Elucidation of the key therapeutic targets and potential mechanisms of Andrographolide multi-targets against osteoarthritis via network pharmacological analysis and experimental validation.

OBJECTIVE: Our purpose is to unveil Andrographolide's potential multi-target and multi-mechanism therapeutic effects in treating OA via systematic network pharmacological analysis and cell experimental validation. MATERIALS AND METHODS: Initially, we gathered data from Andrographolide and OA-related databases to obtain information on Andrographolide's biological properties and the targets linked with OA. We developed a bioinformatic network about Andrographolide and OA, whereby we analyzed the network to identify potential therapeutic targets and mechanisms of action of Andrographolide. Subsequently, we used molecular docking to analyze the binding sites of Andrographolide to the target proteins. At the same time, SDF-1 was used to construct an OA cell model to verify the therapeutic effect of Andrographolide on OA and its effect on target proteins. RESULTS: Our experimental results show that Andrographolide has excellent pharmaceutical properties, by Lipinski's rules for drugs, suggesting that this compound can be considered to have a high therapeutic potential in drug development. 233 targets were preliminarily investigated, the mechanisms through which Andrographolide targets OA primarily involve the TNF signaling pathway, PI3K-AKT signaling pathway, IL-17 signaling pathway, and TLR signaling pathway. These mechanisms target OA by influencing immune and inflammatory responses in the joints, regulating apoptosis to prevent chondrocyte death. Finally, TNF-α, STAT3, TP53, IL-6, JUN, IL-1ß, HIF-1α, TGF-ß1, and AKT1 were identified as 9 key targets of Andrographolide anti-OA. In addition, our molecular docking analyzes with cell experimental validation further confirm the network pharmacology results. According to our molecular docking results, Andrographolide can bind to all the hub target proteins and has a good binding ability (binding energy < -5 kcal/mol), with the strongest binding affinity to AKT1 of -9.2 kcal/ mol. The results of cell experiments showed that Andrographolide treatment significantly increased the cell viability and the expression of COL2A1 and ACAN proteins. Moreover, 30 µM Andrographolide significantly reversed SDF-1-induced increases in the protein expression of TNF-α, STAT3, TP53, IL-6, JUN, IL-1ß, HIF-1α, and TGF-ß1, and decreases in the protein expression of AKT1. CONCLUSION: This study provides a comprehensive understanding of the potential therapeutic targets and mechanisms of action of Andrographolide in OA treatment. Our findings suggest that Andrographolide is a promising candidate for drug development in the management of OA.

Licochalcone A: A Potential Multitarget Drug for Alzheimer's Disease Treatment.

Licochalcone A (Lico-A) is a flavonoid compound derived from the root of the Glycyrrhiza species, a plant commonly used in traditional Chinese medicine. While the Glycyrrhiza species has shown promise in treating various diseases such as cancer, obesity, and skin diseases due to its active compounds, the investigation of Licochalcone A's effects on the central nervous system and its potential application in Alzheimer's disease (AD) treatment have garnered significant interest. Studies have reported the neuroprotective effects of Lico-A, suggesting its potential as a multitarget compound. Lico-A acts as a PTP1B inhibitor, enhancing cognitive activity through the BDNF-TrkB pathway and exhibiting inhibitory effects on microglia activation, which enables mitigation of neuroinflammation. Moreover, Lico-A inhibits c-Jun N-terminal kinase 1, a key enzyme involved in tau phosphorylation, and modulates the brain insulin receptor, which plays a role in cognitive processes. Lico-A also acts as an acetylcholinesterase inhibitor, leading to increased levels of the neurotransmitter acetylcholine (Ach) in the brain. This mechanism enhances cognitive capacity in individuals with AD. Finally, Lico-A has shown the ability to reduce amyloid plaques, a hallmark of AD, and exhibits antioxidant properties by activating the nuclear factor erythroid 2-related factor 2 (Nrf2), a key regulator of antioxidant defense mechanisms. In the present review, we discuss the available findings analyzing the potential of Lico-A as a neuroprotective agent. Continued research on Lico-A holds promise for the development of novel treatments for cognitive disorders and neurodegenerative diseases, including AD. Further investigations into its multitarget action and elucidation of underlying mechanisms will contribute to our understanding of its therapeutic potential.

Counteracting antibiotic resistance: breaking barriers among antibacterial strategies.

INTRODUCTION: To fight against antibiotic resistance, prevention-only is no longer an acceptable strategy. The old concept 'one-infection, one-bug, one-drug', genocentrism in antibiotic discovery, and lack of integration between different antimicrobial strategies have probably contributed to current weaknesses in confronting antibiotic resistance. Resistance should be combatted in all fronts simultaneously, in the patient (complex therapy), the group (where resistance is maintained), and the significant environment (polluted by resistance). AREAS COVERED: This paper is reviewing why specific 'therapeutic' approaches are needed in each of these fronts, using different types of 'drugs' directed to a variety of targets, in the goal of inhibiting antibiotic resistant bacteria. Multi-target integrated combination strategies and therapies should be more extensively evaluated, not only in the infected patient (using novel formats for clinical trials), but as associations of 'therapeutic strategies' in the different compartments where antibiotic resistance emerges and flows (measuring global effects in resistance). EXPERT OPINION: Multi-targeted therapeutic approaches require a relaxation of barriers among the various compounds, including systemic and topic antibiotics, antiseptics, biocides, anti-resistant clones vaccination, phages, decontamination products, and in general eco-evo drugs acting on factors influencing ecology and evolution of resistant bacteria. The application of methods of systems biology will facilitate such a multi-lateral attack to antibiotic resistance. Such advances should be paralleled by a simultaneous progress in regulatory sciences and close coordination among all stakeholders.