The mechanism of Xihuang pills' intervention in the tumour immune microenvironment for the treatment of liver cancer based on the STAT3-PDL1 pathway.

ETHNOPHARMACOLOGICAL RELEVANCE: Xihuang pills, a time-honored Chinese compound formula with a history spanning thousands of years, have demonstrated remarkable efficacy in treating various cancers, such as breast cancer, colon cancer, and liver cancer. Clinical applications over the years have established their effectiveness. Several scholars conducting experimental studies have elucidated the potent tumor-suppressing effects of Xihuang pills. While the inhibition of tumor vascular development and prevention of tumor cell invasion and metastasis have been well-explored mechanisms, the impact on the tumor immune microenvironment has received less attention. This study focuses on investigating the immune microenvironment adjustments induced by Xihuang pills in hepatocellular carcinoma. AIM OF THE STUDY: Tumour cells will find an escape phenomenon during tumour immunotherapy, which will affect immunotherapy results. We will research the regulation of the tumour immune microenvironment, to provide a more complete and precise basis for the elucidation of the mechanism of Xihuang pills in treating cancers. It provides new research ideas for people to treat liver cancer. MATERIALS AND METHODS: Through in vivo and in vitro assessments confirming the intervention effects of Xihuang pills, we observed alterations in T cell typing, macrophage polarization, and tumor-associated cytokine levels. The primary active ingredients of Xihuang pills were identified using UPLC-MS/GC-MS, and relevant pathways in the treatment of hepatocellular carcinoma were predicted through network pharmacology. Combining the network pharmacology approach, we predicted the pathways relevant to Xihuang pills in treating hepatocellular carcinoma and experimentally validated the involvement of PD-1/PD-L1, a key immunity-related axis. RESULTS: Xihuang Pill has a regulatory effect on the tumor immune microenvironment. CONCLUSIONS: The results indicated that Xihuang pills could impact splenic lymphocyte phenotyping, macrophage polarization, and IL-6 cytokine expression in liver cancer mice. The mechanism of action was associated with the regulation of the PD-1/PD-L1 signaling pathway by the STAT3 protein.

The therapeutic potential of Ziziphi Spinosae Semen and Polygalae Radix in insomnia management: Insights from gut microbiota and serum metabolomics techniques.

ETHNOPHARMACOLOGICAL RELEVANCE: Ziziphi Spinosae Semen and Polygalae Radix (ZSS-PR) constitute a traditional Chinese herbal combination with notable applications in clinical and experimental settings due to their evident sedative and calming effects. Aligned with traditional Chinese medicine principles, Ziziphi Spinosae Semen supports cardiovascular health, nourishes the liver, and induces mental tranquillity. Simultaneously, Polygalae Radix elicits calming effects, fosters clear thinking, and reinstates proper coordination between the heart and kidneys. ZSS-PR is commonly employed as a therapeutic intervention for various insomnia types, demonstrating distinct clinical efficacy. Our previous study findings provide evidence that ZSS-PR administration significantly reduces sleep onset latency, increases overall sleep duration, and improves abnormal neurotransmitter levels in a murine insomnia model. AIM OF STUDY: This investigation aimed to scrutinize the intrinsic regulatory mechanism of ZSS-PR in managing insomnia using gut microbiota and serum metabolomics techniques. MATERIALS AND METHODS: Mice were given DL-4-Chlorophenylalanine to induce insomnia and then treated with ZSS-PR. The open-field test assessed the animals' spontaneous activity. Concentrations of neurotransmitters, endocrine hormones, and cytokines in the duodenum were measured using enzyme linked immunosorbent assay, and brain histopathology was evaluated with H&E staining. The impact of ZSS-PR on the metabolic profile was examined by liquid chromatography couped to high resolution mass spectrometry, and 16S rDNA sequencing was used to study the influence of ZSS-PR on the gut microbiota. Additionally, the content of short-chain fatty acids (SCFAs) was analyzed by GC-MS. Finally, correlation analysis investigated relationships between biochemical markers, metabolites, SCFAs, and gut microbiota. RESULTS: ZSS-PR treatment significantly increased movement time and distance in mice with insomnia and improved pathological impairments in the cerebral cortex and hippocampus. It also restored abnormal levels of biochemical markers in the gut of insomnia-afflicted mice, including 5-hydroxytryptamine, dopamine, gastrin, melatonin, tumour necrosis factor-α, and interleukin-1ß. Metabolomics findings showed that ZSS-PR had a significant restorative effect on 15 endogenous metabolites in mice with insomnia. Furthermore, ZSS-PR primarily influenced five metabolic pathways, such as phenylalanine, tyrosine, and tryptophan biosynthesis, glutamine, and glutamate metabolism. Additionally, gut microbiota analysis revealed notable alterations in both diversity and microbial composition after ZSS-PR treatment. These changes were primarily attributed to the relative abundances of microbiota, including Firmicutes, Bacteroidota, Fusobacteriota, Muribaculaceae_unclassified, and Ligilactobacillus. The results of SCFAs analysis demonstrated that ZSS-PR effectively restored abnormal levels of acetic acid, propionic acid, isobutyric acid, butyric acid, isovaleric acid, and valeric acid in insomniac mice. Subsequent correlation analysis revealed that microbiota show obvious correlations with both biochemical markers and metabolites. CONCLUSIONS: The results provide compelling evidence that ZSS-PR effectively mitigates abnormal activity, reduces cerebral pathological changes, and restores abnormal levels of neurotransmitters, endocrine hormones, and cytokines in mice with insomnia. The underlying mechanism is intricately linked to the modulation of gut microbiota and endogenous metabolic pathways.

Serum lipidomics reveal the mechanism of memory disorder improvement by Qifu decoction.

Memory disorder (MD) is a neurodegenerative disease that seriously affects the quality of life of the elderly in China. It is characterized by cognitive deficits and psychiatric symptoms. In addition to oxidative damage, neurotransmitter disorders, and other factors, Ca2+ homeostasis and lipid metabolism are among the major pathways of MD etiology. Studies have shown that Ca2+ influx, causing Ca2+ overload, leads to neuronal apoptosis and alterations in lipid metabolites at all MD stages. Qifu decoction (QFD) is one of the classic compounds for the traditional treatment of dementia, which has been shown to significantly improve MD caused by dementia and Alzheimer's disease (AD). So far, it is not clear whether QFD can regulate Ca2+ homeostasis and lipids to improve MD. In this study, we developed a scopolamine hydrobromide MD mouse model and performed neurobehavioral experiments and examinations of brain tissue pathology, Ca2+ homeostasis-related factor levels, and non-targeted lipidomics to explore the mechanism of QFD action in improving MD. The results showed that four weeks of intragastric administration of QFD resulted in significant increases in the cognitive ability and spatial memory ability of the mice with MD. Furthermore, the damage to nerve cells was reduced, the levels of Ca2+ and CaM in the serum were decreased, whereas the content of CaMKII was increased, and the Ca2+ homeostasis was regulated. Non-targeted lipidomics detected four lipid subclasses and 17 potential differential metabolites. Metabolic pathway analysis revealed that QFD significantly regulated sphingolipid metabolism and improved MD. In summary, QFD improves scopolamine hydrobromide memory impairment in mice by regulating the Ca2+ signaling pathway and sphingolipid metabolism. This study provides new insights into the beneficial mechanism of QFD on MD from the perspective of lipidomics.

Integrated Lipidomics and Network Pharmacology Reveal Mechanism of Memory Impairment Improvement by Yuanzhi San.

Memory impairment (MI) is caused by a variety of causes, endangering human health. Yuanzhi San (YZS) is a common prescription used for the treatment of MI, but its mechanism of action needs further exploration. The purpose of this study was to investigate this mechanism through lipidomics and network pharmacology. Sprague Dawley (SD) rats were divided randomly into the normal, model, and YZS groups. The rats were gavaged with aluminum chloride (200 mg/kg) and intraperitoneally injected with D-galactose (400 mg/kg) every day for 60 days, except for the normal group. From the 30th day, YZS (13.34 g/kg) was gavaged once a day to the rats in the YZS group. Post-YZS treatment, ultra-high-performance liquid chromatography-mass spectrometry (UHPLC/MS) analysis was implemented to conduct a lipidomics study in the hippocampus of rats with memory impairment induced by aluminum chloride and D-galactose. Eight differential metabolites were identified between the normal group and the model group, whereas between the model group and the YZS group, 20 differential metabolites were established. Metabolic pathway analysis was performed on the aforementioned lipid metabolites, all of which were involved in sphingolipid and glycerophospholipid metabolism. Furthermore, serum pharmacochemistry analysis of YZS was carried out at the early stage of our research, which discovered 62 YZS prototype components. The results of the network pharmacology analysis showed that they were related to 1030 genes, and 451 disease genes were related to MI. There were 73 intersections between the YZS and MI targets. Kyoto Encyclopedia of Genes and Genomes (KEGG) analysis showed that these targets were closely related to the sphingolipid metabolic, calcium signaling, and other pathways. The integrated approach of lipidomics and network pharmacology was then focused on four major targets, including PHK2, GBA, SPTLC1, and AChE, as well as their essential metabolites (glucosylceramide, N-acylsphingosine, phosphatidylserine, phosphatidylcholine, and phosphatidylcholine) and pathways (sphingolipid, glycerophospholipid, and arachidonic acid metabolism). The significant affinity of the primary target for YZS was confirmed by molecular docking. The obtained results revealed that the combination of lipidomics and network pharmacology could be used to determine the effect of YZS on the MI biological network and metabolic state, and evaluate the drug efficacy of YZS and its related mechanisms of action.