The clustering-triggered emission mechanism guides the rational design of nonaromatic polyurethanes with intrinsic emissions including room-temperature phosphorescence.
Because colorectal cancer (CRC) stem-like cells (CCS-like cells) contribute to poor patient prognosis, these cells are a potential target for CRC therapy. However, the mechanism underlying the maintenance of CCS-like cell properties remains unclear. Here, we found that patients with advanced stage CRC expressed high levels of polycomb group protein enhancer of zeste homologue 2 (EZH2). High expression of EZH2 in tumor tissues correlated with poor patient prognosis. Conversely, silencing EZH2 reduced CRC cell proliferation. Surprisingly, EZH2 was more highly expressed in the CCS-like cell subpopulation than in the non-CCS-like cell subpopulation. EZH2 knockdown significantly reduced the CD133+/CD44+ subpopulation, suppressed mammosphere formation, and decreased the expression of self-renewal-related genes and strongly impaired tumor-initiating capacity in a re-implantation mouse model. Gene expression data from 433 human CRC specimens from TCGA database and in vitro results revealed that EZH2 helped maintain CCS-like cell properties by activating the Wnt/β-catenin pathway. We further revealed that p21cip1–mediated arrest of the cell cycle at G1/S phase is required for EZH2 activation of the Wnt/β-catenin pathway. Moreover, the specific EZH2 inhibitor EPZ-6438, a clinical trial drug, prevented CRC progression. Collectively, these findings revealed EZH2 maintaining CCS-like cell characteristics by arresting the cell cycle at the G1/S phase. These results indicate a new approach to CRC therapy.
Autophagy critically contributes to metabolic reprogramming and chromosomal stability. It has been reported that monoallelic loss of the essential autophagy gene BECN1 (encoding BECN1/Beclin 1) promotes cancer development and progression. However, the mechanism by which BECN1 is inactivated in malignancy remains largely elusive. We have previously reported a tumor suppressor role of ABHD5 (abhydrolase domain containing 5), a co-activator of PNPLA2 (patatin like phospholipase domain containing 2) in colorectal carcinoma (CRC). Here we report a noncanonical role of ABHD5 in regulating autophagy and CRC tumorigenesis. ABHD5 directly competes with CASP3 for binding to the cleavage sites of BECN1, and consequently prevents BECN1 from being cleaved by CASP3. ABHD5 deficiency provides CASP3 an advantage to cleave and inactivate BECN1, thus impairing BECN1-induced autophagic flux and augmenting genomic instability, which subsequently promotes tumorigenesis. Notably, clinical data also confirm that ABHD5 proficiency is significantly correlated with the expression levels of BECN1, LC3-II and CASP3 in human CRC tissues. Our findings suggest that ABHD5 possesses a PNPLA2-independent function in regulating autophagy and tumorigenesis, further establishing the tumor suppressor role of ABHD5, and offering an opportunity to develop new approaches aimed at preventing CRC carcinogenesis.
Novel 3D hierarchical holey (Co, Ni)3S2 nanostructures are fabricated and exhibit outstanding comprehensive performance as electrodes for electrochemical energy storage.
A facile and diversified synthesis of functionalized CF-containing benzoxepine derivatives via photoredox catalysis was achieved in this work. This novel protocol features broad substrate scope, mild reaction conditions, operational simplicity, easy scale-up, and versatile derivatization, which would facilitate its practical and broad applications in the construction of valuable and synthetically challenging heterocycles.
The efficacy of Fluorouracil (FU) in the treatment of colorectal cancer (CRC) is greatly limited by drug resistance. Autophagy has been implicated in chemoresistance, but the role of selective autophagic degradation in regulating chemoresistance remains unknown. In this study, we revealed a critical role of ABHD5 in charging CRC sensitivity to FU via regulating autophagic uracil yield. We demonstrated that ABHD5 localizes to lysosome and interacts with PDIA5 to prevent PDIA5 from interacting with RNASET2 and inactivating RNASET2. ABHD5 deficiency releases PDIA5 to directly interact with RNASET2 and leave RNASET2 in an inactivate state, which impairs RNASET2-mediated autophagic uracil yield and promotes CRC cells to uptake FU as an exogenous uracil, thus increasing their sensitivity to FU. Our findings for the first time reveal a novel role of ABHD5 in regulating lysosome function, highlighting the significance of ABHD5 as a compelling biomarker predicting the sensitivity of CRCs to FU-based chemotherapy.
Berberine, a quaternary ammonium protoberberine alkaloid with an isoquinoline scaffold isolated from medicinal herbs, exhibits a wide spectrum of pharmacological activities. Berberine has been used in traditional Chinese medicine and Ayurvedic medicine. However, it has poor bioavailability, which seriously limits its application and development. The chemical transformation of natural products is an effective method to improve pharmacological activities. Researches have been carried out on the modification of berberine to obtain better pharmacological properties. In this paper, the structural modifications of berberine for different biological activities and its underlying mechanisms are reviewed.
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