Phenotypic screen identifies the natural product silymarin as a novel anti-inflammatory analgesic.
Daniel M DuBreuilXiaofan LaiKevin ZhuGracesenia ChahyadinataCaroline PernerBrenda M ChiangAshley BattenbergCaroline L SokolBrian J WaingerPublished in: Molecular pain (2023)
Sensory neuron hyperexcitability is a critical driver of pathological pain and can result from axon damage, inflammation, or neuronal stress. G-protein coupled receptor signaling can induce pain amplification by modulating the activation of Trp-family ionotropic receptors and voltage-gated ion channels. Here, we sought to use calcium imaging to identify novel inhibitors of the intracellular pathways that mediate sensory neuron sensitization and lead to hyperexcitability. We identified a novel stimulus cocktail, consisting of the SSTR2 agonist L-054,264 and the S1PR3 agonist CYM5541, that elicits calcium responses in mouse primary sensory neurons in vitro as well as pain and thermal hypersensitivity in mice in vivo . We screened a library of 906 bioactive compounds and identified 24 hits that reduced calcium flux elicited by L-054,264/CYM5541. Among these hits, silymarin, a natural product derived from milk thistle, strongly reduced activation by the stimulation cocktail, as well as by a distinct inflammatory cocktail containing bradykinin and prostaglandin E2. Silymarin had no effect on sensory neuron excitability at baseline, but reduced calcium flux via Orai channels and downstream mediators of phospholipase C signaling. In vivo , silymarin pretreatment blocked development of adjuvant-mediated thermal hypersensitivity, indicating potential use as an anti-inflammatory analgesic.
Keyphrases
- anti inflammatory
- neuropathic pain
- chronic pain
- oxidative stress
- pain management
- spinal cord
- spinal cord injury
- early stage
- drug induced
- high throughput
- metabolic syndrome
- genome wide
- skeletal muscle
- climate change
- risk assessment
- type diabetes
- brain injury
- photodynamic therapy
- transcranial direct current stimulation
- nucleic acid
- heat stress
- single cell
- fluorescence imaging
- wild type