Deng-Shuang Wu

BACKGROUND: Recent evidences showed that long noncoding RNAs (lncRNAs) are frequently dysregulated and play important roles in various cancers. Clear cell renal cell carcinoma (ccRCC) is one of the leading cause of cancer-related death, largely due to the metastasis of ccRCC. However, the clinical significances and roles of lncRNAs in metastatic ccRCC are still unknown. METHODS: lncRNA expression microarray analysis was performed to search the dysregulated lncRNA in metastatic ccRCC. quantitative real-time PCR was performed to measure the expression of lncRNAs in human ccRCC samples. Gain-of-function and loss-of-function experiments were performed to investigate the biological roles of lncRNAs on ccRCC cell proliferation, migration, invasion and in vivo metastasis. RNA pull-down, RNA immunoprecipitation, chromatin immunoprecipitation, and western blot were performed to explore the molecular mechanisms underlying the functions of lncRNAs. RESULTS: The microarray analysis identified a novel lncRNA termed metastatic renal cell carcinoma-associated transcript 1 (MRCCAT1), which is highly expressed in metastatic ccRCC tissues and associated with the metastatic properties of ccRCC. Multivariate Cox regression analysis revealed that MRCCAT1 is an independent prognostic factor for ccRCC patients. Overexpression of MRCCAT1 promotes ccRCC cells proliferation, migration, and invasion. Depletion of MRCCAT1 inhibites ccRCC cells proliferation, migration, and invasion in vitro, and ccRCC metastasis in vivo. Mechanistically, MRCCAT1 represses NPR3 transcription by recruiting PRC2 to NPR3 promoter, and subsequently activates p38-MAPK signaling pathway. CONCLUSIONS: MRCCAT1 is a critical lncRNA that promotes ccRCC metastasis via inhibiting NPR3 and activating p38-MAPK signaling. Our results imply that MRCCAT1 could serve as a prognostic biomarker and therapeutic target for ccRCC.

Renal tumour-initiating cells (T-ICs) contribute to tumorigenesis, progression and drug resistance of renal cell carcinoma (RCC). However, the underlying mechanism for the propagation of renal T-ICs remains unclear. Here we show that long non-coding RNA lncARSR is upregulated in primary renal T-ICs and associated with a poor prognosis of clear cell RCCs (ccRCC). Knockdown of lncARSR attenuates the self-renewal, tumorigenicity and metastasis of renal T-ICs. Conversely, forced lncARSR expression enhances T-IC properties of RCC cells. Mechanistically, the binding of lncARSR to YAP impedes LATS1-induced YAP phosphorylation and facilitates YAP nuclear translocation. Reciprocally, YAP/TEAD promotes lncARSR transcription, thus forming a feed-forward circuit. The correlation between lncARSR and YAP is validated in a ccRCC cohort, where the combination of these two parameters exhibits improved prognostic accuracy. Our findings indicate that lncARSR plays a critical role in renal T-ICs propagation and may serve as a prognostic biomarker and potential therapeutic target.

Biological tyrosine phosphorylation has become an extensively studied reaction. Little, however, is known of the chemistry involved. The acetylation of the tyrosyl phenolic hydroxyl group by N-acetylimidazole was studied as a model acylation reaction over the pH range 7.5-9.5. The reactivities of tyrosine and 3-fluorotyrosine were compared. The ratio of reactivities, kappa F-Tyr/kappa Tyr, decreases with increasing pH. Extrapolation to the state in which equivalent concentrations of the two derivatives exist indicates that, consistent with Brønsted theory, tyrosine is 17 times more reactive than fluorotyrosine. No reactivity was observed with tetrafluorotyrosine, 3-nitrotyrosine, or 3,5-dinitrotyrosine. A peptide containing fluorotyrosine was synthesized and compared with the tyrosine-containing peptide as a substrate for the insulin receptor/tyrosine kinase. In both the presence and absence of insulin, the tyrosine peptide was phosphorylated with higher Vm and Km values than the fluorotyrosine peptide was. These results suggest that ionization of the tyrosyl hydroxyl group has an effect on both the chemical and enzymatic reactivities of the tyrosyl residue in acylation reactions. A model is suggested in which deprotonation of the acceptor occurs upon binding of the substrate to the kinase and implicates a role for the substrate site microenvironment in defining substrate specificity.