Study on the preparation and enzyme inhibitory activity of polyphenols from Sargassum pallidum.

This study aimed to obtain a high yield and purity of Sargassum pallidum polyphenol extracts (SPPE) and study its enzyme activity. Fresh Sargassum pallidum seaweed was selected for optimization of ultrasound-assisted extraction (UAE) conditions and purification conditions using macroporous resin and Sephadex LH20 to obtain SPPE. The SPPE was characterized using UPLC-QTOF-MS/MS and α-amylase, α-glucosidase, tyrosinase, and AchE inhibitory activity were determined. The maximum extraction rate of SPPE was 7.56 mg GAE/g and the polyphenol purity reached 70.5% after macroporous resin and Sephadex LH-20 purification. A total of 50 compounds were identified by UPLC-QTOF-MS/MS. The IC50 values of SPPE were 334.9 µg/mL, 6.290 µg /mL, 0.834 mg /mL and 0.6538 mg /mL for α-amylase, α-glucosidase, tyrosinase and AchE, respectively. Molecular docking technology further revealed the effects of SPPE on the above enzymes. This study provided information on the potential hypoglycemic, whitening and anti-Alzheimer's disease biological activities of SPPE, which had guiding significance for the purification and development of other seaweed polyphenols.

Transcription Factor MITF Inhibits the Transcription of CPT1B to Regulate Fatty Acid ß-Oxidation and Thus Affects Stemness in Lung Adenocarcinoma Cells.

INTRODUCTION: Cancer stem cells (CSCs) play critical roles in lung adenocarcinoma (LUAD) progression, and fatty acid oxidation is key for CSC growth and survival. Therefore, investigating the molecular mechanisms regulating fatty acid ß-oxidation in LUAD is important for its treatment. METHODS: Bioinformatics analysis assessed CPT1B and MITF expression and their correlation in LUAD tissues, as well as the pathways enriched by CPT1B. qRT-PCR assessed expression of CPT1B and MITF, while CCK-8 and sphere-forming assays were used to measure cell viability and stemness, respectively. Dual staining detected lipid accumulation, while kits were used to measure fatty acid ß-oxidation and glycerol content. qRT-PCR was used to assay expression of lipid oxidation genes. Western blot was used to examine expression of stem cell-related markers. Dual-luciferase assay and ChIP assay were used to verify the binding relationship between MITF and CPT1B. RESULTS: CPT1B was found to be highly expressed in LUAD and enriched in linoleic acid metabolism pathway and α-linolenic acid metabolism pathway. Functional experiments showed that CPT1B could promote stemness in LUAD cells by regulating fatty acid ß-oxidation. Additionally, CPT1B was found to be regulated by the upstream transcription factor MITF, which was lowly expressed in LUAD and could downregulate CPT1B expression. Rescue experiments revealed that CPT1B/MITF axis could affect stemness in LUAD cells by regulating fatty acid ß-oxidation. CONCLUSION: Transcription factor MITF inhibited transcription of CPT1B to regulate fatty acid ß-oxidation, thereby suppressing stemness in LUAD cells. MITF and CPT1B may become new targets for LUAD.

Development of predictive models for assessing the progression and invasiveness of satellite lesions in patients with multiple pulmonary ground glass nodules.

Background: Currently, the appropriate treatment of satellite lesions is still controversial. With this study, we aimed to construct a set of nomograms to determine the characteristics of satellite lesions in patients with multiple pulmonary ground glass nodules (MPGGNs) and propose a reference for the management of satellite lesions. Methods: We retrospectively analyzed patients with MPGGNs who had undergone multiple rounds of surgical resection of primary and satellite lesions, including pathologic examinations after surgical resection. Results: A total of 125 lesions from 105 patients were included in the analysis; 85 lesions were advanced and 40 lesions were not advanced. Among them, 55 invasive pulmonary adenocarcinomas (IPA) and 70 noninvasive pulmonary adenocarcinomas were identified. After the final regression analysis, the patients' age, satellite lesion location, consolidation tumor ratio (CTR), lesion border clarity, and lesion diameter were used to predict satellite lesion progression. Patients' gender, satellite lesion location, lesion diameter, and computed tomography (CT) attenuation values were used to predict the invasiveness of the satellite lesion. The constructed nomograms showed strong discrimination with concordance indices (C indices) of 0.816 and 0.823, respectively. Conclusions: We developed a set of nomograms that can predict the risk of advanced or invasive satellite lesions in patients with MPGGNs. The area under the receiver operating characteristic (ROC) curve (AUC), the C-index, and the calibration curve suggest that the nomogram may be useful in the clinical setting. This model has the potential to help clinicians make treatment recommendations for the remaining lesions while treating the primary lesion in patients with MPGGNs.