Comprehensive proteomic characterization of urethral stricture disease in the Chinese population.

Background: Male urethral stricture disease (USD) is predominantly characterized by scar formation. There are few effective therapeutic drugs, and comprehensive molecular characterizations of USD formation remain undefined. Methods: The proteomic profiling of twelve scar tissues and five matched normal adjacent tissues (NATs). Proteomic analysis methods were applied to explore the molecular characterizations of USD formation, including uncovering mechanistic pathways and providing novel biomarkers for scar formation. Results: Comparative proteomic analysis showed that the extracellular matrix (ECM) and complement cascade signaling were predominant in scar tissues. COL11A1 and CD248 significantly contributed to the accumulation of ECM components. Our study presented diverse molecular mechanisms of scar formation across different ages and suggested the potential effects of PXK in Age 1 (<45) patients. Furthermore, immune infiltration studies indicated the therapeutic potential of inhibiting the complement system (C4A, C4B) in Age 2 (≥45) patients, providing a potential clinical strategy for USD. Conclusion: This study illustrated the pathogenesis of USD formation and the diverse characteristics of USD patients with different ages, enhancing our understanding of the disease's pathogenesis and providing a valuable resource for USD treatment.

Identification of novel flavin-dependent monooxygenase from Strobilanthes Cusia reveals molecular basis of indoles' biosynthetic logic.

BACKGROUND: Strobilanthes cusia (Nees) Kuntze is a traditional medical plant distributed widely in south China. The indole compounds that originated from the plant are responsible for its pharmacological activities. However, the reason why indole ingredients are accumulated in this herb and how it is biosynthesized has remained largely unknown. RESULTS: In this study, metabolic and transcriptional profiling measurement experiments of different S. cusia organs were carried out to understand the underlying molecular basis of indoles' biosynthetic logic. A metabolic investigation demonstrated that the indoles are primarily accumulated mainly in aerial parts, particularly in leaves. RNA-seq was employed to reveal the organ specific accumulation of indoles in different S. cusia organs. Meanwhile, a flavin-dependent monooxygenase gene (ScFMO1) was found in S. cusia, and it has capacity to produce indoxyl from indole by the fermentation assay. Finally, we assessed the outcomes of transient expression experiment in tobacco and confirmed that ScFMO1 localizes in cytoplasm. CONCLUSIONS: Our results suggest that ScFMO1 plays a key role in biosynthesis of indoles (Indigo, indirubin, indican, etc.), it will be useful for illuminating the molecular basis of the medicinal indoles' biosynthesis and developing strategies for improving their yields.

Newly synthesized phenanthroimidazole derivatives L082 as a safe anti-tumor and anti-injury inflammation bifunctional compound.

Chemotherapy drugs exerts beneficial antitumor activity before and after cancer surgery. Post-injury complications are a potential hazard after surgical tumor resection. Inflammation caused by surgical stress is known to promote the progression of post-injury complications. Recent studies have found that chemotherapy drugs can promote post-injury inflammatory response, leading to increased post-injury complications. Imidazole derivatives have effective anticancer activity. However, the impact of post-operative inflammation caused by imidazole derivatives is unclear. In this study, two novel phenanthroimidazole derivatives (L082 and L142) were synthesized and characterized. These compounds showed significant inhibitory effects on different tumor cells. The compound L082 also inhibited liver cancer in vivo. In addition, L082 played a significant role in inhibiting the accumulation of inflammatory cells and promoting the elimination of inflammatory cells at the incision, which may be related to inhibiting the production of ROS and NO in oxidative and nitric stress. These results suggest that L082 can be used as a bifunctional drug to suppress tumors and reduce post-injury inflammation complications.