with properties similar to known inhibitors for target receptors.

Published

2024

9. In silico approaches supporting drug repurposing for Leishmaniasis

Author

Gustavo Scheiffer, Karime Zeraik Abdalla Domingues, Daniela Gorski, Alexandre de Fátima Cobre, Raul Edison Luna Lazo, Helena Hiemisch Lobo Borba, Luana Mota Ferreira, and Roberto Pontarolo

Subjects

neglected tropical diseases, computer-aided drug design, repositioning, docking, molecular dynamics, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282, Biology (General), QH301-705.5

Abstract

The shortage of treatment options for leishmaniasis, especially those easy to administer and viable for deployment in the world's poorest regions, highlights the importance of employing these strategies to cost-effectively investigate repurposing candidates. This scoping review aims to map the studies using in silico methodologies for drug repurposing against leishmaniasis. This study followed JBI recommendations for scoping reviews. Articles were searched on PubMed, Scopus, and Web of Science databases using keywords related to leishmaniasis and in silico methods for drug discovery, without publication date restrictions. The selection was based on primary studies involving computational methods for antileishmanial drug repurposing. Information about methodologies, obtained data, and outcomes were extracted. After the full-text appraisal, 34 studies were included in this review. Molecular docking was the preferred method for evaluating repurposing candidates (n=25). Studies reported 154 unique ligands and 72 different targets, sterol 14-alpha demethylase and trypanothione reductase being the most frequently reported. In silico screening was able to correctly pinpoint some known active pharmaceutical classes and propose previously untested drugs. Fifteen drugs investigated in silico exhibited low micromolar inhibition (IC50 < 10 µM) of Leishmania spp. in vitro. In conclusion, several in silico repurposing candidates are yet to be investigated in vitro and in vivo. Future research could expand the number of targets screened and employ advanced methods to optimize drug selection, offering new starting points for treatment development.

Published

2024

10. Adaptation of the REINVENT neural network architecture to generate potential HIV-1 entry inhibitors

Author

D. A. Varabyeu, A. D. Karpenko, A. V. Tuzikov, and A. M. Andrianov

Subjects

generative ai, reinforcement learning, computer-aided drug design, molecular docking, hiv-1, gp120 protein, anti-hiv drugs, Electronic computers. Computer science, QA75.5-76.95

Abstract

Objectives. The main purpose of this work is to adapt the architecture of the REINVENT neural network to generate potential inhibitors of the HIV-1 envelope protein gp120 using in the learning process with reinforcement of molecular docking on GPUs.Methods. To modify the initial network model, molecular docking on GPUs implemented in the learning process with reinforcement was used, and an algorithm was developed that allows converting the representations of connections generated by the SMILES network into the PDBQT format necessary for docking. To accelerate the learning of the neural network in the modified version of the REINVENT model, the AutoDock-Vina-GPU-2.1 docking program was used, and to clarify the results of its work, the procedure for revaluing the affinity of compounds to the target using the RFScore-4 evaluation function was used.Results. Using a modified version of the REINVENT model, more than 60,000 compounds were obtained, of which about 52,000 molecules have a binding energy value to the HIV-1 gp120 protein comparable to the value calculated for the HIV-1 inhibitor NBD-14204, used in calculations as a positive control. Of the 52,000 compounds selected, about 34,000 molecules satisfy the restrictions imposed on a potential drug to ensure its bioavailability when taken orally.Conclusion. The results obtained allow us to demonstrate the effectiveness of an adapted neural network by the example of designing new potential inhibitors of the gp120 HIV-1 protein capable of blocking the CD4- binding site of the gp120 virus envelope protein and preventing its penetration into host cells.

Published

2024

11. Teaching old docks new tricks with machine learning enhanced ensemble docking

Author

Roshni Bhatt, Ann Wang, and Jacob D. Durrant

Subjects

Ensemble virtual screening, Computer-aided drug design, Molecular docking, User-friendly software, Machine learning, Decision trees, Medicine, Science

Abstract

Abstract We here introduce Ensemble Optimizer (EnOpt), a machine-learning tool to improve the accuracy and interpretability of ensemble virtual screening (VS). Ensemble VS is an established method for predicting protein/small-molecule (ligand) binding. Unlike traditional VS, which focuses on a single protein conformation, ensemble VS better accounts for protein flexibility by predicting binding to multiple protein conformations. Each compound is thus associated with a spectrum of scores (one score per protein conformation) rather than a single score. To effectively rank and prioritize the molecules for further evaluation (including experimental testing), researchers must select which protein conformations to consider and how best to map each compound’s spectrum of scores to a single value, decisions that are system-specific. EnOpt uses machine learning to address these challenges. We perform benchmark VS to show that for many systems, EnOpt ranking distinguishes active compounds from inactive or decoy molecules more effectively than traditional ensemble VS methods. To encourage broad adoption, we release EnOpt free of charge under the terms of the MIT license.

Published

2024

12. Hamiltonian diversity: effectively measuring molecular diversity by shortest Hamiltonian circuits

Author

Xiuyuan Hu, Guoqing Liu, Quanming Yao, Yang Zhao, and Hao Zhang

Subjects

Computer-aided drug design, Molecular generation, Molecular diversity, Shortest Hamiltonian circuit, Information technology, T58.5-58.64, Chemistry, QD1-999

Abstract

Abstract In recent years, significant advancements have been made in molecular generation algorithms aimed at facilitating drug development, and molecular diversity holds paramount importance within the realm of molecular generation. Nonetheless, the effective quantification of molecular diversity remains an elusive challenge, as extant metrics exemplified by Richness and Internal Diversity fall short in concurrently encapsulating the two main aspects of such diversity: quantity and dissimilarity. To address this quandary, we propose Hamiltonian diversity, a novel molecular diversity metric predicated upon the shortest Hamiltonian circuit. This metric embodies both aspects of molecular diversity in principle, and we implement its calculation with high efficiency and accuracy. Furthermore, through empirical experiments we demonstrate the high consistency of Hamiltonian diversity with real-world chemical diversity, and substantiate its effects in promoting diversity of molecular generation algorithms. Our implementation of Hamiltonian diversity in Python is available at: https://github.com/HXYfighter/HamDiv . Scientific contribution We propose a more rational molecular diversity metric for the community of cheminformatics and drug development. This metric can be applied to evaluation of existing molecular generation methods and enhancing drug design algorithms.

Published

2024

13. Biological Activity of Late Transition Metal‐Based Compounds: From Computational and Theoretical Studies to Laboratory Exploration and Beyond.

Author

Ruwizhi, Ngonidzashe, Singh, Thishana, Omondi, Bernard O., Bala, Muhammad D., and Keramidas, Anastasios

Subjects

*COMPUTER-assisted drug design, *DRUG discovery, *DRUG design, *MOLECULAR docking, *DENSITY functional theory

Abstract

The use of metal compounds such as cisplatin and its derivatives as therapeutic and diagnostic agents against various diseases is well established. Although metallodrugs have been very successful clinically, low therapeutic selectivity and the potential toxicity of the metal compounds mandate the need for a continuous search for more efficient and specific treatments. Hence, the use of computer‐aided drug design (CADD), molecular modelling and theoretical studies in designing, selecting and applying potential drug candidates have become ever more necessary. Among the many computational and theoretical techniques, molecular docking and density functional theory play significant roles in predicting drug activity. Recent methodologies, within the past 5 years, that rely on these techniques to advance the adoption of potential metallodrugs are highlighted and thoroughly discussed. This is because advancements in computing power have led to the wide use of CADD approaches for drug discovery, development and analysis to shorten the time and reduce the costs associated with drug discovery. [ABSTRACT FROM AUTHOR]

Published

2024

14. WWAD: the most comprehensive small molecule World Wide Approved Drug database of therapeutics.

Author

Savosina, Polina, Druzhilovskiy, Dmitry, Filimonov, Dmitry, and Poroikov, Vladimir

Subjects

MACHINE learning, HOMEOPATHIC agents, CYTOCHROME P-450 CYP3A, ANTIHISTAMINES, COMPUTER-assisted drug design, HISTAMINE receptors

Abstract

The article discusses the creation of the World Wide Approved Drug (WWAD) database, which aims to provide comprehensive information on medicines approved for therapeutic use worldwide. The database collects data from National Medicine Registers (NMRs) and official documentation from medicines regulatory authorities (MRAs) of different countries. The article emphasizes the need for a unified resource that aggregates information on worldwide approved medicines and highlights the challenges in accessing and processing this data. The World Wide Approved Drugs (WWAD) database is a comprehensive resource that provides information on low molecular weight pharmaceutical substances from 71 countries and regions. It includes data on drug names, chemical structures, therapeutic indications, molecular targets, and biological activities. The database can be used for various purposes, including searching for information on approved drugs, drug repositioning, data enrichment, and assessing the novelty of investigated compounds. The WWAD database is freely available for academic use through the Way2Drug platform. This document contains a list of references and citations from various scientific articles and databases related to topics such as computational chemistry, drug discovery, drug repurposing, and regulatory approval of drugs. The references cover a range of subjects including the use of artificial intelligence and machine learning in drug discovery, the development of databases for drug repurposing, and the analysis of drug approvals by regulatory agencies. The document provides a comprehensive list of sources that library patrons can use to further their research on these topics. [Extracted from the article]

Published

2024

15. Structure-Aided Computational Design of Triazole-Based Targeted Covalent Inhibitors of Cruzipain.

Author

Cerutti, Juan Pablo, Diniz, Lucas Abreu, Santos, Viviane Corrêa, Vilchez Larrea, Salomé Catalina, Alonso, Guillermo Daniel, Ferreira, Rafaela Salgado, Dehaen, Wim, and Quevedo, Mario Alfredo

Subjects

*COMPUTER-assisted drug design, *CHAGAS' disease, *GENETIC translation, *TRIAZOLE derivatives, *MOLECULAR docking

Abstract

Cruzipain (CZP), the major cysteine protease present in T. cruzi, the ethiological agent of Chagas disease, has attracted particular attention as a therapeutic target for the development of targeted covalent inhibitors (TCI). The vast chemical space associated with the enormous molecular diversity feasible to explore by means of modern synthetic approaches allows the design of CZP inhibitors capable of exhibiting not only an efficient enzyme inhibition but also an adequate translation to anti-T. cruzi activity. In this work, a computer-aided design strategy was developed to combinatorially construct and screen large libraries of 1,4-disubstituted 1,2,3-triazole analogues, further identifying a selected set of candidates for advancement towards synthetic and biological activity evaluation stages. In this way, a virtual molecular library comprising more than 75 thousand diverse and synthetically feasible analogues was studied by means of molecular docking and molecular dynamic simulations in the search of potential TCI of CZP, guiding the synthetic efforts towards a subset of 48 candidates. These were synthesized by applying a Cu(I)-catalyzed azide-alkyne cycloaddition (CuAAC) centered synthetic scheme, resulting in moderate to good yields and leading to the identification of 12 hits selectively inhibiting CZP activity with IC50 in the low micromolar range. Furthermore, four triazole derivatives showed good anti-T. cruzi inhibition when studied at 50 μ M; and Ald-6 excelled for its high antitrypanocidal activity and low cytotoxicity, exhibiting complete in vitro biological activity translation from CZP to T. cruzi. Overall, not only Ald-6 merits further advancement to preclinical in vivo studies, but these findings also shed light on a valuable chemical space where molecular diversity might be explored in the search for efficient triazole-based antichagasic agents. [ABSTRACT FROM AUTHOR]

Published

2024

16. Implementing novel expert systems in the design of personalized paediatric pyridoxine hydrochloride orodispersible tablets.

Author

SALIM, Ilyasu, KHALID, Garba Mohammed, WADA, Abubakar Sadiq, DANLADI, Suleiman, KURFI, Fatima Shuaibu, and GWARZO, Mahmud Sani

Subjects

*COMPUTER-assisted drug design, *EXPERT systems, *RELIABILITY in engineering, *VITAMIN B6, *INFRARED spectroscopy

Abstract

This research implements a computer-aided formulation development algorithm based on a novel SeDeM-ODT expert system in establishing the design space for paediatric pyridoxine hydrochloride orodispersible tablets (ODTs) using Prosolv® ODTG2, Prosolv® EasyTab SP, and Ludiflash® systems. For each formulation ingredient, expert system-defined preformulation parameter values were experimentally determined according to standardized methods and then normalized to the theoretical radius range [0,10]. Expert diagrams were constructed and the quantitative performance of each ingredient was evaluated using parametric profile index (IPP), flowability (ff'), and compressibility (ffc) functions. The net direct compression capability was quantitatively expressed as the product of expert system reliability and IPP. Direct compression was conducted in an eccentric tablet press and properties were evaluated using weight, dimension, disintegration test, contact angle, tensile strength, x-ray diffraction, and Fourier-transform infrared spectroscopy. The ODTs dissolution profiles were fitted and compared using zero-order, first-order, Hixson-Crowell, and Hopfenberg models. Results of the expert diagram of pyridoxine hydrochloride indicated suboptimal normalized radii values in 8 out of 12 parameters, implying a compromised mechanical zone (ff'=3.61, ffc=2.11). By setting a target ffc for the optimized formulation mix at 5.0, the predicted proportions of the fillers to remedy the direct compression deficits of the drug were computed as 89.00%, 83.23%, and 76.62% for Prosolv® ODTG2 (ffc=5.36), Prosolv® EasyTab SP (ffc=5.58), and Ludiflash® (ffc=5.88), respectively. The produced ODTs were of acceptable target quality, hence the SeDeM-ODT system was considered a reliable formulation tool for establishing the design space of this particular drug-filler systems. [ABSTRACT FROM AUTHOR]

Published

2024

17. New dynamic scoring method for deep evaluation of naloxegol as β-tubulin binding inhibitor.

Author

Sheikh, Hamdullah Khadim, Padron, Jose M., Arshad, Tanzila, Habib, Uzma, Jamil, Shahnila, Khan, Haroon, and Ayub, Khurshid

Abstract

We report a new scoring method for rating the performance of ligands on same protein, using their extensive dynamic flexibility properties, binding with protein, and impact on receptor protein. Based on molecular dynamics (MD), this method is more accurate than single-point energy calculations. This method identified an ideal FDA-approved drug as β-tubulin microtubule inhibitor with improved attributes compared to commercial microtubule disassembly inhibitor, Paclitaxel (PTX). We started with virtual screening (VS) of FDA-approved drugs inside PTX's binding pocket (A) of human β-tubulin protein. Screened ligands (>80% score) were evaluated for non-permeation through blood-brain barrier (BBB) as targets were body cancers, gastrointestinal absorption, Lipinski, non-efflux from central nervous system (CNS) by p-glycoprotein (Pgp) and ADMET analysis. This identified FDA-approved Naloxegol drug with superior attributes compared to PTX. Pocket (A) specific docking of chain length variable derivatives of Naloxegol gave docked poses that underwent MD run to give a range of properties and their descriptors (RMSD, RMSF, RoG, H-bonds, hydrophobic interaction, and SASA). QSPR validated that MD properties dependent upon [-CH2-CH2-O-]n=0-7 chain length of Naloxegol. MD data underwent normalization, PCA analysis, and scoring against PTX. One Naloxegol derivative scored higher than PTX as a potential microtubule disassembly inhibitor. [ABSTRACT FROM AUTHOR]

Published

2024

18. Hamiltonian diversity: effectively measuring molecular diversity by shortest Hamiltonian circuits.

Author

Hu, Xiuyuan, Liu, Guoqing, Yao, Quanming, Zhao, Yang, and Zhang, Hao

Subjects

*COMPUTER-assisted drug design, *COMPUTER-assisted molecular design, *DRUG design, *SHORT circuits, *DRUG development

Abstract

In recent years, significant advancements have been made in molecular generation algorithms aimed at facilitating drug development, and molecular diversity holds paramount importance within the realm of molecular generation. Nonetheless, the effective quantification of molecular diversity remains an elusive challenge, as extant metrics exemplified by Richness and Internal Diversity fall short in concurrently encapsulating the two main aspects of such diversity: quantity and dissimilarity. To address this quandary, we propose Hamiltonian diversity, a novel molecular diversity metric predicated upon the shortest Hamiltonian circuit. This metric embodies both aspects of molecular diversity in principle, and we implement its calculation with high efficiency and accuracy. Furthermore, through empirical experiments we demonstrate the high consistency of Hamiltonian diversity with real-world chemical diversity, and substantiate its effects in promoting diversity of molecular generation algorithms. Our implementation of Hamiltonian diversity in Python is available at: https://github.com/HXYfighter/HamDiv. Scientific contribution We propose a more rational molecular diversity metric for the community of cheminformatics and drug development. This metric can be applied to evaluation of existing molecular generation methods and enhancing drug design algorithms. [ABSTRACT FROM AUTHOR]

Published

2024

19. Synthesis and characterization of gold(I) thiolate derivatives and bimetallic complexes for HIV inhibition.

Author

Adokoh, Christian K., Boadu, Akwasi, Asiamah, Isaac, Agoni, Clement, Lameira, Jeronimo, and Ok, Salim

Subjects

*AIDS, *PUBLIC health, *PROTEASE inhibitors, *INFRARED spectroscopy, *PHOSPHINES

Abstract

Introduction: The human immunodeficiency virus (HIV) remains a significant global health concern, with a reported high infection rate of 38.4 million cases globally; an estimated 2 million new infections and approximately 700,000 HIV/ AIDS-related deaths were reported in 2021. Despite the advent of anti-retroviral therapy (ART), HIV/AIDS persists as a chronic disease. To combat this, several studies focus on developing inhibitors targeting various stages of the HIV infection cycle, including HIV-1 protease. This study aims to synthesize and characterize novel glyco diphenylphosphino metal complexes with potential HIV inhibitory properties. Method: A series of new gold(I) thiolate derivatives and three bimetallic complexes, incorporating amino phosphines and thiocarbohydrate as auxiliary ligands, were synthesized using procedures described by Jiang, et al. (2009) and Coetzee et al. (2007). Structural elucidation and purity assessment of the synthesized compounds (1-11) were conducted using micro-analysis, NMR, and infrared spectrometry. Results and Discussion: Using molecular modeling techniques, three of the metal complexes were identified as potential HIV protease inhibitors, exhibiting strong binding affinity interactions with binding pocket residues. These inhibitors demonstrated an ability to inhibit the flexibility of the flap regions of the HIV protease, similar to the known HIV protease inhibitor, darunavir. This study sheds light on the promising avenues for the development of novel therapeutic agents against HIV/AIDS. [ABSTRACT FROM AUTHOR]

Published

2024

20. A computational chemistry-based approach to optimizing PD-1/PD-L1 inhibitors

Author

Meijuan Zhai, Shiliang Ji, Haoran Hu, Yongjie Wu, Yi Shi, Ruifang Zhu, Yiguo Jiang, and Yang Yang

Subjects

non-small cell lung cancer, PD-1 inhibitor, PD-L1 inhibitor, molecular docking, computer-aided drug design, Chemistry, QD1-999

Abstract

IntroductionTo design effective small molecule inhibitors targeting the immune checkpoint PD-1/PD-L1 and to explore their inhibitory activity.MethodsIn this paper, a total of 69 PD-1/PD-L1 inhibitors with the same backbone were searched through opendatabases, and their docking mechanism with PD-L1 protein was investigatedby molecular docking method, and the active conformation of the inhibitors was explored. The biological activity of the four newly designed inhibitors was also evaluated using ELISA.ResultsThe most active molecule 58 in the dataset formed six hydrogen bonds with Phe67, Val55, Ile116 and Tyr123, while the second most active molecule 34 formed five hydrogen bonds with Phe67 and Ala121, both of which formed π-π stacking interactions with Tyr56. The analysis of the inhibitor docking results determined that the residues Tyr123, Gln66, Thr20, Met115, Asp122 and Ile116 had the greatest influence on the active conformation of the inhibitor. ELISA assays suggested that the four novel inhibitors designed had high inhibition rates, with the inhibition rate of compound N2 being as high as 68.53%.DiscussionIn this paper, we have designed and synthesized various PD-1/PDL1 inhibitors, which provide a basis for drug discovery targeting the PD-1/PDL1 signaling pathway.

Published

2025

21. Natural product databases for drug discovery: Features and applications

Author

Tao Zeng, Jiahao Li, and Ruibo Wu

Subjects

Natural products, Database, Drug discovery, Cheminformatics, Computer-aided drug design, Pharmacy and materia medica, RS1-441, Therapeutics. Pharmacology, RM1-950

Abstract

Natural products (NPs) exhibit diverse chemical structures and biological activities that make them valuable sources for drug discovery. With advancements in computational technology, computation-enabled natural drug discovery is gaining increasing significance, with NP databases playing a pivotal role. In light of this, we first summarize the key features of NP databases, including structural data, property annotations, biological sources, biosynthetic pathways, and web interfaces. Subsequently, the wide applications of these databases in drug discovery, such as virtual screening, knowledge graph construction, and molecular generation, are reviewed. We further discuss the puzzle of database development, focusing on data quality and updating. Finally, we emphasize the pivotal role of team collaboration and toolkit innovation in harnessing the immense potential of NP-related databases to accelerate bioactivity mining, structure modification, and manufacturing. This review aims to elucidate the key features and applications of NP databases, with the goal of aiding researchers in developing and maintaining high-quality NP databases for drug discovery.

Published

2024

22. Structure-guided discovery of novel dUTPase inhibitors with anti-Nocardia activity by computational design

Author

Zhi-Zheng Wang, Jun Weng, Jing Qi, Xin-Xin Fu, Ban-Bin Xing, Yang Hu, Chun-Hsiang Huang, Chin-Yu Chen, and Zigong Wei

Subjects

Computer-aided drug design, antibiotics, Nocardia, dUTPase, Therapeutics. Pharmacology, RM1-950

Abstract

The zoonosis caused by Nocardia is increasing seriously. But commonly used antibiotic drugs often lead to resistance. N. seriolae dUTPase (NsdUTPase) plays a key role in the proliferation of Nocardia, and was regarded as a potent drug target. However, there was little report about the NsdUTPase inhibitors. In this study, we discovered a series of novel NsdUTPase inhibitors to fight against Nocardia. The first crystal structure of NsdUTPase was released, and a structure-based computational design was performed. Compounds 4b and 12b exhibited promising activities towards NsdUTPase (IC50 = 0.99 μM and 0.7 μM). In addition, they showed satisfied anti-Nocardia activity (MIC value ranges from 0.5 to 2 mg/L) and low cytotoxicity, which were better than approved drugs oxytetracycline and florfenicol. Molecular modelling study indicated that hydrophobic interaction might be the main contribution for ligand binding. Our results suggested that NsdUTPase inhibitors might be a useful way to repress Nocardia.

Published

2024

23. Using Multiscale Molecular Modeling to Analyze Possible NS2b-NS3 Protease Inhibitors from Philippine Medicinal Plants

Author

Allen Mathew Fortuno Cordero and Arthur A. Gonzales

Subjects

molecular modeling, computer-aided drug design, dengue virus, NS2b-NS3 protease, phytochemicals, Biology (General), QH301-705.5

Abstract

Within the field of Philippine folkloric medicine, the utilization of indigenous plants like Euphorbia hirta (tawa-tawa), Carica papaya (papaya), and Psidium guajava (guava) as potential dengue remedies has gained attention. Yet, limited research exists on their comprehensive effects, particularly their anti-dengue activity. This study screened 2944 phytochemicals from various Philippine plants for anti-dengue activity. Absorption, distribution, metabolism, excretion, and toxicity (ADMET) profiling provided 1265 compounds demonstrating pharmacokinetic profiles suitable for human use. Molecular docking targeting the dengue virus NS2b-NS3 protease’s catalytic triad (Asp 75, Ser 135, and His 51) identified ten ligands with higher docking scores than reference compounds idelalisib and nintedanib. Molecular dynamics simulations confirmed the stability of eight of these ligand–protease complexes. Molecular Mechanics/Poisson–Boltzmann Surface Area (MM/PBSA) analysis highlighted six ligands, including veramiline (−80.682 kJ/mol), cyclobranol (−70.943 kJ/mol), chlorogenin (−63.279 kJ/mol), 25beta-Hydroxyverazine (−61.951 kJ/mol), etiolin (−59.923 kJ/mol), and ecliptalbine (−56.932 kJ/mol) with favorable binding energies, high oral bioavailability, and drug-like properties. This integration of traditional medical knowledge with advanced computational drug discovery methods paves new pathways for the development of treatments for dengue.

Published

2024

24. Leveraging computational tools to combat malaria: assessment and development of new therapeutics

Author

Nomagugu B. Ncube, Matshawandile Tukulula, and Krishna G. Govender

Subjects

Computer-aided drug design, in silico techniques, Machine learning, AI, QSAR, Information technology, T58.5-58.64, Chemistry, QD1-999

Abstract

Abstract As the world grapples with the relentless challenges posed by diseases like malaria, the advent of sophisticated computational tools has emerged as a beacon of hope in the quest for effective treatments. In this study we delve into the strategies behind computational tools encompassing virtual screening, molecular docking, artificial intelligence (AI), and machine learning (ML). We assess their effectiveness and contribution to the progress of malaria treatment. The convergence of these computational strategies, coupled with the ever-increasing power of computing systems, has ushered in a new era of drug discovery, holding immense promise for the eradication of malaria. Scientific contribution Computational tools remain pivotal in drug design and development. They provide a platform for researchers to explore various treatment options and save both time and money in the drug development pipeline. It is imperative to assess computational techniques and monitor their effectiveness in disease control. In this study we examine renown computational tools that have been employed in the battle against malaria, the benefits and challenges these tools have presented, and the potential they hold in the future eradication of the disease.

Published

2024

25. Computer-guided design of novel nitrogen-based heterocyclic sphingosine-1-phosphate (S1P) activators as osteoanabolic agents

Author

Rattanawan Tangporncharoen, Chuleeporn Phanus-Umporn, Supaluk Prachayasittikul, Chanin Nantasenamat, Veda Prachayasittikul, and Aungkura Supokawej

Subjects

sphingosine-1-phosphate activators, quantitative structure-activity relationship, computer-aided drug design, osteoanabolic, quinoxalines, indoles, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282, Biology (General), QH301-705.5

Abstract

Osteoanabolic agents, or drugs that promote bone formation, have gained considerable attention for osteoporosis management due to their curative and preventive potentials. Sphingosine-1-phosphate receptor 2 (S1PR2) is an attractive drug target, in which its activation leads to osteogenesis-promoting effect. Nitrogen-containing heterocyclic scaffolds (i.e., quinoxaline and indole) are promising pharmacophores possessing diverse bioactivities and were reported as S1PR2 activators. Quantitative structure-activity relationship (QSAR) modeling is a computational approach well-known as a fundamental tool for facilitating successful drug development. This study demonstrates the discovery of new S1PR2 activators using computational-driven rational design. Herein, an original dataset of nitrogen-containing S1PR2 activators was collected from ChEMBL database. The retrieved dataset was separated into two datasets according to their core scaffolds (i.e., quinoxaline and indole). QSAR modeling was performed using multiple linear regression (MLR) algorithm to successfully obtain two models with good predictive performance. The constructed models also revealed key properties playing essential roles for potent S1PR2 activation, such as Van der Waals volume (R2v+ and E3v), mass (MATS5m and Km), electronegativity (H3e), and number of 5-membered rings (nR05). Subsequently, the constructed models were further employed to guide rational design and predict S1PR2 activating effects of an additional set of 752 structurally modified compounds. Most of the modified compounds were predicted to have higher potency than their parents, and a set of promising potent newly designed compounds was highlighted. Additionally, drug-likeness prediction was performed to reveal that most of the newly designed compounds are druggable compounds with possibility for further development.

Published

2024

26. Computational approaches for the design of modulators targeting protein-protein interactions

Author

Rehman, Ashfaq Ur, Khurshid, Beenish, Ali, Yasir, Rasheed, Salman, Wadood, Abdul, Ng, Ho-Leung, Chen, Hai-Feng, Wei, Zhiqiang, Luo, Ray, and Zhang, Jian

Subjects

Pharmacology and Pharmaceutical Sciences, Biomedical and Clinical Sciences, Networking and Information Technology R&D (NITRD), Good Health and Well Being, Humans, Protein Binding, Drug Discovery, Proteins, Molecular Dynamics Simulation, Drug Delivery Systems, Computational Biology, Protein-protein interactions, Computer-aided drug design, computational approaches, machine-based learning, molecular dynamics simulations, docking, screening, Pharmacology & Pharmacy, Pharmacology and pharmaceutical sciences

Abstract

BackgroundProtein-protein interactions (PPIs) are intriguing targets for designing novel small-molecule inhibitors. The role of PPIs in various infectious and neurodegenerative disorders makes them potential therapeutic targets . Despite being portrayed as undruggable targets, due to their flat surfaces, disorderedness, and lack of grooves. Recent progresses in computational biology have led researchers to reconsider PPIs in drug discovery.Areas coveredIn this review, we introduce in-silico methods used to identify PPI interfaces and present an in-depth overview of various computational methodologies that are successfully applied to annotate the PPIs. We also discuss several successful case studies that use computational tools to understand PPIs modulation and their key roles in various physiological processes.Expert opinionComputational methods face challenges due to the inherent flexibility of proteins, which makes them expensive, and result in the use of rigid models. This problem becomes more significant in PPIs due to their flexible and flat interfaces. Computational methods like molecular dynamics (MD) simulation and machine learning can integrate the chemical structure data into biochemical and can be used for target identification and modulation. These computational methodologies have been crucial in understanding the structure of PPIs, designing PPI modulators, discovering new drug targets, and predicting treatment outcomes.

Published

2023

27. Applications of artificial intelligence to alchemical free energy calculations in contemporary drug design

Author

Scheen, Jenke, Michel, Julien, Mey, Antonia, and Kirrander, Adam

Subjects

computational chemistry, computer-aided drug design, CADD, AFE science

Abstract

The work presented in this thesis resides at the interface of alchemical free energy methods (AFE) and machine-learning (ML) in the context of computer-aided drug discovery (CADD). The majority of the work consists of explorations into regions of synergy between the individual parts. The overarching hypothesis behind this work is that although areas of high potential exist for standalone ML and AFE in CADD, an additional source of value can be found in areas where ML and AFE are combined in such a way that the new methodology profits from key strengths in either part. Physics-based AFE calculations have - over several decades - grown into precise and accurate sub-kcal·mol−1 (in terms of mean absolute error versus experimental measures) methods of predicting ligand-protein binding affinities which is the main driver of its popularity in project support in drug design workflows. Data-driven ML methods have seen a similar rapid development spurred by the exponential growth in computational hardware capabilities, but are generally still lacking in accuracy versus experimental measures of binding affinities to support drug design work. Contrastingly, however, the first relies mainly on physical rules in the form of statistical mechanics and the latter profits from interpolating signals within large training domains of data. After a historical and theoretical introduction into drug discovery, AFE calculations and ML methods, the thesis will highlight several studies that reflect the above hypothesis along multiple key points in the AFE workflow. Firstly, a methodology that combines AFE with ML has been developed to compute accurate absolute hydration free energies. The hybrid AFE/ML methodology was trained on a subset of the FreeSolv database, and retrospectively shown to outperform most submissions from the SAMPL4 competition. Compared to pure machine-learning approaches, AFE/ML yields more precise estimates of free energies of hydration, and requires a fraction of the training set size to outperform standalone AFE calculations. The ML-derived correction terms are further shown to be transferable to a range of related AFE simulation protocols. The approach may be used to inexpensively improve the accuracy of AFE calculations, and to flag molecules which will benefit the most from bespoke force field parameterisation efforts. Secondly, early investigations into data-driven AFE network generators has been performed. Because AFE calculations make use of alchemical transformations between ligands in congeneric series, practitioners are required to estimate an optimal combination of transformations for each series. AFE networks constitute the collection of edges chosen such that all ligands (nodes) are included in the network and where each edge is a AFE calculation. As there are a vast number of possible configurations for such networks this step in AFE setup suffers from several shortcomings such as scalability and transferability between AFE softwares. Although AFE network generation has been automated in the past, the algorithm depends mostly on expert-driven estimation of AFE transformation reliabilities. This work presents a first iteration of a data-driven alternative to the state-of-the-art using a graph siamese neural network architecture. A novel dataset, RBFE Space, is presented as a representative and transferable training domain for AFE ML research. The workflow presented in this thesis matches state-of-the-art AFE network generation performance with several key benefits. The workflow provides full transferability of the network generator because RBFE-Space is open-sourced and ready to be applied to other AFE softwares. Additionally, the deep learning model represents the first robust ML predictor of transformation reliabilities in AFE calculations. Finally, one major shortcoming of AFE calculations is its decreased reliability for transformations that are larger than ∼5 heavy atoms. The work reported in this thesis describes investigations into whether running charge, Van der Waals and bond parameter transformations individually (with variable λ allocation per step) offers an advantage to transforming all parameters in a single step, as is the current standard in most AFE workflows. Initial results in this work qualitatively suggest that the bound leg benefits from a MultiStep protocol over a onestep ("SoftCore") protocol, whereas the free leg does not show benefit. Further work was performed by Cresset that showed no observable benefit of the MultiStep approach over the Softcore approach. Several key findings are reported in this work that illustrate the benefits of dissecting an FEP approach and comparing the two approaches side-by-side.

Published

2023

28. Insights into the Effects of Ligand Binding on Leucyl-tRNA Synthetase Inhibitors for Tuberculosis: In Silico Analysis and Isothermal Titration Calorimetry Validation.

Author

Rehman, Zia Ur, Najmi, Asim, and Zoghebi, Khalid

Subjects

*ISOTHERMAL titration calorimetry, *TUBERCULOSIS, *MOLECULAR dynamics, *MYCOBACTERIUM tuberculosis, *MITOCHONDRIAL RNA, *GLUTAMINE synthetase

Abstract

Incidences of drug-resistant tuberculosis have become common and are rising at an alarming rate. Aminoacyl t-RNA synthetase has been validated as a newer target against Mycobacterium tuberculosis. Leucyl t-RNA synthetase (LeuRS) is ubiquitously found in all organisms and regulates transcription, protein synthesis, mitochondrial RNA cleavage, and proofreading of matured t-RNA. Leucyl t-RNA synthetase promotes growth and development and is the key enzyme needed for biofilm formation in Mycobacterium. Inhibition of this enzyme could restrict the growth and development of the mycobacterial population. A database consisting of 2734 drug-like molecules was screened against leucyl t-RNA synthetase enzymes through virtual screening. Based on the docking scores and MMGBSA energy values, the top three compounds were selected for molecular dynamics simulation. The druggable nature of the top three hits was confirmed by predicting their pharmacokinetic parameters. The top three hits—compounds 1035 (ZINC000001543916), 1054 (ZINC000001554197), and 2077 (ZINC000008214483)—were evaluated for their binding affinity toward leucyl t-RNA synthetase by an isothermal titration calorimetry study. The inhibitory activity of these compounds was tested against antimycobacterial activity, biofilm formation, and LeuRS gene expression potential. Compound 1054 (Macimorelin) was found to be the most potent molecule, with better antimycobacterial activity, enzyme binding affinity, and significant inhibition of biofilm formation, as well as inhibition of the LeuRS gene expression. Compound 1054, the top hit compound, has the potential to be used as a lead to develop successful leucyl t-RNA synthetase inhibitors. [ABSTRACT FROM AUTHOR]

Published

2024

29. Design, in silico Evaluation, and Determination of Antitumor Activity of Potential Inhibitors Against Protein Kinases: Application to BCR-ABL Tyrosine Kinase.

Author

Koroleva, Elena V., Ermolinskaya, Anastasiya L., Ignatovich, Zhanna V., Kornoushenko, Yury V., Panibrat, Alesia V., Potkin, Vladimir I., and Andrianov, Alexander M.

Subjects

*PROTEIN kinases, *ANTINEOPLASTIC agents, *ACUTE promyelocytic leukemia, *CHRONIC myeloid leukemia, *COMPUTER-assisted drug design, *PROTEIN-tyrosine kinases

Abstract

Despite significant progress made over the past two decades in the treatment of chronic myeloid leukemia (CML), there is still an unmet need for effective and safe agents to treat patients with resistance and intolerance to the drugs used in clinic. In this work, we designed 2-arylaminopyrimidine amides of isoxazole-3-carboxylic acid, assessed in silico their inhibitory potential against Bcr-Abl tyrosine kinase, and determined their antitumor activity in K562 (CML), HL-60 (acute promyelocytic leukemia), and HeLa (cervical cancer) cells. Based on the analysis of computational and experimental data, three compounds with the antitumor activity against K562 and HL-60 cells were identified. The lead compound efficiently suppressed the growth of these cells, as evidenced by the low IC50 values of 2.8 ± 0.8 μM (K562) and 3.5 ± 0.2 μM (HL-60). The obtained compounds represent promising basic structures for the design of novel, effective, and safe anticancer drugs able to inhibit the catalytic activity of Bcr-Abl kinase by blocking the ATP-binding site of the enzyme. [ABSTRACT FROM AUTHOR]

Published

2024

30. Current perspectives and trend of computer-aided drug design: a review and bibliometric analysis.

Author

Zhenhui Wu, Shupeng Chen, Yihao Wang, Fangyang Li, Huanhua Xu, Maoxing Li, Yingjian Zeng, Zhenfeng Wu, and Yue Gao

Abstract

Aim: Computer-aided drug design (CADD) is a drug design technique for computing ligand-receptor interactions and is involved in various stages of drug development. To better grasp the frontiers and hotspots of CADD, we conducted a review analysis through bibliometrics. Methods: A systematic review of studies published between 2000 and 20 July 2023 was conducted following the PRISMA guidelines. Literature on CADD was selected from the Web of Science Core Collection. General information, publications, output trends, countries/regions, institutions, journals, keywords, and influential authors were visually analyzed using software such as Excel, VOSviewer, RStudio, and CiteSpace. Results: A total of 2031 publications were included. These publications primarily originated from 99 countries or regions led by the U.S. and China. Among the contributors, MacKerell AD had the highest number of articles and the greatest influence. The Journal of Medicinal Chemistry was the most cited journal, whereas the Journal of Chemical Information and Modeling had the highest number of publications. Conclusions: Influential authors in the field were identified. Current research shows active collaboration between countries, institutions, and companies. CADD technologies such as homology modeling, pharmacophore modeling, quantitative conformational relationships, molecular docking, molecular dynamics simulation, binding free energy prediction, and high-throughput virtual screening can effectively improve the efficiency of new drug discovery. Artificial intelligence-assisted drug design and screening based on CADD represent key topics that will influence future development. Furthermore, this paper will be helpful in better understanding the frontiers and hotspots of CADD. [ABSTRACT FROM AUTHOR]

Published

2024

31. Understanding the impact of binding free energy and kinetics calculations in modern drug discovery.

Author

Adediwura, Victor A., Koirala, Kushal, Do, Hung N., Wang, Jinan, and Miao, Yinglong

Abstract

For rational drug design, it is crucial to understand the receptor-drug binding processes and mechanisms. A new era for the use of computer simulations in predicting drug-receptor interactions at an atomic level has begun with remarkable advances in supercomputing and methodological breakthroughs. End-point free energy calculation methods such as Molecular Mechanics/Poisson Boltzmann Surface Area (MM/PBSA) or Molecular-Mechanics/Generalized Born Surface Area (MM/GBSA), free energy perturbation (FEP), and thermodynamic integration (TI) are commonly used for binding free energy calculations in drug discovery. In addition, kinetic dissociation and association rate constants (${k_{off}}$ k off and ${k_{on}}$ k on ) play critical roles in the function of drugs. Nowadays, Molecular Dynamics (MD) and enhanced sampling simulations are increasingly being used in drug discovery. Here, the authors provide a review of the computational techniques used in drug binding free energy and kinetics calculations. The applications of computational methods in drug discovery and design are expanding, thanks to improved predictions of the binding free energy and kinetic rates of drug molecules. Recent microsecond-timescale enhanced sampling simulations have made it possible to accurately capture repetitive ligand binding and dissociation, facilitating more efficient and accurate calculations of ligand binding free energy and kinetics. [ABSTRACT FROM AUTHOR]

Published

2024

32. Potential antioxidant, α-glucosidase, butyrylcholinesterase and acetylcholinesterase inhibitory activities of major constituents isolated from Alpinia officinarum hance rhizomes: computational studies and in vitro validation.

Author

Al Garni, H.A., El-Halawany, A.M., Koshak, A.E., Malebari, A.M., Alzain, A.A., Mohamed, G.A., Ibrahim, S.R.M., El-Sayed, N.S., and Abdallah, H.M.

Subjects

*ACETYLCHOLINESTERASE, *GLYCOSIDASE inhibitors, *BUTYRYLCHOLINESTERASE, *ANTIOXIDANTS, *ALPINIA, *CINNAMIC acid, *IN vitro studies, *CHOLINESTERASES

Abstract

Alpinia officinarum is a commonly used spice with proven folk uses in various traditional medicines. In the current study, six compounds were isolated from its rhizomes, compounds 1–3 were identified as diarylheptanoids, while 4–6 were identified as flavonoids and phenolic acids. The isolated compounds were subjected to virtual screening against α-glucosidase, butyrylcholinesterase (BChE), and acetylcholinesterase (AChE) enzymes to evaluate their potential antidiabetic and anti-Alzheimer's activities. Molecular docking and dynamics studies revealed that 3 exhibited a strong binding affinity to human a α- glucosidase crystal structure compared to acarbose. Furthermore, 2 and 5 demonstrated high potency against AChE. The virtual screening results were further supported by in vitro assays, which assessed the compounds' effects on α-glucosidase, cholinesterases, and their antioxidant activities. 5-Hydroxy-7-(4-hydroxy-3-methoxyphenyl)-1-phenylheptan-3-one (2) showed potent antioxidant effect in both ABTs and ORAC assays, while p-hydroxy cinnamic acid (6) was the most potent in the ORAC assay. In contrary, kaempferide (4) and galangin (5) showed the most potent effect in metal chelation assay. 5-Hydroxy-1,7-diphenylhepta-4,6-dien-3-one (3) and 6 revealed the most potent effect as α-glucosidase inhibitors where compound 3 showed more potent effect compared to acarbose. Galangin (5) revealed a higher selectivity to BChE, while 2 showed the most potent activity to (AChE). [ABSTRACT FROM AUTHOR]

Published

2024

33. Leveraging computational tools to combat malaria: assessment and development of new therapeutics.

Author

Ncube, Nomagugu B., Tukulula, Matshawandile, and Govender, Krishna G.

Subjects

*MALARIA, *MOSQUITO nets, *DRUG discovery, *COMPUTER-assisted drug design, *DRUG design, *ARTIFICIAL intelligence, *COMPUTATIONAL neuroscience

Abstract

As the world grapples with the relentless challenges posed by diseases like malaria, the advent of sophisticated computational tools has emerged as a beacon of hope in the quest for effective treatments. In this study we delve into the strategies behind computational tools encompassing virtual screening, molecular docking, artificial intelligence (AI), and machine learning (ML). We assess their effectiveness and contribution to the progress of malaria treatment. The convergence of these computational strategies, coupled with the ever-increasing power of computing systems, has ushered in a new era of drug discovery, holding immense promise for the eradication of malaria. Scientific contribution: Computational tools remain pivotal in drug design and development. They provide a platform for researchers to explore various treatment options and save both time and money in the drug development pipeline. It is imperative to assess computational techniques and monitor their effectiveness in disease control. In this study we examine renown computational tools that have been employed in the battle against malaria, the benefits and challenges these tools have presented, and the potential they hold in the future eradication of the disease. [ABSTRACT FROM AUTHOR]

Published

2024

34. Synthesis, Characterization, Molecular Docking, and Preliminary Antimicrobial Evaluation of Thiazolidinone Derivatives.

Author

Hussein, Sarmad Saadi, Ali, Karima Fadhil, and Al-Saady, Fouad Abdulameer

Subjects

*ANTI-infective agents, *MOLECULAR docking, *STAPHYLOCOCCUS aureus, *FLUCONAZOLE, *CEFTRIAXONE

Abstract

Several derivatives carrying thiazolidine-4-one pharmacophore were prepared to evaluate their antimicrobial activities. The set of compounds were shown to possess potential activities as determined by molecular docking studies for both candidal (14-alpha demethylase) and bacterial enzymes (Penicillin binding protein of E. coli). In vitro antimicrobial activities were also performed to confirm the molecular docking results. Molecular characterization by spectral techniques (FT-IR, 13C NMR and ¹H NMR) was carried out to confirm the identity of the synthesized compounds. The synthesized compounds were evaluated for antibacterial and anticandidal activity by comparing them with the reference drugs (positive controls) ceftriaxone and fluconazole respectively. Four bacterial species (Klebsiella pneumonia, Escherichia coli, Staphylococcus epidermis, Staphylococcus aureus) and one fungal species (Candida albicans) were inoculated into petri dishes and were expose to the synthesized compounds by well diffusion method. The series of the proposed compounds were successfully synthesized and some of them were proven to have antibacterial activities comparable to the reference drug. Particularly, the compounds 2c and 2a posessed activities against K. pneumomia being higher than ceftriaxone with average inhibition zone diameters of 17 mm and 16 mm at highest concentration respectively. Compound 2b was effective against E. Coli also yielding higher activity than ceftriaxone achieving an average diameter of 17 mm at the highest concentration. [ABSTRACT FROM AUTHOR]

Published

2024

35. Identification of Helicobacter pylori‐carcinogenic TNF‐alpha‐inducing protein inhibitors via daidzein derivatives through computational approaches.

Author

Tayyeb, Jehad Zuhair, Mondal, Shibam, Anisur Rahman, Md, Kumar, Swapon, Bayıl, Imren, Akash, Shopnil, Hossain, Md. Sarowar, Alqahtani, Taha, Zaki, Magdi E. A., and Oliveira, Jonas Ivan Nobre

Subjects

DAIDZEIN, MOLECULAR dynamics, DRUG resistance in cancer cells, HELICOBACTER, HELICOBACTER pylori, PROTEIN binding

Abstract

Gastric cancer is considered a class 1 carcinogen that is closely linked to infection with Helicobacter pylori (H. pylori), which affects over 1 million people each year. However, the major challenge to fight against H. pylori and its associated gastric cancer due to drug resistance. This research gap had led our research team to investigate a potential drug candidate targeting the Helicobacter pylori‐carcinogenic TNF‐alpha‐inducing protein. In this study, a total of 45 daidzein derivatives were investigated and the best 10 molecules were comprehensively investigated using in silico approaches for drug development, namely pass prediction, quantum calculations, molecular docking, molecular dynamics simulations, Lipinski rule evaluation, and prediction of pharmacokinetics. The molecular docking study was performed to evaluate the binding affinity between the target protein and the ligands. In addition, the stability of ligand–protein complexes was investigated by molecular dynamics simulations. Various parameters were analysed, including root‐mean‐square deviation (RMSD), root‐mean‐square fluctuation (RMSF), radius of gyration (Rg), hydrogen bond analysis, principal component analysis (PCA) and dynamic cross‐correlation matrix (DCCM). The results has confirmed that the ligand–protein complex CID: 129661094 (07) and 129664277 (08) formed stable interactions with the target protein. It was also found that CID: 129661094 (07) has greater hydrogen bond occupancy and stability, while the ligand–protein complex CID 129664277 (08) has greater conformational flexibility. Principal component analysis revealed that the ligand–protein complex CID: 129661094 (07) is more compact and stable. Hydrogen bond analysis revealed favourable interactions with the reported amino acid residues. Overall, this study suggests that daidzein derivatives in particular show promise as potential inhibitors of H. pylori. [ABSTRACT FROM AUTHOR]

Published

2024

36. WWAD: the most comprehensive small molecule World Wide Approved Drug database of therapeutics

Author

Polina Savosina, Dmitry Druzhilovskiy, Dmitry Filimonov, and Vladimir Poroikov

Subjects

approved drugs database, cheminformatics, computer-aided drug design, unified resource, World Wide Approved Drugs (WWAD), Therapeutics. Pharmacology, RM1-950

Published

2024

37. Bioinformatics investigation of the effect of volatile and non-volatile compounds of rhizobacteria in inhibiting late embryogenesis abundant protein that induces drought tolerance

Author

Etminani Faegheh, Fazeli-Nasab Bahman, Gowtham Hittanahallikoppal Gajendramurthy, Mirzaei Ali Reza, Barasarathi Jayanthi, and Sayyed Riyaz Z.

Subjects

computer-aided drug design, molecular docking, pharmacokinetic, virtual screening, Agriculture, Agriculture (General), S1-972

Abstract

Drought is a major problem worldwide for agriculture, horticulture, and forestry. In many cases, major physiological and biochemical changes occur due to drought stress. The plant’s response to drought stress includes a set of systems for intracellular regulation of gene expression and inter-tissue and inter-organ signaling, which ultimately leads to increased stress tolerance. Meanwhile, the role of plant growth-promoting bacteria in improving many harmful consequences of drought stress has been discussed. One of the new ways to increase tolerance to drought stress in plants is drug design using methods based on computer analysis, bioinformatics, pharmacokinetics, and molecular docking. The present study aimed to identify volatile and non-volatile compounds involved in drought tolerance using molecular docking methods. In this research, among the volatile and non-volatile compounds effective in increasing growth and inducing drought tolerance, compounds that have a high affinity for interacting with the active site of late embryogenesis abundant (LEA) protein were identified through molecular docking methods, and it was presented as a suitable inhibitor for this protein. Based on the docking results, the inhibition potentials of the studied compounds differed, and the most vital interaction in the case of LEA 3 protein was related to the gibberellic acid compound, whose energy is equivalent to −7.78 kcal/mol. Due to the basic understanding of many mechanisms operating in the interactions of plants and bacteria, it is expected that the practical use of these compounds will grow significantly in the coming years, relying on pharmacokinetic methods and molecular docking.

Published

2024

38. Computational Drug Design Approaches for the Identification of Novel Antidiabetic Compounds from Natural Resources through Molecular Docking, ADMET, and Toxicological Studies

Author

Akter, Bakul, Uddin, Md. Sohorab, Islam, Mohammad Rashedul, Ahamed, Kutub Uddin, Aktar, Most. Nazmin, Hossain, Mohammed Kamrul, Salamatullah, Ahmad Mohammad, and Bourhia, Mouhammed

Published

2024

39. The importance of in-silico studies in drug discovery

Author

Roney, Miah and Mohd Aluwi, Mohd Fadhlizil Fasihi

Published

2024

40. Teaching old docks new tricks with machine learning enhanced ensemble docking

Author

Bhatt, Roshni, Wang, Ann, and Durrant, Jacob D.

Published

2024

41. Design, synthesis, and anti-tumor activity of derivatives of ring A and C-28 of asiatic acid.

Author

Yan-Qiu, Meng, Meng, Bei-Bei, Xu, Dong-Ping, Wang, Zhi-Qi, Li, Jin-Ming, and Huang, Mei-Qi

Subjects

*CLINICAL drug trials, *COMPUTER-assisted molecular modeling, *COMPUTER-aided design, *ANTINEOPLASTIC agents, *CELL proliferation, *HYDROCARBONS, *CELL lines, *DRUG design, *MOLECULAR structure

Abstract

Based on computer-aided drug design (CADD), the active groups of the known active small molecule compounds that can bind to EGFR target protein were analyzed through the molecular docking method. Then, 12 novel asiatic acid derivatives were synthesized by introducing active groups at ring A and C-28 positions of asiatic acid. The structures of these novel compounds were determined by NMR and MS. Furthermore, the anti-tumor activities of these derivatives on human lung cancer cells (A549) and human breast cancer cells (MCF-7) were evaluated by MTT assay. In conclusion, compounds I4 and II3 have stronger anti-cancer activity than parent compounds, the activities were stronger than gefitinib and comparable to afatinib, which may be potential candidate compounds for tumor therapy. [ABSTRACT FROM AUTHOR]

Published

2024

42. In silico drug design strategies for discovering novel tuberculosis therapeutics.

Author

Canales, Christian S. Carnero, Pavan, Aline Renata, dos Santos, Jean Leandro, and Pavan, Fernando Rogério

Abstract

Tuberculosis remains a significant concern in global public health due to its intricate biology and propensity for developing antibiotic resistance. Discovering new drugs is a protracted and expensive endeavor, often spanning over a decade and incurring costs in the billions. However, computer-aided drug design (CADD) has surfaced as a nimbler and more cost-effective alternative. CADD tools enable us to decipher the interactions between therapeutic targets and novel drugs, making them invaluable in the quest for new tuberculosis treatments. In this review, the authors explore recent advancements in tuberculosis drug discovery enabled by in silico tools. The main objectives of this review article are to highlight emerging drug candidates identified through in silico methods and to provide an update on the therapeutic targets associated with Mycobacterium tuberculosis. These in silico methods have not only streamlined the drug discovery process but also opened up new horizons for finding novel drug candidates and repositioning existing ones. The continued advancements in these fields hold great promise for more efficient, ethical, and successful drug development in the future. [ABSTRACT FROM AUTHOR]

Published

2024

43. Prediction of probability distributions of molecular properties: towards more efficient virtual screening and better understanding of compound representations.

Author

Duda, Jarosław and Podlewska, Sabina

Abstract

Various in silico approaches to predict activity and properties of chemical compounds constitute nowadays the basis of computer-aided drug design. While there is a general focus on the predictions of values, mathematically more appropriate is the prognosis of probability distributions, which offers additional possibilities, such as the evaluation of uncertainty, higher moments, and quantiles. In this study, we applied the Hierarchical Correlation Reconstruction approach to assess several ADMET properties of chemical compounds. It uses multiple linear regression to independently assess multiple moments, which are then finally combined into predicted probability distribution. The method enables inexpensive selection of compounds with properties nearly certain to fall into the particular range during virtual screening and automatic rejection of predictions characterized by high rate of uncertainty; however, unlike to the currently used virtual screening methods, it focuses on the prediction of the property distribution, not its actual value. Moreover, the presented protocol enables detection of structural features, which should be carefully considered when optimizing compounds towards particular property, as well as it provides deeper understanding of the examined compound representations. [ABSTRACT FROM AUTHOR]

Published

2024

44. Comparative molecular docking and toxicity between carbon-capped metal oxide nanoparticles and standard drugs in cancer and bacterial infections.

Author

Mohammadjani, Navid, Karimi, Sahand, Moetasam Zorab, Musa, Ashengroph, Morahem, and Alavi, Mehran

Subjects

*METAL nanoparticles, *MOLECULAR docking, *DRUG standards, *METALLIC oxides, *BACTERIAL diseases

Abstract

Introduction: Nanoparticles (NPs) are of great interest in the design of various drugs due to their high surface-to-volume ratio, which result from their unique physicochemical properties. Because of the importance of examining the interactions between newly designed particles with different targets in the case of various diseases, techniques for examining the interactions between these particles with different targets, many of which are proteins, are now very common. Methods: In this study, the interactions between metal oxide nanoparticles (MONPs) covered with a carbon layer (Ag2O3, CdO, CuO, Fe2O3, FeO, MgO, MnO, and ZnO NPs) and standard drugs related to the targets of Cancer and bacterial infections were investigated using the molecular docking technique with AutoDock 4.2.6 software tool. Finally, the PRO TOX-II online tool was used to compare the toxicity (LD50) and molecular weight of these MONPs to standard drugs. Results: According to the data obtained from the semi flexible molecular docking process, MgO and Fe2O3 NPs performed better than standard drugs in several cases. MONPs typically have a lower 50% lethal dose (LD50) and a higher molecular weight than standard drugs. MONPs have shown a minor difference in binding energy for different targets in three diseases, which probably can be attributed to the specific physicochemical and pharmacophoric properties of MONPs. Conclusion: The toxicity of MONPs is one of the major challenges in the development of drugs based on them. According to the results of these molecular docking studies, MgO and Fe2O3 NPs had the highest efficiency among the investigated MONPs. [ABSTRACT FROM AUTHOR]

Published

2024

45. Unveiling Novel Urease Inhibitors for Helicobacter pylori : A Multi-Methodological Approach from Virtual Screening and ADME to Molecular Dynamics Simulations.

Author

Valenzuela-Hormazabal, Paulina, Sepúlveda, Romina V., Alegría-Arcos, Melissa, Valdés-Muñoz, Elizabeth, Rojas-Pérez, Víctor, González-Bonet, Ileana, Suardíaz, Reynier, Galarza, Christian, Morales, Natalia, Leddermann, Verónica, Castro, Ricardo I., Benso, Bruna, Urra, Gabriela, Hernández-Rodríguez, Erix W., and Bustos, Daniel

Subjects

*MOLECULAR dynamics, *HELICOBACTER pylori, *UREASE, *SMALL molecules, *COMPUTER-assisted drug design

Abstract

Helicobacter pylori (Hp) infections pose a global health challenge demanding innovative therapeutic strategies by which to eradicate them. Urease, a key Hp virulence factor hydrolyzes urea, facilitating bacterial survival in the acidic gastric environment. In this study, a multi-methodological approach combining pharmacophore- and structure-based virtual screening, molecular dynamics simulations, and MM-GBSA calculations was employed to identify novel inhibitors for Hp urease (HpU). A refined dataset of 8,271,505 small molecules from the ZINC15 database underwent pharmacokinetic and physicochemical filtering, resulting in 16% of compounds for pharmacophore-based virtual screening. Molecular docking simulations were performed in successive stages, utilizing HTVS, SP, and XP algorithms. Subsequent energetic re-scoring with MM-GBSA identified promising candidates interacting with distinct urease variants. Lys219, a residue critical for urea catalysis at the urease binding site, can manifest in two forms, neutral (LYN) or carbamylated (KCX). Notably, the evaluated molecules demonstrated different interaction and energetic patterns in both protein variants. Further evaluation through ADMET predictions highlighted compounds with favorable pharmacological profiles, leading to the identification of 15 candidates. Molecular dynamics simulations revealed comparable structural stability to the control DJM, with candidates 5, 8 and 12 (CA5, CA8, and CA12, respectively) exhibiting the lowest binding free energies. These inhibitors suggest a chelating capacity that is crucial for urease inhibition. The analysis underscores the potential of CA5, CA8, and CA12 as novel HpU inhibitors. Finally, we compare our candidates with the chemical space of urease inhibitors finding physicochemical similarities with potent agents such as thiourea. [ABSTRACT FROM AUTHOR]

Published

2024

46. A Hands-On Collaboration-Ready Single- or Interdisciplinary Computational Exercise in Molecular Recognition and Drug Design.

Author

Allen, Patrick, Nguyen, Nguyet, Humphrey, Nicholas D., Mao, Jia, Chavez-Bonilla, Daniel, and Sorin, Eric J.

Subjects

DRUG design, COMPUTER-assisted drug design, MOLECULAR recognition, COLLEGE curriculum, PHYSICAL & theoretical chemistry, SUFFERING

Abstract

Molecular docking plays an increasingly necessary role in interdisciplinary research, particularly in modern drug design. Pharmaceutical companies compose a trillion dollar per year industry and the public is generally unaware of how beneficial pharmaceutics come to be. Despite this increasing relevance in contemporary research, docking and, by extension, computational science, have been under-represented in undergraduate education in the chemical, biochemical, and biophysical sciences. We describe herein how a multidisciplinary approach is used to design novel inhibitors of the butyrylcholinesterase enzyme (BChE), an upregulated protein in patients suffering from Alzheimer's disease. Students will then be able to compare their designed inhibitors to known BChE inhibitors via molecular docking using this easily adapted hands-on computational laboratory exercise or at-home activity that provides users with a module in which to learn the fundamentals of computer-aided drug design. While being well suited for upper-division courses in biology/biochemistry and physics/physical chemistry, the accessibility of this module allows for its incorporation into college curricula as early as second-term organic chemistry. Highly portable freeware makes this an ideal learning tool by which to infuse single- or multidisciplinary drug design reasoning into college level curricula at no cost to the student or instructor. [ABSTRACT FROM AUTHOR]

Published

2024

47. Synthesis and characterization of gold(I) thiolate derivatives and bimetallic complexes for HIV inhibition

Author

Christian K. Adokoh, Akwasi Boadu, Isaac Asiamah, and Clement Agoni

Subjects

anti-retroviral treatments, computer-aided drug design, gold(I) thiolate derivatives, bimetallic complexes, molecular docking, molecular dynamics, Chemistry, QD1-999

Abstract

Introduction: The human immunodeficiency virus (HIV) remains a significant global health concern, with a reported high infection rate of 38.4 million cases globally; an estimated 2 million new infections and approximately 700,000 HIV/AIDS-related deaths were reported in 2021. Despite the advent of anti-retroviral therapy (ART), HIV/AIDS persists as a chronic disease. To combat this, several studies focus on developing inhibitors targeting various stages of the HIV infection cycle, including HIV-1 protease. This study aims to synthesize and characterize novel glyco diphenylphosphino metal complexes with potential HIV inhibitory properties.Method: A series of new gold(I) thiolate derivatives and three bimetallic complexes, incorporating amino phosphines and thiocarbohydrate as auxiliary ligands, were synthesized using procedures described by Jiang, et al. (2009) andCoetzee et al. (2007). Structural elucidation and purity assessment of the synthesized compounds (1–11) were conducted using micro-analysis, NMR, and infrared spectrometry.Results and Discussion: Using molecular modeling techniques, three of the metal complexes were identified as potential HIV protease inhibitors, exhibiting strong binding affinity interactions with binding pocket residues. These inhibitors demonstrated an ability to inhibit the flexibility of the flap regions of the HIV protease, similar to the known HIV protease inhibitor, darunavir. This study sheds light on the promising avenues for the development of novel therapeutic agents against HIV/AIDS.

Published

2024

48. In Silico Estimation of the Safety of Pharmacologically Active Substances Using Machine Learning Methods: A Review

Author

V. V. Poroikov, A. V. Dmitriev, D. S. Druzhilovskiy, S. M. Ivanov, A. A. Lagunin, P. V. Pogodin, A. V. Rudik, P. I. Savosina, O. A. Tarasova, and D. A. Filimonov

Subjects

pharmacologically active substances, safety, in silico studies, structure–activity relationship, sar, computer-aided drug design, machine learning, way2drug, Therapeutics. Pharmacology, RM1-950

Abstract

Scientific relevance. Currently, machine learning (ML) methods are widely used in the research and development of new pharmaceuticals. ML methods are particularly important for assessing the safety of pharmacologically active substances early in the research process because such safety assessments significantly reduce the risk of obtaining negative results in the future.Aim. This study aimed to review the main information and prediction resources that can be used for the assessment of the safety of pharmacologically active substances in silico.Discussion. Novel ML methods can identify the most likely molecular targets for a specific compound to interact with, based on structure–activity relationship analysis. In addition, ML methods can be used to search for potential therapeutic and adverse effects, as well as to study acute and specific toxicity, metabolism, and other pharmacodynamic, pharmacokinetic, and toxicological characteristics of investigational substances. Obtained at early stages of research, this information helps to prioritise areas for experimental testing of biological activity, as well as to identify compounds with a low probability of producing adverse and toxic effects. This review describes free online ML-based information and prediction resources for assessing the safety of pharmacologically active substances using their structural formulas. Special attention is paid to the Russian computational products presented on the Way2Drug platform (https://www.way2drug.com/dr/).Conclusions. Contemporary approaches to the assessment of pharmacologically active substances in silico based on structure–activity relationship analysis using ML methods provide information about various safety characteristics and allow developers to select the most promising candidates for further in-depth preclinical and clinical studies.

Published

2023

49. Structure-Aided Computational Design of Triazole-Based Targeted Covalent Inhibitors of Cruzipain

Author

Juan Pablo Cerutti, Lucas Abreu Diniz, Viviane Corrêa Santos, Salomé Catalina Vilchez Larrea, Guillermo Daniel Alonso, Rafaela Salgado Ferreira, Wim Dehaen, and Mario Alfredo Quevedo

Subjects

Chagas disease, Cruzipain, triazole derivatives, targeted covalent inhibitors, computer-aided drug design, Organic chemistry, QD241-441

Abstract

Cruzipain (CZP), the major cysteine protease present in T. cruzi, the ethiological agent of Chagas disease, has attracted particular attention as a therapeutic target for the development of targeted covalent inhibitors (TCI). The vast chemical space associated with the enormous molecular diversity feasible to explore by means of modern synthetic approaches allows the design of CZP inhibitors capable of exhibiting not only an efficient enzyme inhibition but also an adequate translation to anti-T. cruzi activity. In this work, a computer-aided design strategy was developed to combinatorially construct and screen large libraries of 1,4-disubstituted 1,2,3-triazole analogues, further identifying a selected set of candidates for advancement towards synthetic and biological activity evaluation stages. In this way, a virtual molecular library comprising more than 75 thousand diverse and synthetically feasible analogues was studied by means of molecular docking and molecular dynamic simulations in the search of potential TCI of CZP, guiding the synthetic efforts towards a subset of 48 candidates. These were synthesized by applying a Cu(I)-catalyzed azide-alkyne cycloaddition (CuAAC) centered synthetic scheme, resulting in moderate to good yields and leading to the identification of 12 hits selectively inhibiting CZP activity with IC50 in the low micromolar range. Furthermore, four triazole derivatives showed good anti-T. cruzi inhibition when studied at 50 μM; and Ald-6 excelled for its high antitrypanocidal activity and low cytotoxicity, exhibiting complete in vitro biological activity translation from CZP to T. cruzi. Overall, not only Ald-6 merits further advancement to preclinical in vivo studies, but these findings also shed light on a valuable chemical space where molecular diversity might be explored in the search for efficient triazole-based antichagasic agents.

Published

2024

50. Rapid discovery of a new antifoulant: From in silico studies targeting barnacle chitin synthase to efficacy against barnacle settlement

Author

Zhixuan Wang, Shanshan Yao, Zhaofang Han, Zhuo Li, Zhiwen Wu, Huanhuan Hao, and Danqing Feng

Subjects

Marine biofouling, Computer-aided drug design, Chitin synthase, Marine natural products, Barnacle, Antifoulant, Environmental pollution, TD172-193.5, Environmental sciences, GE1-350

Abstract

Due to the adverse environmental impacts of toxic heavy metal–based antifoulants, the screening of environmentally friendly antifoulants has become important for the development of marine antifouling technology. Compared with the traditional lengthy and costly screening method, computer-aided drug design (CADD) offers a promising and efficient solution that can accelerate the screening process of green antifoulants. In this study, we selected barnacle chitin synthase (CHS, an important enzyme for barnacle settlement and development) as the target protein for docking screening. Three CHS genes were identified in the barnacle Amphibalanus amphitrite, and their encoded proteins were found to share a conserved glycosyltransferase domain. Molecular docking of 31,561 marine natural products with AaCHSs revealed that zoanthamine alkaloids had the best binding affinity (−11.8 to −12.6 kcal/mol) to AaCHSs. Considering that the low abundance of zoanthamine alkaloids in marine organisms would limit their application as antifoulants, a marine fungal–derived natural product, mycoepoxydiene (MED), which has a similar chemical structure to zoanthamine alkaloids and the potential for large-scale production by fermentation, was selected and validated for stable binding to AaCHS2L2 using molecular docking and molecular dynamics simulations. Finally, the efficacy of MED in inhibiting cyprid settlement of A. amphitrite was confirmed by a bioassay that demonstrated an EC50 of 1.97 μg/mL, suggesting its potential as an antifoulant candidate. Our research confirmed the reliability of using AaCHSs as antifouling targets and has provided insights for the efficient discovery of green antifoulants by CADD.

Published

2024