Cu^2+改性g-C3N4光催化剂的光催化性能

本文通过将Cu^2+掺入g-C3N4结构中成功制备了Cu/g-C3N4光催化剂,并进一步优化其光催化性能。同时,采用多种表征方法对Cu/g-C3N4光催化剂的结构、形貌、光学和光电性能进行了分析。X射线衍射(XRD)和X射线光电子能谱(XPS)结果表明制备的光催化剂为Cu/g-C3N4,且Cu的价态为+2。在可见光照射下,研究了不同铜含量的Cu/g-C3N4和gC3N4光催化剂的光催化活性。实验结果表明,Cu/g-C3N4光催化剂的降解能力显著高于纯相的g-C3N4。N2吸附-解吸等温线表明,Cu^2+的引入对g-C3N4的微观结构影响不大,说明光催化活性的提高可能与光生载流子的有效分离有关。因此,Cu/g-C3N4光催化降解RhB和CIP性能的提升可能是由于Cu^2+可以作为电子捕获陷阱从而降低了载流子的复合速率。通过光电测试表明,在g-C3N4中掺入Cu^2+可以降低g-C3N4的电子空穴复合速率,加速电子空穴对的分离,从而提高了其光催化活性。自由基捕获实验和电子自旋共振(ESR)结果表明,超氧自由基(O2·-)、羟基自由基(·OH)和空穴的协同作用提高了Cu/g-C3N4光催化剂的光催化活性。

面向重大需求 引领学科前沿——“脂代谢可塑性调控的分子与细胞机制”重大项目结题综述

国家自然科学基金重大项目“脂代谢可塑性调控的分子与细胞机制”围绕脂代谢可塑性调控的分子与细胞机制这一生理学重大基础科学问题,在分子、细胞和组织器官水平上系统开展研究。阐释了脂代谢可塑性调控过程中感应脂肪酸、葡萄糖和氨基酸等营养物和代谢物的分子机制,揭示了细胞内不同细胞器的形态变化、互作交流和应激响应等在维持脂代谢稳态中的作用机制,发现了多种内分泌因子通过组织器官间交流互作参与机体脂代谢可塑性及其相关生理和病理生理学过程的调控机制。研究结果为肥胖、糖尿病等重大代谢性疾病的临床研究提供了新的理论依据,为我国代谢研究领域培养了一批优秀人才,使我国科学家在国际相关领域的研究中发挥了引领作用。最后,本文概述了脂代谢领域的发展态势以及下一步发展的建议。

ERp44 C160S/C212S mutants regulate IP_(3)R_(1) channel activity

Previous studies have indicated that ERp44 inhibits inositol 1,4,5-trisphosphate(IP3)-induced Ca2+release(IICR)via IP3R1,but the mechanism remains largely unexplored.Using extracellular ATP to induce intracellular calcium transient as an IICR model,Ca2+image,pull down assay,and Western blotting experiments were carried out in the present study.We found that extracellular ATP induced calcium transient via IP3Rs(IICR)and the IICR were markedly decreased in ERp44 overexpressed Hela cells.The inhibitory effect of C160S/C212S but not C29S/T396A/ΔT(331–377)mutants of ERp44 on IICR were significantly decreased compared with ERp44.However,the binding capacity of ERp44 to L3V domain of IP3R1(1L3V)was enhanced by ERp44 C160S/C212S mutation.Taken together,these results suggest that the mutants of ERp44,C160/C212,can more tightly bind to IP3R1 but exhibit a weak inhibition of IP3R1 channel activity in Hela cells.