溴化+烷基三甲基铵滴定时氨基酰化酶的失活与构象变化的比较

研究了阳离子去污剂-溴化+烷基三甲基铵变性时氨基酰酶的失活与构象变化.当用溴化+烷基三甲基铵滴定氨基酰化酶时,随着去污剂浓度增大,酶的活力逐渐丧失,至50mmolL时酶完全失活.用荧光发射光谱(295nm激发)的方法监测了氨基酰化酶的构象变化.发现氨基酰化酶失活先于构象变化.从这一结果看来.金属酶的活性部位构象可能也是比整个分子的构象具有较大的柔性或运动性.     

氨基酰化酶在LDS溶液中的失活与去折叠的比较研究

氨基酰化酶在阴离子去污剂十二烷基硫酸溶液中的失活与去折叠的研究结果表明,在低浓度的ＬＤＳ溶液中变性时,以荧光和紫外差吸收方法监测的酶分子构象尚未发生明显变化,而酶的活力已经大部分或几乎全部丧失。当ＬＤＳ浓度达１．６ｍｍｏｌ／Ｌ时,此时酶分子的构象变化才达到最大程度。在实验使用的ＬＤＳ的浓度范围内,用远紫外ＣＤ光谱监测的二级结构没有发生明显的变化。     

盐酸己烷基双胍对肌酸激酶的活力及构象的影响

测定了盐酸己烷基双胍(C_6H_(13)C_2N_5H_(?)HCl;记为HBGC)对肌酸激酶(Creatine Kinase;记为CK)的活力的影响;同时利用荧光光谱,紫外差光谱.付里叶红外光谱等手段测定了HBGC对CK构象的影响,结果表明.HBGC为0.07mol时就使CK完全失活、而且在高浓度的HBGC中变性后的CK.稀释时即可完全复活;CK的活力丧失明显先于构象的变化,与溴化+烷基三甲铵不同,HBGC可以破坏CK的二级结构,使之完全无序化.     

胍和脲溶液对氨基酰化酶活性和构象的影响

 本文研究了不同浓度盐酸胍和脲溶液对猪肾氨基酰化酶活性和构象的影响。研究结果表明,在低浓度的胍和脲溶液中(小于2mol/L),酶分子的整体构象变化的程度与活力变化的程度基本是平行的;而在高浓度的胍和脲溶液中(2mol/L以上),失活程度稍大于构象变化的程度。这些结果与分子量和亚基组成基本相同,但不含金属配基的肌酸激酶的结果,以及小分子量的胰凝乳蛋白酶和牛胰核糖核酸酶的结果相比较来看,可以认为配基锌离子的存在对酶分子的活性部位区域构象的稳定作用有一定的贡献,致使氨基酰化酶的活性部位的构象状态不象后三种酶那样脆弱。同时,我们还发现锌离子的存在对酶分子整体构象的稳定性上贡献很小。     

氨基酰化酶在LDS溶液中的失活与去折叠的比较研究

氨基酰化酶在阴离子去圬剂十二烷基硫酸锂（ＬＤＳ）溶液中的失活与去折叠的研究结果表明,在低浓度的ＬＤＳ溶液（０．６ｍｍｏｌ／Ｌ）中变性时,以荧光和紫外差吸收方法监测的酶分子构象尚未发生明显变化。而酶的活力已经大部分或几乎全部丧失。当ＬＤＳ浓度达１．６ｍｍｏｌ／Ｌ时,此时酶分子的构象变化才达到最大程度,在实验使用的ＬＤＳ的浓度范围内,用远紫外ＣＤ光谱监测的二级结构没有发生明显的变化。从上述研究结果,可以认为含锌氨基酰化酶的活性部位也具有相对的柔性。     

截流荧光法研究米曲霉氨基酰化酶的快速胍变性动力学

 用荧光光谱法、截流荧光法和酶活力测定法研究了在盐酸胍溶液中米曲霉氨基酰化酶变性动力学。我们发现在4.8mol/L盐酸胍溶液作用下(0.05mol/L磷酸缓冲溶液,pH7.4,25℃),氨基酰化酶二聚体解离成单亚基过程是一个十分快速的过程,反应速率常数k为3361l/s,即约需3ms时间完成;而单亚基分子的构象变化需要约20min方能到达平衡态,这是一个逐渐变化的缓慢过程。酶分子在胍作用下的失活现象同酶分子的结构变化紧密相关,在胍浓度大于4mol/L时酶完全失活。在高浓度盐酸胍下酶失活主要是因为酶二聚体迅速解离成单亚基的过程和单亚基构象逐渐变化的缓慢过程。双亚基解离常数大小标志着酶分子亚基间作用力的强弱。     

PAR对氨基酰化酶不可逆抑制动力学研究

本文将邹氏的在酶的活性修饰剂存在下的底物反应动力学理论应用于氨基酰化酶被金属螯合剂PAR脱锌而失活的动力学研究。通过对不同浓度的PAR存在下底物反应过程和含有PAR的不同浓度的底物中酶促反应的分析,讨论了PAR对氨基酰化酶的脱锌机制。这一过程很可能按如下机制进行:首先,PAR与酶分子活性部位的锌结合,形成一复合物,这一步是较快的反应,然后发生一个可逆的构象变化,最后是不可逆的去锌步骤。锌的存在显然稳定了酶活性部位的构象,而这正是酶活性所必需的。     

人肌肌酸激酶胍变性时的失活与构象变化的比较研究

应用二阶导数光谱、紫外差吸收光谱和荧光光谱等监测手段,研究了人肌肌酸激酶在盐酸胍溶液中的构象变化。二阶导数光谱结果表明,若以6M盐酸胍中肌酸激酶酪氨酸残基的暴露程度为100％,则天然酶酪氨酸残基的暴露程度只有2％。而紫外差吸收光谱和荧光光谱的变化与兔肌肌酸激酶的结果相似。比较不同胍浓度下人肌肌酸激酶的失活与构象变化,表明酶的失活先于构象变化。同时还测定了不同浓度胍溶液中人肌酶的失活与构象变化的速度常数。结果表明以几种方法测定的构象变化均为单相的一级过程,而酶的失活却呈现了由快慢两相组成的一级反应过程。比较同浓度胍溶液中的失活速度与构象变化速度,发现酶失活的快相反应速度常数比构象变化的速度常数大1—2个数量级,慢相速度常数与构象变化速度常数相近。上述结果进一步支持了酶的活性部位构象柔性的观点。     

酵母乙醇脱氢酶胍变性时的失活与去折叠的比较研究

应用荧光发射光谱,圆二色光谱,二阶导数光谱和紫外差吸收光谱等监测手段,研究了酵母乙醇脱氢酶在胍溶液中的去折叠。比较不同盐酸胍浓度下酵母乙醇脱氢酶的失活与构象变化,实验表明酶的失活先于构象变化：在低浓度胍溶液中,构象尚未发生明显变化时,酶活几乎已经完全丧失。由上述结果可见,含有辅基金属离子Ｚｎ~（２＋）酶的活性部位较酶分子的整体结构也具有柔性。     

酵母乙醇脱氢酶胍变性时的失活与去折叠的比较研究

应用荧光发射光谱,圆二色光谱,二阶导数光谱和紫外差吸收光谱等监测手段,研究了酵母乙醇脱氢酶在胍溶液中的去折叠,比较不同盐酸胍浓度下酵母乙醇脱氢酶的失活与构象变化,实验表明酶的失活先于构象变化,在低浓度胍溶液中,构象尚未发生明显变化时,酶活几乎已经完全丧失,由上述结果可见,含有辅基金属离子Ｚｎ＾２＋酶的活性部位较酶分子的整体结构也具有柔性。     

Inactivation and unfolding of aminoacylase during denaturation in sodium dodecyl sulfate solutions

During denaturation by sodium dodecyl sulfate (SDS), aminoacylase shows a rapid decrease in activity with increasing concentration of the detergent to reach complete inactivation at 1.0 mM SDS. The denatured minus native-enzyme difference spectrum showed two negative peaks at 287 and 295 nm. With the increase of concentration of SDS, both negative peaks increased in magnitude to reach maximal values at 5.0 mM SDS. The fluorescence emission intensity of the enzyme decreased, whereas there was no red shift of emission maximum in SDS solutions of increasing concentration. In the SDS concentration regions employed in the present study, no marked changes of secondary structure of the enzyme have been observed by following the changes in far-ultraviolet CD spectra. The inactivation of this enzyme has been followed and compared with the unfolding observed during denaturation in SDS solutions. A marked inactivation is already evident at low SDS concentration before significant conformational changes can be detected by ultraviolet absorbance and fluorescence changes. The inactivation rate constants of free enzyme and substrate-enzyme complex were determined by the kinetics method of the substrate reaction in the presence of inactivator previously described by Tsou [Tsou (1988),Adv. Enzymol. Related Areas Mol. Biol. 61, 381–436]. It was found that substrate protects against inactivation and at the same SDS concentrations, the inactivation rate of the free enzyme is much higher than the unfolding rate. The above results show that the active sites of metal enzyme containing Zn²⁺ are also situated in a limited and flexible region of the enzyme molecule that is more fragile to denaturants than the protein as a whole.     

Comparison of inactivation and unfolding of methanol dehydrogenase during denaturation in guanidine hydrochloride and urea

The activity and the conformational changes of methanol dehydrogenase (MDH), a quinoprotein containing pyrrolo-quinoline quinone as its prosthetic group, have been studied during denaturation in guanidine hydrochloride (GdnHCl) and urea. The unfolding of MDH was followed using the steady-state and time resolved fluorescence methods. Increasing the denaturant concentration in the denatured system significantly enhanced the inactivation and unfolding of MDH. The enzyme was completely inactivated at 1 M GdnHCl or 6 M urea. The fluorescence emission maximum of the native enzyme was at 332 nm. With increasing denaturant concentrations, the fluorescence emission maximum red-shifted in magnitude to a maximum value (355 nm) at 5 M GdnHCl or 8 M urea. Comparison of inactivation and conformational changes during denaturation showed that in general accord with the suggestion made previously by Tsou, the active sites of MDH are situated in a region more flexible than the molecule as a whole.     

Unfolding and inactivation of Ampullarium crossean beta-glucosidase during denaturation by guanidine hydrochloride

Changes of activity and conformation of Ampullarium crossean beta-glucosidase in different concentrations of guanidine hydrochloride (GuHCl) have been studied by measuring the fluorescence spectra and its relative activity after denaturation. The fluorescence intensity of the enzyme decreased distinctly with increasing guanidine concentrations, the emission peaks appeared red shifted (from 338.4 to 350.8 nm), whereas a new fluorescence emission peak appeared near 310 nm. Changes in the conformation and catalytic activity of the enzyme were compared. A corresponding rapid decrease in catalytic activity of the enzyme was also observed. The extent of inactivation was greater than that of conformational changes, indicating that the active site of the enzyme is more flexible than the whole enzyme molecule. k(+0)>k(+0)' also showed that the enzyme was protected by substrate to a certain extent during guanidine denaturation.     

Unfolding and inactivation during thermal denaturation of an enzyme that exhibits phytase and acid phosphatase activities

The thermostability of an enzyme that exhibits phytase and acid phosphatase activities was studied. Kinetics of inactivation and unfolding during thermal denaturation of the enzyme were compared. The loss of phytase activity on thermal denaturation is most suggestive of a reversible process. As for acid phosphatase activities, an interesting phenomenon was observed; there are two phases in thermal inactivation: when the temperature was between 45 and 50 degrees C, the thermal inactivation could be characterized as an irreversible inactivation which had some residual activity and when the temperature was above 55 degrees C, the thermal inactivation could be characterized as an irreversible process which had no residual activity. The microscopic rate constants for the free enzyme and substrate-enzyme complex were determined by Tsou's method [Adv. Enzymol. Relat. Areas Mol. Biol. 61 (1988) 381]. Fluorescence analyses indicate that when the enzyme was treated at temperatures below 60 degrees C for 60 min, the conformation of the enzyme had no detectable change; when the temperatures were above 60 degrees C, some fluorescence red-shift could be observed with a decrease in emission intensity. The inactivation rates (k(+0)) of free enzymes were faster than those of conformational changes during thermal denaturation at the same temperature. The rapid inactivation and slow conformational changes of phytase during thermal denaturation suggest that inactivation occurs before significant conformational changes of the enzyme, and the active site of this enzyme is situated in a relatively fragile region which makes the active site more flexible than the molecule as a whole.     

Inactivation and conformational changes of fatty acid synthase from chicken liver during unfolding by sodium dodecyl sulfate

Fatty acid synthase is an important enzyme participating in energy metabolism in vivo. The inactivation and conformational changes of the multifunctional fatty acid synthase from chicken liver in SDS solutions have been studied. The results show that the denaturation of this multifunctional enzyme by SDS occurred in three stages. At low concentrations of SDS (less than 0.15 mM) the enzyme was completely inactivated with regard to the overall reaction. For each component of the enzyme, the loss of activity occurred at higher concentrations of SDS. Significant conformational changes (as indicated by the changes of the intrinsic fluorescence emission and the ultraviolet difference spectra) occurred at higher concentrations of SDS. Increasing the SDS concentration caused only slight changes of the CD spectra, indicating that SDS had no significant effect on the secondary structure of the enzyme. The results suggest that the active sites of the multifunctional fatty acid synthase display more conformational flexibility than the enzyme molecule as a whole.     

3-磷酸甘油醛脱氢酶胍变性时的活力及构象变化

酵母3-磷酸甘油醛脱氢酶在盐酸胍溶液中的内源荧光及剩余活力的变化结果提示:apo酶及holo酶的活力在胍浓度为0.5M左右可完全丧失.同时伴有内源荧光强度的下降,光谱宽度的增加和335nm最大发射峰的红移(提示了色氨酸残基的暴露).与已经报导的肌肉酶(内源荧光强度在胍浓度为0.4—1.2M范围相对稳定)不同,酵母酶内源荧光在此浓度范围内表现为逐渐降低.在0.7M胍溶液中,内源荧光变化动力学过程只能测出一相,而酶失活动力学过程为快慢两相,快相动力学速度常数至少大于内源荧光降低速度常数三个数量级以上.以上结果提示:低浓度胍可引起该酶的完全失活,活性部位的空间构象比酶分子的构象更易受到变性剂的扰乱;有一个色氨酸残基位于或靠近酶的活性部位.     

The guanidine like effects of arginine on aminoacylase and salt-induced molten globule state

Aminoacylase is a dimeric enzyme containing one Zn(2+) ion per subunit. The arginine (Arg)-induced unfolding of Holo-aminoacylase and Apo-aminoacylase has been studied by measurement of enzyme activity, fluorescence emission spectra and 1-anilino-8-naphthalenesulfonate (ANS) fluorescence spectra. Besides being the most alkaline amino acid, the arginine molecule contains a positively charged guanidine group, similar to guanidine hydrochloride, and has been used in many refolding systems to suppress protein aggregation. Our results showed that arginine caused the inactivation and unfolding of aminoacylase, with no aggregation during denaturation. A comparison between the unfolding of aminoacylase in aqueous and HCl (pH 7.5) arginine solutions indicated that the guanidine group of arginine had protein-denaturing effects similar to those of guanidine hydrochloride, which might help us understand the mechanism by which arginine suppresses incorrect refolding. The results showed that arginine-denatured aminoacylase could be reactivated and refolded correctly, indicating that arginine is as good a denaturant as the guanidine or urea for study of protein unfolding and refolding. Both the intrinsic fluorescence and the ANS fluorescence spectra showed that the arginine-unfolded aminoacylase formed a molten globule state in the presence of KCl, suggesting that intermediates exist during aminoacylase refolding. The results for the Apo-aminoacylase followed were similar to those for the Holo-enzyme, suggesting that Holo- and Apo-aminoacylase might have a similar unfolding and refolding pathway.     

Comparison of the rates of inactivation and conformational changes of creatine kinase during urea denaturation

The denaturation of creatine kinase in urea solutions of different concentrations has been studied by following the changes in the ultraviolet absorbance and intrinsic fluorescence as well as by the exposure of hidden SH groups. In concentrated urea solutions, the denaturation of the enzyme results in negative peaks at 285 nm with shoulders at 280 and 290 nm and positive peaks at 244 and 302 nm in the denatured minus native enzyme difference spectrum. The fluorescence emission maximum of the enzyme red shifts with increasing intensity in urea solutions of increasing concentrations. At least part of these changes can be attributed to direct effects of urea on the exposed Tyr and Trp residues as shown by experiments with model compounds. The inactivation of this enzyme has been followed and compared with the conformational changes observed during urea denaturation. A marked decrease in enzyme activity is already evident at low urea concentrations before significant conformational changes can be detected by the exposure of hidden SH groups or by ultraviolet absorbance and fluorescence changes. At higher urea concentrations, the enzyme is inactivated at rates 3 orders of magnitude faster than the rates of conformational changes. The above results are in accord with those reported previously for guanidine denaturation of this enzyme [Yao, Q., Hou, L., Zhou, H., & Tsou, C.-L. (1982) Sci. Sin. (Engl. Ed.) 25, 1186-1193] and can best be explained by assuming that the active site of this enzyme is situated near the surface of the enzyme molecule and is sensitive to very slight conformational changes.