牛血清IgG热化学变性和热变性的研究

使用差示扫描量热仪(DSC)和荧光光谱法研究了在pH 7.4时牛血清IgG (bIgG)热变性, 热化学变性和等温化学变性过程(变性剂为尿素和盐酸胍), 首次报道了bIgG在热化学变性和等温化学变性过程中的相关热力学参数. DSC和荧光光谱实验结果表明, bIgG的热变性和热化学变性过程都是较复杂的不可逆过程, 这个过程可被看作一个三态变构过程. DSC实验表明在热化学变性过程中bIgG的变性温度和焓变值会随着环境中的变性剂浓度的升高而降低. 使用荧光光谱法对bIgG在尿素或盐酸胍存在下的等温化学变性过程进行了研究, 结果显示bIgG的化学变性过程也是一个较复杂的非二态过程. 实验数据分析表明, 变性剂尿素和盐酸胍与bIgG之间主要是依靠氢键相互作用的, 而热变性过程中bIgG的凝集是由于bIgG热变性时结构改变后暴露出的疏水结构互相作用造成的. 实验结果还表明单纯的热变性只能导致bIgG的不完全变性, 而即使是在高浓度变性剂存在时的bIgG热化学变性, 尿素和盐酸胍分别导致的bIgG热化学变性的去折叠态也是不同的.     

盐酸胍和尿素诱导溶菌酶变性的微量热研究

应用恒温微量热技术,对盐酸胍和尿素与溶菌酶在30℃水溶液中的结合作用及造成溶菌酶变性的过程进行了研究,并根据简单结合模型,计算了它们之间的结合常数、结合自由能。用变性中点的直线外推方法求出了表观变性焓。实验结果表明,盐酸胍和尿素诱导溶菌酶变性的相互作用均分为3个阶段。溶菌酶在盐酸胍溶液中的变性焓在pH=4.16时为81...     

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.     

脲和盐酸胍诱导的卵清溶菌酶分子去折叠过程中各稳定构象态的分布和过渡

以内源荧光光谱和荧光相图法研究了脲和盐酸胍诱导的卵清溶菌酶分子的去折叠过程,结果表明,当变性液中脲和盐酸胍的浓度分别约为4.0和3.0 mol/L时,卵清溶菌酶分子的去折叠过程均存在一个折叠中间态,这两个去折叠过程均符合"三态模型".在卵清溶菌酶分子"三态"去折叠过程的基础上,通过变性剂分子和卵清溶菌酶分子之间的缔合一...     

小分子热休克蛋白Mj HSP16.5的分级变性

应用荧光光谱、圆二色光谱、体积排阻色谱、激光动态光散射等技术, 研究了来自嗜热古细菌Methanococcus jannaschii (Mj)的小分子热休克蛋白Mj HSP16.5在变性剂作用下的变性过程. 研究表明, 在pH 7时, Mj HSP16.5在8 mol·L-1尿素作用下不会发生变性. 在pH 7条件下, 盐酸胍对Mj HSP16.5的变性表现为一个分级过程,分别在2.0、3.0和6.0 mol·L-1盐酸胍浓度附近,出现明显的结构变化; 到7.0 mol·L-1盐酸胍时, Mj HSP16.5才完全变性. 降低溶液pH值将使Mj HSP16.5的变性变得更为容易.     

牛血清蛋白在盐酸胍和尿素体系中变性的微量热研究

在30 ℃时用恒温微量热法研究了不同pH值下盐酸胍、尿素诱导牛血清蛋白变性的过程. 并用Privalov提出的简单键合模型对量热数据进行了分析, 计算了表观键合常数K, 简单键合的单个表观键合自由能ΔG和总吉布斯能ΔG(a), 用变性中点的直线外推方法求出了表观变性焓ΔH_d. 实验结果表明, 牛血清蛋白与盐酸胍的键合在碱性条件下更易进行, 牛血清蛋白在盐酸胍溶液中的变性焓ΔH_d在牛血清蛋白的pH＝6.97和7.05时为350 kJ•mol^－1, 在pH＝9.30时为275 kJ•mol^－1, 表明牛血清蛋白在接近中性时较稳定. 而牛血清蛋白与尿素的键合在酸性条件下更易进行, 此变性焓ΔH_d在牛血清蛋白的pH＝6.97时为295 kJ•mol^－1, 在pH＝7.05和9.30时为230 kJ•mol^－1. 此结果说明牛血清蛋白在两种变性剂溶液中的展开程度是不同的.     

参数Z对疏水色谱中胍变蛋白质分子构象变化的表征

用计量置换参数Ｚ对疏水色谱流动相中存在盐酸胍时蛋白质分子构象变化进行了表征。除溶菌酶外，其余４种蛋白质的Ｚ值随盐酸胍浓度的增大先增大，而后减小。将盐酸胍和脲对蛋白质Ｚ值的影响进行了比较后发现，在疏水色谱中Ｚ值作为蛋白质分子构象变化表征的一个重要的结论是随变性剂浓度的增大，埋藏在蛋白质分子内部的疏水性氨基酸残基暴露到分子表面的程度逐渐增大，造成了Ｚ值随蛋白质分子构象变化程度的增大而减小。蛋白质的Ｚ值随盐酸胍及脲浓度变化的不同特点，反映了两者对蛋白质变性机理的不同。     

DMSO对鸡蛋白溶菌酶溶液变性的影响

利用差示扫描量热(DSC)和温度调制差示扫描量热(MDSC)研究了鸡蛋白溶菌酶在纯水及二甲基亚砜(DMSO)/水混合溶剂中的热变性过程, 探讨了酶的浓度、扫描速率和共溶剂的含量对热变性行为的影响规律. 在纯水溶液中, 溶菌酶的变性焓(△Hm)随酶浓度的增大而增大. 而在DMSO/水混合溶剂中, 变性温度(Tm)随DMSO体积分数的增大向低温方向移动, 变性峰变低变宽; 当DMSO体积分数达到70%后, 热变性曲线变成了一条光滑的直线. 另外, 在纯水溶液中溶菌酶的MDSC图除了出现DSC中可观察到的主吸热峰(I)外, 在峰(I)的前面还出现一个小而对称的吸热峰(II), 并且当体系中有DMSO存在时也未能观察到此峰. 当溶菌酶浓度增大时, Tm(II)移向低温, △Hm(II)减小, Tm(I)与Tm(II)之间的距离变长. 吸热峰(II)的出现被认为是由于水溶液中溶菌酶二聚体的可逆离解造成的.     

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。     

等转化率法分析溶菌酶在添加剂影响下的热变性行为

利用差示扫描量热法(DSC)研究了溶菌酶在不同浓度的添加剂(蔗糖、葡萄糖、果糖、甘露醇)和不同浓度的磷酸盐缓冲液影响下的热变性过程,并用等转化率法对该过程进行了分析.变性温度Tm随扫描速率和添加剂浓度的增加而提高,随磷酸盐缓冲液浓度的增加而降低.磷酸盐加速了溶菌酶的变性过程,降低了溶菌酶的热稳定性,而添加剂则增强了溶菌酶的热稳定性.在添加剂存在的条件下,溶菌酶变性过程部分为聚集不可逆过程,部分则可逆.等转化率法表明溶菌酶在所有条件下,其表观活化能在不同的转化率下并未保持不变,而是随转化率增大而减小,说明了一个简单的反应机理并不能用来描述溶菌酶的变性过程,其过程并不是标准两态可逆过程,而是一个涉及多种蛋白质状态的复杂过程.     

Assessment of interactions between four proteins and benzothiazole derivatives by DSC and CD

The thermal denaturation of ovalbumin, lysozyme, myoglobin and fibrinogen at different BTS concentrations have been investigated using differential scanning calorimetry (DSC) and circular dichroism (CD) spectroscopy. Thermodynamic parameters: melting temperatures (T_m), calorimetric enthalpy (ΔH), van’t Hoff enthalpy (ΔH_v) were obtained for all the systems under study. Thermal denaturation of the four proteins was completely irreversible. Changes in the protein conformation due to the adsorption of BTS molecules have been monitored by using UV-CD spectra. Greater changes in α-helical contents correspond with the BTS higher concentrations. The lysozyme denaturation temperature increases at low concentrations BTS indicating that BTS acts as a structure stabilizer; meanwhile it acts as a destabilizer at higher concentrations in all the proteins studied. The major effect is observed in the case of myoglobin, the protein with the highest α-helical secondary structure (75%).     

Microcalorimetric determination of displacement adsorption enthalpies of protein refolding on a moderately hydrophobic surface at 308 K

Both microcalorimetric determination of displacement adsorption enthalpies ΔH and measurement of adsorbed amounts of guanidine – denatured lysozyme (Lys) refolding on the surface of hydrophobic interaction chromatography (HIC) packings at 308 K were carried out and compared with that at 298 K. Study shows that both temperature and concentration of guanidine hydrochloride (GuHCl) affect the molecular mechanism of hydrophobic interaction of protein with adsorbent based on the analysis of dividing ΔH values into three kinds of enthalpy fractions. The adsorption in higher concentrations of GuHCl (>1.3 mol L^–1) at 308 K is an enthalpy-driving process, and the adsorption under other GuHCl concentrations is an entropy-driving process. The fact that the Lys denatured by 1.8 mol L^–1 GuHCl forms a relatively stable intermediate state under the studied conditions will not be changed by temperature.     

On the Use of the Hypothesis of Statistically Homogeneous Suspensions in the Calculation of Their Conductivity

Electrostatic effects on protein adsorption were investigated using differential scanning calorimetry (DSC) and adsorption isotherms. The thermal denaturation of lysozyme, ribonuclease A (RNase), and alpha-lactalbumin in solution and adsorbed onto silica nanoparticles was examined at three concentrations of cations: 10 and 100 mM of sodium and 100 mM of sodium to which 10 mM of calcium was added. The parameters investigated were the denaturation enthalpy (DeltaH), the temperature at which the denaturation transition was half-completed (T(m)), and the temperature range of the denaturation transition. For lysozyme and RNase, adsorption isotherms depend strongly on the ionic strength. At low ionic strength both proteins have a high affinity for the silica particles and adsorption is accompanied by a 15-25% reduction in DeltaH and a 3-6 degrees C decrease in T(m), indicating that the adsorbed state of the proteins is destabilized. Also, an increase in the width of the denaturation transition is observed, signifying a larger conformational heterogeneity of the surface bound proteins. At higher ionic strengths, both with and without the addition of calcium, no significant adsorption-induced alteration in DeltaH was observed for all three proteins. The addition of calcium, however, decreases the width of the denaturation transition for lysozyme and RNase in the adsorbed state. Copyright 2001 Academic Press.     

Cooperative Effect of Guanidinium Chloride and Urea on Lysozyme Refolding

Abstract

The interaction between urea and guanidinium chloride (GuHCl) on lysozyme refolding was investigated in this work. Live micrococcus lysodeikticus was successfully introduced into a refolding system. Lysozyme can be refolded from the GuHCl-denatured, DTT-reduced state in a good yield of 96.54% at final protein concentration as high as 0.2 mg·mL^?1. A model could be employed to elucidate refolding kinetics behavior and the kinetics constants were studied. In the coexistence of GuHCl and urea, the aggregation rate decreased by increasing urea concentration to a proper value. The cooperation of GuHCl and urea not only suppressed the competition of the aggregation reaction but also increased the yield of refolding efficiently.     

Influence of urea on the high-performance cation-exchange chromatography of hen egg white lysozyme

The effects of urea on the high-performance cation-exchange chromatography of hen egg lysozyme are reported. The capacity factor, k', has been determined as a function of cation concentration with a polyaspartate column using the acetates of Na+, K+, Ca2+ and Mg2+. Urea decreases lysozyme retention. Plots of log k' vs. log ionic strength show linear relationships. The slope of the plot describing the Ca2+ elution of lysozyme was the same in the presence of 5 M urea as in its absence. In strong urea solutions and at elevated temperatures, lysozyme denaturation is evidenced by a marked decrease in k'. The temperature range for denaturation corresponded closely to that observed in intrinsic fluorescence and circular dichroism measurements. The potential utility and limitations of high-performance ion-exchange chromatography for studying protein denaturation are discussed.