Colorectal cancer (CRC) ranks the third most common cancer type in both men and women. Besides the known genetic and epigenetic changes in the gut epithelial cells, we now know that disturbed gut microbes could also contribute to the onset and progression of CRC. Hence, keeping a balanced gut microbiota (GM) has become a novel pursue in the medical field, particularly in the area of gastrointestinal disorders. Gynostemma pentaphyllum (Gp) is a dietary herbal medicine. In our previous study, Gp saponins (GpS) displayed prebiotic and cancer-preventive properties through the modulation of GM in Apc Min/+ mice. However, the specific group(s) of GM links to the health effects of GpS remains unknown. To track down the missing link, we first investigated and found that inoculation with fecal materials from GpS-treated Apc Min/+ mice effectively reduces polyps in Apc Min/+ mice. From the same source of the fecal sample, we successfully isolated 16 bacterial species. Out of the 16 bacteria, Bifidobacterium animalis stands out as the responder to the GpS-growth stimulus. Biochemical and RNAseq analysis demonstrated that GpS enhanced expressions of a wide range of genes encoding biogenesis and metabolic pathways in B. animalis culture. Moreover, we found that colonization of B. animalis markedly reduces the polyp burden in Apc Min/+ mice. These findings reveal a mutualistic interaction between the prebiotic and a probiotic to achieve anticancer and cancer-preventive activities. Our result, for the first time, unveils the anticancer function of B. animalis and extend the probiotic horizon of B. animalis.
Flavonoid represents a significant class of secondary metabolites in Pu-erh tea with benefits to human health. For a rapid and complete discovery of such compounds, we established a data mining workflow that integrates software MS-DIAL, MS-FINDER, and molecular networking analysis. As a result, 181 flavonoids were tentatively annotated including 22 first found in Puerh tea, and two of them were potentially new molecules. The dynamic alteration of these flavonoids during Pu-erh fermentation was further investigated. They all showed a trend of first increasing and then decreasing. Moreover, statistical analysis showed that the first to third pile turnings of the fermentation process had a greater impact on the changes of flavonoids. Partial metabolic pathways were proposed. This study provides a quick and automatic strategy for flavonoid profiling. The temporal dimension of flavonoids during fermentation may serve as a theoretical basis for Pu-erh tea manufacturing technology and study on substance foundation.
Covalent drugs are newly developed and proved to be successful therapies in past decades. However, the pharmacokinetics (PK) and pharmacodynamic (PD) studies of covalent drugs now ignore the drug and metabolite−protein modification. The low abundance of modified proteins also prevents its investigation. Herein, a simple, selective, and sensitive liquid chromatography-mass spectrometry (LC-MS)/MS quantitative method was established based on the mechanism of a drug and its metabolite−protein adducts using osimertinib as an example.Five metabolites with covalent modification potential were identified. The drug and its metabolite−cysteine adducts released from modified proteins by a mixed hydrolysis method were developed to characterize the level of the modified proteins. This turned the quantitative objects from proteins or peptides to small molecules, which increased the sensitivity and throughput of the quantitative approach. Accumulation of protein adducts formed by osimertinib and its metabolites in target organs was observed in vivo and long-lasting modifications were noted. These results interpreted the long duration of the covalent drugs' effect from the perspective of both parent and the metabolites. In addition, the established method could also be applied in blood testing as noninvasive monitoring. This newly developed approach showed great feasibility for PK and PD studies of covalent drugs.
Psoriasis is an inflammatory skin disease, where keratinocytes play pivotal roles in its pathogenesis. We prepared Celastrol Noisome hydrogel (Cel Nio gel) for the treatment of psoriasis and aimed to study its target site as well as the mechanism. Methods: Cel Nio was fabricated with thin-film hydration and sonication, then topically administered to imiquimod (IMQ)-induced psoriasis mice. The concentrations of Cel in the skin, blood and lymphatic system were determined using LC-MS. The anti-psoriasis effect of Cel Nio gel was studied, and the levels of inflammatory cytokines in blood were evaluated by flow cytometry. For the in vitro study, the uptake of Nio by HaCaT cells was quantified with flow cytometry, and the anti-inflammatory effect of Cel on HaCaT cells was detected with qPCR. The expressions of inflammatory factors and Ki-67 in skin were observed by immunofluorescence. Results: Cel Nio possessed a particle size of 133 nm with encapsulation efficacy (EE%) of 83.2%. After topical administration of Cel Nio gel to mice, Cel was mainly accumulated in the skin instead of exposure in blood or lymphatic system, while the levels of inflammatory factors in blood had a significant decline. In addition, the preparation of Nio enhanced the uptake by HaCaT cells, and Cel obviously reduced the mRNA levels of inflammatory cytokines in HaCaT cells. Moreover, Cel Nio gel significantly decreased the expression of inflammatory cytokines and Ki-67 in the skin. Conclusion: Cel Nio gel achieved the anti-psoriatic effect by inhibiting the inflammation and hyperproliferation of keratinocytes in the skin and further suppressing the systemic inflammation, thus could be a novel topical drug delivery system to treat psoriasis with topical and systemic effects.
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