Reduction of 1,2-dicarbonyl compounds and of their N-phenylimine derivatives by sodium cyanide under aprotic conditions

Some aromatic 1,2-dicarbonyl compounds, i.e. 9,10-phenanthrenequinone, acenaphthenequinone and benzil, and their corresponding N-phenyl monoimines, have been reduced, using dry acetonitrile as the solvent, in the presence of sodium cyanide as a reducing agent. Comparative potentiostatic preparative-scale electrolysis is described.     

超氧负离子在生物发光中的作用

活性氧物种和超氧负离子是生物体内的重要物质,本文通过超氧负离子在生物发光反应中的作用,针对几种不同的典型生物发光体系,综述了超氧负离子参与发光反应的相关理论和实验研究进展.     

Parsing disease‐relevant protein modifications from epiphenomena: perspective on the structural basis of SOD1‐mediated ALS

Conformational change and modification of proteins are involved in many cellular functions. However, they can also have adverse effects that are implicated in numerous diseases. How structural change promotes disease is generally not well‐understood. This perspective illustrates how mass spectrometry (MS), followed by toxicological and epidemiological validation, can discover disease‐relevant structural changes and therapeutic strategies. We (with our collaborators) set out to characterize the structural and toxic consequences of disease‐associated mutations and post‐translational modifications (PTMs) of the cytosolic antioxidant protein Cu/Zn‐superoxide dismutase (SOD1). Previous genetic studies discovered >180 different mutations in the SOD1 gene that caused familial (inherited) amyotrophic lateral sclerosis (fALS). Using hydrogen–deuterium exchange with mass spectrometry, we determined that diverse disease‐associated SOD1 mutations cause a common structural defect – perturbation of the SOD1 electrostatic loop. X‐ray crystallographic studies had demonstrated that this leads to protein aggregation through a specific interaction between the electrostatic loop and an exposed beta‐barrel edge strand. Using epidemiology methods, we then determined that decreased SOD1 stability and increased protein aggregation are powerful risk factors for fALS progression, with a combined hazard ratio > 300 (for comparison, a lifetime of smoking is associated with a hazard ratio of ~15 for lung cancer). The resulting structural model of fALS etiology supported the hypothesis that some sporadic ALS (sALS, ~80% of ALS is not associated with a gene defect) could be caused by post‐translational protein modification of wild‐type SOD1. We developed immunocapture antibodies and high sensitivity top‐down MS methods and characterized PTMs of wild‐type SOD1 using human tissue samples. Using global hydrogen–deuterium exchange, X‐ray crystallography and neurotoxicology, we then characterized toxic and protective subsets of SOD1 PTMs. To cap this perspective, we present proof‐of‐concept that post‐translational modification can cause disease. We show that numerous mutations (N➔D; Q➔E), which result in the same chemical structure as the PTM deamidation, cause multiple diseases. Copyright © 2017 John Wiley & Sons, Ltd.     

Absolute quantification of superoxide dismutase in cytosol and mitochondria of mice hepatic cells exposed to mercury by a novel metallomic approach

In the last years, the development of new methods for analyzing accurate and precise individual metalloproteins is of increasing importance, since numerous metalloproteins are excellent biomarkers of oxidative stress and diseases. In that way, methods based on the use of post column isotopic dilution analysis (IDA) or enriched protein standards are required to obtain a sufficient degree of accuracy, precision and high limits of detection. This paper reports the identification and absolute quantification of Cu,Zn-superoxide dismutase (Cu,Zn-SOD) in cytosol and mitochondria from mice hepatic cells using a innovative column switching analytical approach. The method consisted of orthogonal chromatographic systems coupled to inductively coupling plasma-mass spectrometry equipped with a octopole reaction systems (ICP-ORS-MS) and UV detectors: size exclusion fractionation (SEC) of the cytosolic and mitochondrial extracts followed by online anion exchange chromatographic (AEC) separation of Cu/Zn containing species. After purification, Cu,Zn-SOD was identified after tryptic digestion by molecular mass spectrometry (MS). The MS/MS spectrum of a doubly charged peptide was used to obtain the sequence of the protein using the MASCOT searching engine. This optimized methodology reduces the time of analysis and avoids the use of sample preconcentration and clean-up procedures, such as cut-off centrifuged filters, solid phase extraction (SPE), precipitation procedures, off-line fractions insolates, etc. In this sense, the method is robust, reliable and fast with typical chromatographic run time less than 20 min. Precision in terms of relative standard deviation (n = 5) is of 3–5% and detection limits is 0.21 ng Cu g⁻¹.     

竹红菌乙素镁、锌配位聚合物的光物理和光生物性质

竹红菌乙素(HB)能与Mg2+和Zn2+形成重复单元数为5-20的配位聚合物(Mg2+-HB,Zn2+-HB),利用紫外-可见(UV-Vis)吸收光谱,傅里叶变换红外(FTIR)光谱,核磁共振氢谱(1H NMR)对其进行了表征.Mg2+-HB和Zn2+-HB的单重态氧量子产率分别为HB的1.2倍和0.42倍.瞬态吸收实验表明:氧气能够猝灭Mg2+-HB和Zn2+-HB的三重态,其效率可超过96％.系间窜越效率(φT)和将能量传递给氧气并能产生单重态氧的三重态光敏剂的比例(fT△)对HB及其金属配合物的单重态氧量子产率有较大影响.电子自旋共振(EPR)实验结果表明:Mg2+-HB和Zn2+-HB产生半醌负离子自由基的能力较弱,进而降低了Mg2+-HB和Zn2+-HB光敏产生超氧负离子自由基的能力.紫外-可见吸收光谱与小牛胸腺脱氧核糖核酸(CT DNA)熔链温度实验表明:Mg2+-HB和Zn2+-HB可通过静电作用与DNA结合.有氧条件下,Mg2+-HB,HB和Zn2+-HB对小牛胸腺DNA的光敏损伤效率分别为32％,25％和22％.活性氧猝灭实验表明Mg2+-HB主要通过单重态氧光敏损伤DNA.     

紫外可见吸收光谱法研究钴超氧化物歧化酶活性中心钴与组氨酸的相互作用

应用紫外可见吸收光谱研究了钴超氧化物歧化酶在缓冲溶液中与组氨酸的相互作用。发现酶活性中心的Ｃｏ（Ⅱ）在缓冲溶液中可以与外部物质进行交换相互作用。Ｃｏ（Ⅱ）与组氨酸形成络合物并在活性中心与络合物间达成动态平衡。     

X-ray absorption study of Cu,Zn SOD under high pressure

Abstract

We have investigated Cu, Zn Superoxide Dismutase (Cu, Zn SOD) metal sites at high pressure using X-ray absorption. XAS (X-ray Absorption Spectroscopy) gives information on local structure and it is particularly suited to metal site investigation. To the best of our knowledge, this is the first time that protein conformational states have been investigated using the high pressure XAS technique. Cu, Zn SOD catalyses the dismutation of toxic oxygen radicals produced in cells; this reaction occurs at the copper metal site. Structural changes around the copper, induced by pressure, can be directly related to protein substates. Their characterisation is thus important in the understanding of protein activity.

The high-pressure device was a Paris-Edinburgh large volume cell.

Experiments were performed on lyophilised Cu, Zn SOD between 0 and 48 kbar at the copper and zinc K-edges. The two metal local atomic environments have a different behaviour as pressure increases: copper exhibits a more flexible environment; on the contrary, zinc shows small structural modifications. We have identified a state, formed between 3 and 8 kbar, which is stable up to 48 kbar.     

New hydroperoxybriarane diterpenoids from the octocoral Briareum violaceum

A known briarane, brianthein W (1), along with four new hydroperoxybriaranes, briaviolides R–U (2–5), have been obtained from the octocoral Briareum violaceum. The absolute configuration of 1 was determined by X-ray analysis for the first time and the structures of briaranes 2–5 were established by spectroscopic methods. Bioactivity study showed that briarane 3 decreased the production of superoxide anions from human neutrophils.     

Enhanced Peroxymonosulfate Activation by NixCo1-xOOH for Efficient Catalytic Oxidation of Organic Pollutants

Peroxymonosulfate(PMS) has received increasing attention as viable technology for recalcitrant organics removal from polluted waters. Although promising, alternative heterogeneous catalysts with stable structure, strong hydrophilicity, environmental friendliness and excellent catalytic performance are highly desirable to facilitate the wide industrialization of PMS. In this work, Ni doped CoOOH catalyst was employed as PMS activator. Ni dopant had a significant influence on the morphology, structure and catalytic performance of CoOOH. NiojCoo.gOOH exhibited the best catalytic performance. Reaction rate ofNio.2Coo.8OOH was 2, 4, and 4.4 times that of CoOOH, CoFe2O4 and CO3O4, respectively. Moreover, Ni。2C00.8OOH/PMS system had potential application to organic pollutants and displayed a great catalytic activity over a broader pH value(e.g., 4-10). More importantly, Ni doping accelerated the transfonnation of Co(Ⅲ) and Co(Ⅱ) and formed active species CoOH^+ and NiOH^+ which were responsible to the enhancement of PMS activation.OH, SO4^-:O2^- and 1^O2 were detected, indicating both non-radical and radical processes in the Nio.2Coo.8OOH/PMS system. These findings provide a promising alternative to mixed-metal oxyhydroxides catalysts for PMS activation, demonstrating a great potential in environmental remediation and wastewater treatment.