脲和盐酸胍诱导溶菌酶去折叠的荧光相图法研究

用荧光相图法分别研究了脲和盐酸胍诱导卵清溶菌酶去抓叠的过程。当变性体 系中无还原剂2－巯基乙醇存在、脲浓度从0变化至4.0 mol/L（或盐酸胍浓度从0变 化至3.0 mol/L）时,溶菌酶从天然态转变为部分折叠中间态,当脲浓度从4.0 mol/L变化至8.0 mol/L（或盐酸胍浓度从3.0 mol/L变化至6.0 mol/L）时,溶菌 酶从中间态转变为去折叠态,此时该蛋白的变性过程符合“三态模型”。而当变性 体系中有该还原剂存在时,溶菌酶则由天然态直接转变为去折叠态,此时脲诱导该 蛋白去折叠的过程符合曲型的“二态模型”。实难结果表明荧光相图法可以检测蛋 白南去抓叠的中间态。     

Ca2+与乳清蛋白结合的亲和毛细管电泳研究

利用亲和毛细管电泳研究了Ca²⁺与α-人乳清蛋白(α-HLA)的结合情况.以恒定浓度α-HLA作为受体,运行缓冲溶液加入不同浓度的Ca²⁺作为配体,可观察到由于Ca²⁺的结合,α-HLA的电泳淌度发生了变化.通过Scatchard方程的淌度比(M)处理数据得到α-HLA与Ca²⁺的表观结合常数(K_app)为2.0×107(mol/L)^-1.同时考察了Ca²⁺对变性剂(尿素)和热诱导所引起的α-HLA去折叠的影响,结果表明,Ca²⁺的结合增强了α-HLA的稳定性,也即提高了α-HLA抗变性剂和热诱导的去折叠性能.     

盐酸胍诱导的变性卵清溶菌酶分子重折叠过程及其各稳定构象态的分布和过渡

采用变性和非变性电泳、 高效凝胶排阻色谱、 内源荧光发射光谱和荧光相图以及生物活性测定等方法, 研究了盐酸胍诱导的变性卵清溶菌酶分子的重折叠过程及此过程中卵清溶菌酶分子各稳定构象态的分布和过渡. 结果表明, 当复性液中盐酸胍浓度分别约为5.0和2.4 mol/L时, 变性卵清溶菌酶分子的重折叠过程各存在1个稳定折叠中间态, 重折叠过程符合"四态模型". 在卵清溶菌酶分子四态重折叠过程基础上, 结合盐酸胍与卵清溶菌酶分子之间的缔合-解离平衡, 给出了一个定量描述变性剂诱导的蛋白质分子复性过程中蛋白质分子复性率随溶液中变性剂浓度变化的方程. 该方程包含2个特征折叠参数, 一个是蛋白质分子从一个稳定构象态过渡到另一个稳定构象态的热力学过渡平衡常数k; 另一个是在此过程中平均每个蛋白质分子所结合的变性剂分子数目m. 通过这2个特征折叠参数能够定量描述盐酸胍诱导的变性卵清溶菌酶完全去折叠态、 折叠中间态和天然态分子随复性液中盐酸胍浓度变化的分布和过渡情况.     

可视化检测次氯酸的苯并咪唑类 荧光增强型探针

合成了一种新型的苯并咪唑类荧光增强型探针2-{[4-(1H-苯并咪唑-2-基)苯亚甲基]氨基}-3-氨基马来腈(ZY12), 用光谱方法研究了其对次氯酸的识别作用. 实验结果表明, ZY12对ClO ^-表现出较高的选择性和灵敏度, 且响应快速, 抗干扰能力强; 将ClO ^-加入到ZY12溶液中后, 反应体系的荧光强度随ClO ^-浓度的增加而逐渐增强, 并伴随着荧光颜色由微蓝色到亮蓝色的变化, 可实现对ClO ^-的可视化检测; 在1.8×10 ^-6~3.4×10 ^-5 mol/L浓度范围内, ZY12能够定量检测ClO ^-, 检测限为2.8×10 ^-7 mol/L; ZY12可应用于不同水样中ClO ^-的检测, 并能对HeLa活细胞中的ClO ^-进行荧光成像.     

蛋白折叠液相色谱法中流动相对重组人干扰素-γ质量回收率的影响

蛋白折叠液相色谱法(PFLC)用于变性蛋白质复性并同时纯化时对流动相组成及其洗脱条件的要求远较通常的液相色谱法高。用端基为PEG-200的高效疏水作用色谱固定相对重组人干扰素-γ(rhIFN-γ)进行纯化并同时复性,详细研究了流动相组成、梯度洗脱模式和流速对rhIFN-γ质量回收率和活性的影响。分别以3.0 mol/L (NH4)2SO4 +0.05 mol/L KH2PO4(pH 7.0)和0.05 mol/L KH2PO4(pH 7.0)为流动相A和B,采用35 min非线性梯度洗脱时,所得rhIFN-γ的质量回收率最高。     

氧氟沙星与脲诱牛血清白蛋白结合的机制研究

利用荧光光谱和紫外光谱研究了脲(Urea)对牛血清白蛋白(BSA)结构的影响以及氧氟沙星(Oflx)与脲诱导的BSA结合的情况.结果显示:Urea诱导BSA变性历经两步、三态且伴随中问态形成的过程中,随着Urea浓度的增大,BSA荧光强度降低并先蓝移(344～336 nm),后又红移至350 nm.Urea浓度在4.6～5.2 mol/L范围时,Oflx对BSA中间态有强的猝灭作用(KQ)=10.46X 104L/mol,Urea 4.8 mol/L)和较大的结合常数(KA=3.8807X105L/mol,Urea 4.8 mol/L),但是结合位点数小(n=0.76,Urea 5.0 mol/L),能量传递效率低(E=0.3002,Urea 4.8 mol/L).同步荧光光谱显示:Urea诱导BSA去折叠时,色氨酸残基(Trp-212)微境并未发生改变,而酪氨酸残基(Tyr)的最大荧光发射峰蓝移,Oflx的加入诱导Trp-212的微环境更具疏水性.Oflx加速了Urea对BSA的失活作用.     

血红蛋白和细胞色素c构象去折叠行为研究

利用紫外-可见吸收和荧光光谱法研究了血红蛋白(Hb)与细胞色素c(Cytc)两种血红素蛋白的去折叠行为。采用化学变性剂盐酸胍(GdHCl)和尿素(Urea)诱导两种蛋白构象去折叠,阐述了两种蛋白的去折叠机理。Hb的血红素(Heme)辅基通过与卟啉铁原子和组氨酸配位,与肽链键合的稳定性较差,在3.0 mol/L的盐酸胍作用下即发生解离。而Cyt c的Heme辅基通过卟啉与半胱氨酸形成二硫键呈现较强的稳定性,盐酸胍浓度达到6.0 mol/L也难使其发生解离。该研究为阐释蛋白构象与功能之间的关系提供了重要依据。     

抗坏血酸包裹的铜纳米簇作为荧光探针定量测定维生素B12

以抗坏血酸(AA)为模板和还原剂,通过“一锅法”在水溶液中合成低毒性的青色荧光铜纳米簇(AA@CuNCs)。实验表明,制备的水溶性AA@CuNCs外观呈球形,有良好的分散性,粒径约为1.6 nm。维生素B₁₂(VB₁₂)能高效猝灭AA@CuNCs的荧光,猝灭机理为静态猝灭和内滤效应。在10～60μmol/L与100～120μmol/L浓度范围内,VB₁₂浓度与AA@CuNCs的相对荧光强度(F₀/F)呈较好的线性关系,检出限低至0.07μmol/L。此外,该荧光探针可以有效地应用于实际样品中VB₁₂的检测,并可将其应用于细胞成像。     

用疏水色谱对还原型胍变性牛胰岛素的折叠特性研究

用疏水相互色谱(HPHIC)对还原胍变性牛胰岛素在疏水界面上的折叠与复性进行了研究.结果表明,采用普通流动相时,对还原胍变胰岛素的复性效果较差,而采用氧化型流动相可使其复性效率提高到66%,并用反相色谱(RPLC)、紫外吸收光谱、荧光光谱及MALDI-TOF对其复性效果进行了验证.同时与体积排阻色谱(SEC)和稀释法对还原胍变胰岛素的复性结果进行了比较.结果表明,SEC根本无法使还原胍变胰岛素复性,而稀释法的复性效率仅有2%.这进一步表明HPHIC是变性蛋白复性的有效工具,变性蛋白在疏水界面折叠过程中,蛋白质与固定相之间的疏水相互作用对蛋白折叠起着关键性的作用,是蛋白折叠的主要驱动力.     

溶剂热插层法制备荧光石墨相氮化碳量子点及其在Fe3+检测中的应用

利用溶剂热法, 基于氢氧化钾的插层作用制备了荧光氮化碳量子点(g-C₃N₄ QDs). 所获得的氮化碳量子点具有良好的水溶性和荧光稳定性. 透射电子显微镜(TEM)照片显示, 氮化碳量子点的粒径约为2.3 nm; X射线光电子能谱(XPS)和红外光谱(FTIR)结果表明, 氮化碳量子点表面存在大量的亲水基团; 荧光发射光谱(PL)结果表明, 氮化碳量子点具有激发波长依赖性. 基于三价铁离子(Fe³⁺)对荧光氮化碳量子点荧光的猝灭现象, 构建了一种用于检测Fe³⁺的荧光传感器, 在Fe³⁺浓度为5~100 μmol/L范围内, 检测体系表现出良好的线性关系, 检出限约为0.5 μmol/L, 实现了对Fe³⁺的高效、 灵敏、 选择性检测.     

盐酸胍诱导的淀粉液化芽孢杆菌α-淀粉酶去折叠过程的研究

分别用内源荧光光谱法、荧光相图法、荧光探针法、荧光猝灭法、蛋白质电泳法以及体积排阻色谱法研究了盐酸胍诱导的淀粉液化芽孢杆菌a-淀粉酶的去折叠过程. 内源荧光光谱和荧光相图结果表明, 当变性液中盐酸胍浓度约为1.0 mol/L时, 芽孢杆菌a-淀粉酶的去折叠过程中出现一个部分折叠中间体, 其去折叠过程符合“三态模型”; 荧光探针结果表明, 在溶液中盐酸胍浓度约为1.0 mol/L时, 中间态芽孢杆菌a-淀粉酶分子中存在着能够与探针分子1-苯胺 基-8-萘磺酸(ANS)结合的稳定的疏水区域; 荧光猝灭研究给出了不同程度变性的淀粉液化芽孢杆菌a-淀粉酶中的Trp的分布情况, 结果表明中间态芽孢杆菌a-淀粉酶分子中能够被碘化钾猝灭的位于分子表面的色氨酸残基数目达到最大的8个; 蛋白电泳和体积排阻色谱结果表明, 在盐酸胍诱导的芽孢杆菌a-淀粉酶分子的整个去折叠过程中, 不会以共价键或非共价键形式形成芽孢杆菌a-淀粉酶分子之间的集聚体或集聚体沉淀. 在此基础上, 对盐酸胍诱导的淀粉液化芽孢杆菌a-淀粉酶的去折叠过程进行了描述.     

Purification of a crystallin domain of Yersinia crystallin from inclusion bodies and its comparison to native protein from the soluble fraction

It has been established that many heterologously produced proteins in E. coli accumulate as insoluble inclusion bodies. Methods for protein recovery from inclusion bodies involve solubilization using chemical denaturants such as urea and guanidine hydrochloride, followed by removal of denaturant from the solution to allow the protein to refold. In this work, we applied on-column refolding and purification to the second crystallin domain D2 of Yersinia crystallin isolated from inclusion bodies. We also purified the protein from the soluble fraction (without using any denaturant) to compare the biophysical properties and conformation, although the yield was poor. On-column refolding method allows rapid removal of denaturant and refolding at high protein concentration, which is a limitation in traditionally used methods of dialysis or dilution. We were also able to develop methods to remove the co-eluting nucleic acids during chromatography from the protein preparation. Using this protocol, we were able to rapidly refold and purify the crystallin domain using a two-step process with high yield. We used biophysical techniques to compare the conformation and calcium-binding properties of the protein isolated from the soluble fraction and inclusion bodies.     

Urea-induced Inactivation and Unfolding of Recombinant Phospholipid Hydroperoxide Glutathione Peroxidase from Oryza sativa

Phospholipid hydroperoxide glutathione peroxidase is an antioxidant enzyme that has the highest capability of reducing membrane-bound hydroperoxy lipids as compared to free organic and inorganic hydroperoxides amongst the glutathione peroxidases.In this study,urea-induced effects on the inactivation and unfolding of a recombinant phospholipid hydroperoxide glutathione peroxidase(PHGPx)from Oryza sativa were investigated by means of circular dichroism and fluorescence spectroscopy.With the increase of urea concentration,the residual activity of OsPHGPx decreases correspondingly.When the urea concentration is above 5.0 mol/L,there was no residual activity.In addition,the observed changes in intrinsic tryptophan fluorescence,the binding of the hydrophobic fluorescence probe ANS,and the far UV CD describe a common dependence on the concentration of urea suggesting that the conformational features of the native OsPHGPx are lost in a highly cooperative single transition.The unfolding process comprises of three zones:the native base-line zone between 0 and 2.5 mol/L urea,the transition zone between 2.5 and 5.5 mol/L urea,and the denatured base-line zone above 5.5 mol/L urea.The transition zone has a midpoint at about 4.0 mol/L urea.     

高效疏水相互作用色谱法复性与同时纯化重组人Flt3配体的包涵体蛋白质

Flt3配体(FL)是一类具有促进早期造血功能的细胞因子,在促进造血细胞生长发育及造血动员方面具有重要的临床应用价值。为了用基因工程方法获得大量用于临床和研究的重组人FL(rhFL)蛋白质,本文对在大肠杆菌(E. coli)中表达得到的Flt3配体的包涵体进行回收、洗涤,溶解于8 mol/L脲后在高效疏水相互作用色谱(HPHIC)柱上进行rhFL包涵体的复性与同时纯化,并对其保留特征和复性规律进行了研究。结果表明,在连续进样、变性蛋白质质量浓度为8.51 g/L、固定相选用端基为PEG800、流动相添加4 mol/L脲、1.8 mmol/L 还原型谷胱甘肽(GSH)和0.3 mmol/L氧化型谷胱甘肽(GSSH)、pH 7.0的优化条件下,复性与同时纯化rhFL包涵体的质量回收率为36.9%,纯度达94.5%以上。本文仅用一步HPHIC法成功地复性与同时纯化了rhFL蛋白质,为获得高活性的rhFL产品奠定了一定的工作基础。     

Binding of 8-anilino-1-naphthalenesulfonate to lecithin:cholesterol acyltransferase studied by fluorescence techniques

The solvatochromic fluorescent probe 8-anilino-1-naphthalenesulfonate (ANS) has been used to study the hydrophobicity and conformational dynamics of lecithin:cholesterol acyltransferase (LCAT). The ANS to LCAT binding constant was estimated from titrations with ANS, keeping a constant concentration of LCAT (2 microM). Apparent binding constant was found to be dependent on the excitation. For the direct excitation of ANS at 375 nm the binding constant was 4.7 microM(-1) and for UV excitation at 295 nm was 3.2 microM(-1). In the later case, not only ANS but also tryptophan (Trp) residues of LCAT is being excited. Fluorescence spectra and intensity decays show an efficient energy transfer from tryptophan residues to ANS. The apparent distance from Trp donor to ANS acceptor, estimated from the changes in donor lifetime was about 3 nm and depends on the ANS concentration. Steady-state and time-resolved fluorescence emission and anisotropies have been characterized. The lifetime of ANS bound to LCAT was above 16 ns which is characteristic for it being in a hydrophobic environment. The ANS labeled LCAT fluorescence anisotropy decay revealed the correlation time of 42 ns with a weak residual motion of 2.8 ns. These characteristics of ANS labeled LCAT fluorescence show that ANS is an excellent probe to study conformational changes of LCAT protein and its interactions with other macromolecules.     

Novel column-based protein refolding strategy using dye-ligand affinity chromatography based on macroporous biomaterial

A novel column-based chromatographic protein refolding strategy was developed using dye-ligand affinity chromatography (DLAC) based on macroporous biomaterial. Chitosan–silica (CS–silica) biomaterial with macroporous surface was used as the supporting matrix for the preparation of the DLAC material. The dye-ligand Cibacron Blue F3GA (CBF) was selected as affinity handle and could be covalently immobilized to form dye-ligand affinity adsorbent (CBF–CS–silica) using the reactivity of NH₂ on CS–silica biomaterial. After the model protein catalase was denatured with 6 mol/L urea, the denaturant could be rapidly removed and catalase could be successfully refolded as facilitated by the adsorption of CBF–CS–silica. The urea denaturation process and the elute condition for the chromatographic refolding were optimized by measuring tryptophan fluorescence and activity of catalase. The refolding performance of the proposed DLAC was compared with dilution refolding. The protein concentration during the proposed chromatographic refolding increased by a factor of 20 without reducing the yield achieved as compared to dilution refolding. The column-based protein refolding strategy based on dye-ligand affinity chromatography with porous biomaterial being matrix possessed potential in chromatographic refolding of protein.     

Binding of naproxen and 1-anilino-8-naphtalenesulphonic acid to albumin: Characterization of their binding sites in bovine serum albumin

The binding of naproxen (NP) and 1-anilino-8-naphtalenesulphonic acid (ANS) to bovine serum albumin (BSA) has been studied by equilibrium dialysis and spectrophotofluorometry, respectively. The drug protein (D/P) ratio is found to determine the nature of binding sites for NP but not for ANS. At low D/P ratio, NP possesses a specific site in BSA and one of the tryptophan residues is part of it. Fluorometric investigation reveals non-displacement of ANS from its sites by the binding of NP to its specific site. At high D/P ratio, NP instead causes localized conformational changes in BSA. Furthermore, it is possible to infer the location of NP's specific site as loop 4 of BSA. NP and ANS binding sites have also been examined by employing Bromocresol Green (BCG) as a spectrophotometric probe. Competition studies are also able to establish distinct binding pattern for the two ligands in BSA. The displacement pattern points out the presence of independent sites for NP (specific site) and ANS (initially occupied site) in BSA in spite of their amphipathically similar nature.     

Spectroscopic studies on the irreversible heat-induced structural transition of Pin1

Previously, the mechanism of the thermal unfolding of Pin1 (on-line measurements) was studied, revealing that Pin1 has a relatively high thermal stability. However, it is still questionable whether the unfolding of Pin1 is reversible. In the present work, intrinsic tryptophan fluorescence, ANS fluorescence, RLS, FTIR and CD spectroscopies are used to evaluate the reversibility of the thermal unfolding of Pin1. Intrinsic tryptophan fluorescence studies indicate that structural changes around tryptophan motifs in Pin1 are possibly reversible after heat treatment (even above 98°C), for no significant change in the intensity or λ(max) of the spectra was observed. ANS fluorescence measurements indicate the irreversible exposure of the hydrophobic clusters in Pin1 after heat treatment at 98°C, with increase in the fluorescence intensity and blue shift in λmax. Also, RLS signals of the Pin1-ANS system increased after heat treatment, possibly implying both the unfolding and the aggregation of Pin1. In addition, FTIR and CD results confirmed the irreversible unfolding of the secondary structure in Pin1 after heat treatment above 90°C, showing decreases in both α-helix and β-sheet. In summary, the present work mainly suggests that heat treatment, especially above 90°C, has an important impact on the structural stability of Pin1, and the structural unfolding induced by heat was proved to be irreversible.     

Enhanced refolding of lysozyme with imidazolium-based room temperature ionic liquids: Effect of hydrophobicity and sulfur residue

The expression of recombinant proteins in microorganism frequently leads to the formation of insoluble aggregates, inclusion bodies (IBs). Thus, the additional in vitro protein refolding process is required to convert inactive IBs into water-soluble active proteins. This study investigated the effect of sulfur residue and hydrophobicity of imidazolium-based room temperature ionic liquids (RTILs) on the refolding of lysozyme as a model protein in the batch dilution method which is the most commonly used refolding method. When lysozyme was refolded in the refolding buffer containing [BF4]-based RTILs with a systematic variety of alkyl chain on cations varying from two to eight, less hydrophobic imidazolium cations having shorter alkyl chains were effective to facilitate lysozyme refolding. Compared to the conventional refolding buffer, 2 times higher lysozyme refolding yield was obtained in 1-ethyl-3-methylimidazolium tetrafluoroborate ([EMIM][BF4]) containing refolding buffer. The refolding yield of lysozyme was even more increased by 2.5 times when 1-butyl-3-methylimidazolium methylsulfate ([BMIM][MS]) containing sulfur residue on anion was used. The sulfur residue in [BMIM][MS] is supposed to improve the refolding yield of lysozyme which has 4 intramolecular disulfide bonds. For dilution-based refolding of lysozyme, the optimum concentrations of RTILs in refolding buffer were found to be 1.0 M [EMIM][BF4] and 0.5 M [BMIM][MS], respectively. The optimum temperate for dilution-based refolding of lysozyme with RTILs was 4 °C.     

Protein unfolding and subsequent refolding: a spectroscopic investigation

The mechanism by which the protein Bovine Serum Albumin (BSA) undergoes unfolding induced by Guanidine Hydrochloride (GdHCl) and then the subsequent refolding brought in by many-fold dilution was studied by steady-state fluorescence, anisotropy, time resolved measurements and Circular Dichroism (CD) spectroscopy. CD data reveal that the protein attains a degree of extra rigidity at low concentrations of the denaturant, GdHCl, and this observation was correlated with other techniques used in this present work. The unfolding and refolding of BSA appear to proceed through intermediates and both the processes are sequential in nature. The intrinsic fluorescence from the tryptophan amino acid residue of BSA and another external fluorophore Nile Red was made use of in order to investigate the mechanisms of unfolding and refolding and we have conclusively proved that both these processes follow a reversible mechanism.