From irreversible to reversible covalent inhibitors: Harnessing the andrographolide scaffold for anti-inflammatory action.

Covalent drugs with prolonged actions often show superior potency, yet integrated strategies for optimizing their structural and electronic features are lacking. Herein, we present our effort directed towards understanding the contribution of chemical reactivity to biological potency to rationally design new covalent inhibitors based on the ent-ladane andrographolide scaffold for anti-inflammatory action. Specifically, a series of andrographolide derivatives comprising various Michael acceptors was developed and their thiol reactivity was assayed under various chemical and biological conditions. The cell-based SAR studies permitted the assessment of the inhibitor efficacy in more complex systems, which were often limited in traditional covalent drug development using isolated proteins or peptides. Our in vitro study identified enone 17 as the most promising candidate which demonstrated potent anti-inflammatory activity and superior safety profiles as compared to the lead compound andrographolide. Its reversibility following a Michael addition reaction with biological thiols resulted in more predictable pharmacological responses. In addition, 17 exhibited good in vivo efficacy at doses as low as 0.3 mg/kg when tested in LPS-induced acute lung injury model. Given a good balance of chemical reactivity and biological potency, enone 17 potentially offers a new therapeutic option based on natural product chemistry for the management of inflammatory conditions.

Anti-malarial drug, artemisinin and its derivatives for the treatment of respiratory diseases.

Artemisinins are sesquiterpene lactones with a peroxide moiety that are isolated from the herb Artemisia annua. It has been used for centuries for the treatment of fever and chills, and has been recently approved for the treatment of malaria due to its endoperoxidase properties. Progressively, research has found that artemisinins displayed multiple pharmacological actions against inflammation, viral infections, and cell and tumour proliferation, making it effective against diseases. Moreover, it has displayed a relatively safe toxicity profile. The use of artemisinins against different respiratory diseases has been investigated in lung cancer models and inflammatory-driven respiratory disorders. These studies revealed the ability of artemisinins in attenuating proliferation, inflammation, invasion, and metastasis, and in inducing apoptosis. Artemisinins can regulate the expression of pro-inflammatory cytokines, nuclear factor-kappa B (NF-κB), matrix metalloproteinases (MMPs), vascular endothelial growth factor (VEGF), promote cell cycle arrest, drive reactive oxygen species (ROS) production and induce Bak or Bax-dependent or independent apoptosis. In this review, we aim to provide a comprehensive update of the current knowledge of the effects of artemisinins in relation to respiratory diseases to identify gaps that need to be filled in the course of repurposing artemisinins for the treatment of respiratory diseases. In addition, we postulate whether artemisinins can also be repurposed for the treatment of COVID-19 given its anti-viral and anti-inflammatory properties.