Withanolide Scaffold in Drug Discovery: A Review of Structural Modifications, Structure-Activity Relationships, and Pharmacological Targets

Harsh Bhardwaj; Lalit Mohan; Siddhi Gupta; Sapna Meena; Mahapurush Daiya; Anu Vedi; Shalu Kumar; Raaz K  Maheshwari

doi:10.59436/jsiane.v6i2.8.2583-2093

Authors

Harsh Bhardwaj Department of Chemistry, Shri RK Patni Girls’ College, Kishangarh, Ajmer, Rajasthan, India
Lalit Mohan Department of Zoology, Dayalbagh Educational Institute(Deemed University), Agra, Uttar Pradesh, India
Siddhi Gupta Department of Botany, SBD Govt PG College, Sardarshahar Churu, Rajasthan
Sapna Meena Department of Chemistry, SMBM Govt Girls College, Nagaur, Rajasthan, India
Mahapurush Daiya Department of Botany, Baba Khinwan Das PG College, Sanglia, Sikar, Rajasthan, India
Anu Vedi Department of Biotechnology, Banasthali Vidyapeeth (Deemed University) Niwai, Tonk, Rajasthan
Shalu Kumar Department of Agronomy, ARNI University, Kathgarh, Indora, Kangra, Himachal Pradesh, India
Raaz K Maheshwari Freelance Investigator and Scientific Writer, Jaipur, MDSU-SBRM Govt PG College, Ajmer, Rajasthan, India

DOI:

https://doi.org/10.59436/jsiane.v6i2.8.2583-2093

Keywords:

withanolides; structure–activity relationships; covalent drug discovery; Michael acceptor; steroidal lactone; Withania somnifera

Abstract

Withanolides are C-28 polyoxygenated steroidal lactones that are characterised by a pair of C2-C3 enones and an α,β-unsaturated d-lactone held in fixed space geometry by a rigid ergostane tetracyclic core. The architecture allows specific covalent interaction with nucleophilic cysteine targets in the protein of interest of mechanobiological interest and has been utilised in a polypharmacology profile of anticancer, anti-inflammatory, neuroprotective, and immunomodulatory activities. A pre-existing SAR dataset of significant chemical depth in more than 1,200 natural analogues spread out in 15 genera in the Solanaceae provides a basis that is further extended by emerging semi-synthetic literature. This review critically discusses the medicinal chemistry-based analysis of withanolide scaffold modification as structural changes at the A-ring enone, lactone ring, peripheral hydroxyl positions and C-17 side chain translate into defined biological outcomes at molecular targets of validated structure requirements that are defined as pharmacophoric elements. Cytotoxic, anti-inflammatory and neuroprotective phages, with their structural separability being a key feature, are is the new opportunities in chemoproteomics-mediated target discovery, biosynthetic engineering and targeted covalent drug design

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Withanolide Scaffold in Drug Discovery: A Review of Structural Modifications, Structure-Activity Relationships, and Pharmacological Targets

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