丁咯地尔与人血清白蛋白结合的光谱学研究

用紫外吸收光谱法、荧光光谱法和傅立叶变换红外光谱法探讨了在模拟人体生理条件下,丁咯地尔与人血清白蛋白(HSA)的结合模式.结果表明:丁咯地尔对HSA的内源荧光有显著的猝灭作用,且猝灭机理主要为静态猝灭.丁咯地尔与HSA形成了1 ∶ 1的复合物,结合常数K=7.43×102 L·mol-1(308 K).根据Fster偶极-偶极非辐射能量转移机理,求得丁咯地尔与HSA间的结合距离r=2.64 nm.由热力学参数确定其作用力以氢键和范德华力为主.同步荧光和傅立叶变换红外光谱表明丁咯地尔对HSA二级结构的含量产生影响,使HSA的α-螺旋结构的含量明显降低,β-折叠和β-转角结构的含量增加.     

2-(4-甲基苯基)-3-(N-乙酰基)-5-(2-羟基苯基)-1,3,4-噁唑啉的合成及与人血清白蛋白的相互作用

合成了2-(4-甲基苯基)-3-(N-乙酰基)-5-(2-羟基苯基)-1,3,4-噁唑啉(MPAHO),并用核磁共振波谱法和红外光谱法对其进行了表征。采用荧光光谱技术研究了MPAHO与人血清白蛋白(HSA)的相互作用。结果表明:MPAHO对HSA有较强的荧光猝灭作用,根据Stern-Volmer方程得到的荧光猝灭常数,可判断由于与MPAHO反应而导致HSA的荧光猝灭均属于静态猝灭。采用位点结合模型公式和Frster非辐射能量转移理论计算了结合常数、结合位点数、结合距离。从计算得到的热力学参数焓变ΔH和熵变ΔS,推断MPAHO与HSA之间的作用力为静电引力。并应用同步荧光光谱和三维荧光技术研究了MPAHO对HSA构象的影响。     

百草枯与牛血清白蛋白结合作用的荧光光谱

在模拟动物体生理条件下, 用荧光光谱和紫外-可见吸收光谱法研究了在不同温度下, 百草枯(PQ)与牛血清白蛋白(BSA)结合反应的光谱行为. 试验发现, PQ对BSA有较强的荧光猝灭作用. 用Stern-Volmer和Lineweaver-Burk方程分别处理试验数据, 发现BSA与PQ发生反应生成了新的复合物, 属于静态荧光猝灭, 发生分子内的非辐射能量转移. 根据F?rster的偶极-偶极非辐射能量转移理论计算出结合位置距离212位色氨酸残基2.07 nm. 由Lineweaver-Burk方程求出了不同温度下反应时复合物的形成常数K_LB (297 K: 2.035×10⁴ L•mol^－1; 304 K: 3.256×10⁴ L•mo^－1; 311 K: 2.889×10⁴ L•mol^－1)及对应温度下结合反应的热力学参数(⊿H^Ø＝18.50 kJ•mol^－1;⊿S^Ø＝144.7 J•K^－1/145.2 J•K^－1/141.0 J•K^－1; ⊿G^Ø＝－24.50 kJ•mol^－1/－25.66 kJ•mol^－1/－25.36 kJ•mol^－1), 证明二者主要靠疏水作用力结合. 同时用三维荧光光谱及同步荧光光谱法探讨了PQ对BSA构象的影响, 为预防和医治PQ中毒提供了重要依据.     

某些芳香族氨基酸作探针荧光猝灭法测定秋水仙碱

在适当的酸性介质中, 秋水仙碱(COL)能与色氨酸(Trp)、酪氨酸(Tyr)和苯丙氨酸(Phe)等芳香族氨基酸反应并形成结合产物, 此时将引起上述氨基酸的荧光发生猝灭, 最大猝灭波长分别位于350 nm (Trp), 304 nm (Tyr), 284 nm (Phe). 其荧光猝灭值(ΔF)在一定范围内与秋水仙碱成正比. 当用Trp和Tyr作探针时, 荧光猝灭法测定秋水仙碱具有高灵敏度, 其检出限分别为15.1 ng/mL (3.78×10^－8 mol/L)和19.8 ng/mL (4.96×10^－8 mol/L). 文中研究了适宜的反应条件和影响因素, 考察了共存物质的影响, 表明方法有良好的选择性, 可用于秋水仙碱的测定. 文中讨论了复合物的组成、结合力和结合模式. 通过温度的影响以及Stern-Volmer作图, 判断该反应为静态猝灭反应, 它们的结合常数(K)在25 ℃时分别为9.7×10⁶ (COL-Trp), 8.9×10⁶ (COL-Tyr)和6.3×10⁵ (COL-Phe). 其作用力主要是芳基堆集作用和氢键结合作用, 而芳基堆集作用是发生荧光猝灭的主要原因.     

荧光光谱法研究除草醚与牛血清白蛋白的相互作用

运用荧光光谱和紫外吸收光谱研究水溶液中除草醚(NP)与牛血清白蛋白(BSA)的相互作用.结果表明,NP与BSA形成基态复合物导致BSA内源荧光猝灭,猝灭机理主要为静态猝灭和非辐射能量转移.运用位点模型计算298 K、308 K、318 K时结合常数K_A分别为6.97×10~4、5.25×10~4 、4.96×10~4 L·mol~(-1),结合位点数n分别为0.98、0.92、0.96.根据热力学参数确定其作用力以疏水作用和静电作用为主;运用F(o)rster偶极-偶极非辐射能量转移原理,测定了NP与BSA的结合距离r为2.19 nm;用同步荧光技术初步考察了NP对BSA构象的影响.     

盐酸异丙肾上腺素与牛血清白蛋白相互作用

采用荧光猝灭法和毛细管区带电泳法研究了盐酸异丙肾上腺素（IH）与牛血清白蛋白（BSA）的相互作用。荧光猝灭法研究表明:IH对BSA有较强的荧光猝灭作用,根据Stern-Volmer方程得到猝灭速率常数（K_q）为2.53×10¹³ L·mol^-1·s^-1,该荧光猝灭属于静态猝灭。采用位点结合模型公式计算得结合常数为1.72×10⁴ L·mol^-1,结合位点数n为1;毛细管区带电泳法研究表明:IH与BSA的结合常数为4.07×10⁴ L·mol^-1,结合位点数n为1。     

手性钌配合物的合成、抗肿瘤活性及其与血清蛋白的相互作用

合成了手性钌配合物Δ, Λ-[Ru(bpy)₂(pyip)]²⁺, 通过元素分析、核磁共振、质谱和CD光谱对配合物进行了表征. 采用MTT法评价了3种异构体对多种肿瘤细胞株的体外抗肿瘤活性以及对正常细胞的毒性. 结果表明, Δ-[Ru(bpy)₂(pyip)]²⁺的抗肿瘤活性明显优于其异构体, 对A375, SW480, MCF-7和A549的半数抑制浓度低于顺铂. 通过荧光光谱法研究了在生理pH条件下, 手性钌配合物与牛血清白蛋白(BSA)之间的结合作用以及荧光猝灭机制. 依据Scatchard方程测定了结合常数和结合位点数, 根据热力学方程讨论了两者间的主要作用力类型. 结果表明, 钌配合物对牛血清白蛋白的荧光猝灭机制为静态猝灭. Δ-1, 1和Λ-1与牛血清白蛋白的结合常数分别为1.16×10⁵, 5.12×10⁴和3.64×10⁴, 结合位点数均为1, 主要作用力类型是静电作用. 钌配合物在体内能够被血清蛋白存储转运且结合时对蛋白构象无影响.     

土贝母皂苷II与人血清白蛋白相互作用机制的光谱研究

人血清白蛋白多种结合位点的存在使其成为许多药物可能的结合靶点. 土贝母皂苷具有广泛的生理和药理活性, 它与蛋白质相互作用机制的研究对于深入了解其药理药效具有重要的意义. 采用荧光光谱法研究了土贝母皂苷II (TBMSⅡ)与人血清白蛋白(HSA)之间的相互作用, 根据Stern-Volmer荧光淬灭方程计算得293, 298, 303, 308 K时TBMSⅡ与HSA相互作用的结合常数分别为1.002×10⁵, 0.701×10⁵, 0.514×10⁵, 0.411×10⁵ L•mol^－1. 由实验计算出热力学参数焓变ΔH为－44.829 kJ•mol^－1, 熵变ΔS为－57.497 J•mol^－1•K^－1, 表明分子间的氢键及疏水作用是TBMSⅡ-HSA复合物的主要作用力, 结合位点位于HSA的亚结构ⅡA, 这与分子模拟方法的结果相一致. 依据能量转移原理求得TBMSⅡ与HSA间的距离为4.95 nm|三维、同步荧光光谱及圆二色谱的结果表明TBMSⅡ的加入使HSA构象发生变化, α-螺旋结构有所下降.     

含磷三足体稀土铕(Ⅲ)配合物与牛血清白蛋白的作用机理

在pH=7.3的Tris-HCl缓冲溶液(模拟生理条件)中, 采用荧光光谱、 循环伏安曲线和紫外光谱研究了N-二(苯-二氨基甲酰基)甲基磷酸铕(Ⅲ)配合物[Eu(pic)₃L]与牛血清白蛋白(BSA)的相互作用. 实验结果表明: 配合物与BSA可以形成1∶1结合型无荧光复合物Eu(pic)₃L-BSA, Eu(pic)₃L对 BSA 内源荧光的猝灭类型为静态猝灭. 根据双对数回归方程计算出二者在不同温度下的结合常数K及结合位点数n, 通过热力学参数得出配合物与 BSA 之间以氢键和范德华力为主. 根据Foster的偶极-偶极无辐射能量转移机理可知配合物与BSA之间可能以偶极-偶极无辐射能量转移方式进行能量传递. 分别考察了Fe³⁺和Cu²⁺对配合物与BSA结合作用的影响, 推测Fe³⁺和Cu²⁺可能在配合物与BSA间起“离子架桥”作用, 使Eu(pic)₃L-BSA复合物的稳定性增强. 循环伏安法研究结果表明配合物与BSA相互作用形成无电活性的Eu(pic)₃L-BSA复合物, 使得溶液中游离的配合物浓度降低.     

新型药物2-甲基-2,4-二乙氧羰基-6-三氟甲氧基-1,2-二氢喹啉的合成及其与HSA的相互作用

合成了一种新化合物2-甲基-2,4-二乙氧羰基-6-三氟甲氧基-1,2-二氢喹啉(M DTDQ),采用共振光散射法(RLS)、荧光光谱法、紫外光谱法以及电化学阻抗法(EIS)研究了MDTDQ与人血清白蛋白(HSA)的作用机理。电化学阻抗及共振光散射光谱分析表明HSA与MDTDQ发生结合形成了复合物;MDTDQ对HSA有荧光猝灭作用,由Stern-Volmer方程以及紫外吸收光谱判断其猝灭过程主要为静态猝灭;通过双对数方程计算出298 K,304 K,310 K时两者的结合常数及其相应的结合位点数;根据热力学参数方程计算出△H、△S和△G的值分别为-64.28 k J/mol,-131.70 J·mol-1·K-1,-24.95k J/mol,推断两者之间的作用力类型主要是氢键和范德华力;由Frster非辐射能量转移理论得到MDTDQ与HSA的结合距离为2.85 nm;同步荧光光谱数据表明MDTDQ引起了HSA构象的变化。采用分子模拟对接分析了MDTDQ与HSA的结合,所得结论与实验研究结果一致。     

Spectroscopic studies on the interaction between riboflavin and albumins

The interactions between riboflavin (RF) and human and bovine serum albumin (HSA and BSA) were studied by using absorption and fluorescence spectroscopic methods. Intrinsic fluorescence emission spectra of serum albumin in the presence of RF show that the endogenous photosensitizer acts as a quencher. The decrease of fluorescence intensity at about 350 nm is attributed to changes in the environment of the protein fluorophores caused by the ligand. The quenching mechanisms of albumins by RF were discussed. The binding constants and binding site number were obtained at various temperatures. The distance between albumins and RF in the complexes suggests that the primary binding site for RF is close to tryptophan residue (Trp214) of HSA and Trp212 of BSA. The hydration process of albumins has also been discussed.     

盐酸拓扑替康与人血清白蛋白的相互作用及分子模拟

用荧光光谱法、分光光度法研究了盐酸拓扑替康(topotecan hydrochloride, 简记为THC)与人血清白蛋白(human serum albumins, HSA)的相互结合反应. 计算了反应的结合常数、结合位点数和热力学常数. 盐酸拓扑替康在人血清白蛋白上的结合位置与色氨酸残基间的距离为3.63 nm. 分子模型研究表明, 盐酸拓扑替康与人血清白蛋白的亚结构域IIA结合, 二者间的作用力主要为疏水作用, 此外, 蛋白质的丙氨酸(Ala-291)残基和天冬氨酸(Asp-256)残基与盐酸拓扑替康之间还存在氢键作用力.     

Binding of the bioactive component daphnetin to human serum albumin demonstrated using tryptophan fluorescence quenching

Daphnetin (7,8-dihydroxycoumarin), one of the major bioactive components isolated from Daphne koreane Nakai, has been used in traditional Chinese medicine for the treatment of coagulation disorders. It is also a chelator, an antioxidant and a protein kinase inhibitor. In this paper, a combination of intrinsic fluorescence, Fourier transform infrared (FT-IR) spectroscopy and circular dichroic (CD) spectroscopy has been used to characterize the binding between daphnetin and human serum albumin (HSA) under physiological conditions with drug concentrations of 6.7 x 10(-6) - 2.3 x 10(-5) mol x L(-1), and a HSA concentration of 1.5 x 10(-6) mol x L(-1). Changes in the CD spectra and FT-IR spectra were observed upon ligand binding, and the degree of tryptophan fluorescence quenching did change significantly in the complexes. These data have proved the change in protein secondary structure accompanying ligand binding. The change in tryptophan fluorescence intensity was used to determine the binding constants. The thermodynamic parameters, the enthalpy change (DeltaH) and the entropy change (DeltaS) were calculated to be -12.45 kJ x mol(-1)and 52.48 J x mol(-1) x K(-1) according to the van't Hoff equation, which indicated that hydrophobic and electrostatic interactions played the main role in the binding of daphnetin to HSA, in accordance with the results of calculations performed on a Silicon Graphics Ocatane2 workstation. In addition, the binding distance between daphnetin and HSA was obtained (4.02 nm) based on the Forster energy transfer theory.     

FLUORESCENCE INVESTIGATIONS OF ALBUMIN FROM PATIENTS WITH FAMILIAL DYSALBUMINEMIC HYPERTHYROXINEMIA*

Familial dysalbuminemic hyperthyroxinemia (FDH) is an autosomal dominant syndrome in which clinically euthyroid patients have elevated total thyroxine levels. These high serum thyroxine levels are traceable to altered binding of thyroxine to the patient's albumin. Albumin from FDH patients and normal volunteers have been purified. Reverse-phase and ion-exchange high performance liquid chromatography and sodium dodecyl sulfate-polyacrylamide gel electrophoresis on the FDH-human serum albumin (HSA) samples show a single band that comigrates with normal HSA. In both protein solutions the intrinsic fluorescence, upon 280 nm excitation, is predominantly due to the single tryptophan residue. The quantum yield of this intrinsic fluorescence in the FDH-HSA solutions is, however, reduced relative to that of HSA. Furthermore, the “average” lifetime value of the tryptophan emission in the FDH-HSA sample is less than that of normal HSA, consistent with its reduced quantum yield. The binding of thyroxine to both albumins effectively quenches the tryptophan emission probably via a nonradiative energy transfer mechanism. Time-resolved data suggest that the albumin from the dysalbuminemic patients is actually an approximately equimolar mixture of normal HSA and FDH-HSA indicative of heterologous expression. Quenching of the intrinsic HSA and FDH-HSA fluorescence by serial additions of thyroxine showed enhanced quenching of FDH-HSA relative to HSA at any T4 to albumin mole ratio, therefore supporting earlier reports of increased thyroxine affinity to FDH-HSA.     

Spectroscopic studies on the interaction of bovine (BSA) and human (HSA) serum albumins with ionic surfactants

Bovine (BSA) and human (HSA) serum albumins are frequently used in biophysical and biochemical studies since they have a similar folding, a well known primary structure, and they have been associated with the binding of many different categories of small molecules. One important difference of BSA and HSA is the fact that bovine albumin has two tryptophan residues while human albumin has a unique tryptophan. In this work results are presented for the interaction of BSA and HSA with several ionic surfactants, namely, anionic sodium dodecyl sulfate (SDS), cationic cethyltrimethylammonium chloride (CTAC) and zwitterionic N-hexadecyl-N,N-dimethyl-3-ammonium-1-propanesulfonate (HPS), as monitored by fluorescence spectroscopy of intrinsic tryptophans and circular dichroism spectroscopy. On the interaction of all three surfactants with BSA, at low concentrations, a quenching of fluorescence takes place and Stern-Volmer analysis allowed to estimate their 'effective' association constants to the protein: for SDS, CTAC and HPS at pH 7.0 these constants are, respectively, (1.4+/-0.1) x 10(5) M(-1), (8.9+/-0.1) x 10(3) M(-1) and (1.4+/-0.1) x 10(4) M(-1). A blue shift of maximum emission is observed from 345 to 330 nm upon surfactant binding. Analysis of fluorescence emission spectra allowed to separate three species in solution which were associated to native protein, a surfactant protein complex and partially denatured protein. The binding at low surfactant concentrations follows a Hill plot model displaying positive cooperativity and a number of surfactant binding sites very close to the number of cationic or anionic residues present in the protein. Circular dichroism data corroborated the partial loss of secondary structure upon surfactant addition showing the high stability of serum albumin. The interaction of the surfactants with HSA showed an enhancement of fluorescence at low concentrations, opposite to the effect on BSA, consistent with the existence of a unique buried tryptophan residue in this protein with considerable static quenching in the native state. The effects of surfactants at low concentrations were very similar to those of myristic acid suggesting a non specific binding through hydrophobic interaction modulated by eletrostatic interactions. The changes in the vicinity of the tryptophan residues are discussed based on the recently published crystallographic structure of HSA myristate complex (S. Curry et al., Nat. Struct. Biol. 5 (1998) 827).     

The Photochemical Study of HSA and BSA with Resonance Light-Scattering and Fluorescence Spectra

In recent years, people have paid close attention to the physiological harms induced byultraviolet (UV) irradiation. The serum albumin, which constitutes 60% of blood plasma,has very important physiological functions. Therefore, to study their photochemicalreaction is of great significance. The metal ions, little molecules and medicines etcinteracting with HSA or BSA have been reported ','*"', but it has not been repoFted aboutusing RLS to study the photochemical reaction of HSA or BSA.…     

Characterization of subdomain IIA binding site of human serum albumin in its native, unfolded, and refolded states using small molecular probes

Subdomain IIA binding site of human serum albumin (HSA) was characterized by examining the change in HSA fluorescence in the native, unfolded, and refolded states. The study was carried out in the absence and presence of small molecular probes using steady-state and time-resolved fluorescence measurements. 2-Pyridone, 3-pyridone, and 4-pyridone bear similar molecular structures to those found in many drugs and are used here as probes. They are found to specifically bind in subdomain IIA and cause a reduction in the fluorescence intensity and lifetime of the Trp-214 residue in native HSA which is located in the same subdomain. The efficiency of energy transfer from Trp-214 fluorescence to the probes was found to depend on the degree of the spectral overlap between the donor's fluorescence and the acceptor's absorption. After probe binding in subdomain IIA, the distance between the donor and acceptor was calculated using Forster theory. The calculated quenching rate constants and binding constants were also shown to depend on the degree of spectral overlap. The results point to a static quenching mechanism operating in the complexes. Denaturation of HSA in the presence of guanidine hydrochloride (GdnHCl) starts at [GdnHCl] > 1.0 M and is complete at [GdnHCl] > or = 6.0 M. Upon unfolding, two fluorescence peaks were observed. One peak was assigned to the fluorescence of Trp-214 in a polar environment, and the other peak was assigned to tyrosine fluorescence. A reduction of the fluorescence intensity of the two peaks upon binding of the probes to the denatured HSA indicates that Tyr-263 in subdomain IIA is one of the tyrosine residues responsible for the second fluorescence peak. The results were confirmed by measuring the fluorescence spectra and lifetimes of denatured HSA at different excitation wavelengths, and of L-tryptophan and L-tyrosine free in buffer. The measured lifetimes of denatured HSA are typical of tryptophan in a polar environment and are slightly reduced upon probe binding. Dilution of the denatured HSA by buffer results in a partial refolding of subdomain IIA. This partial refolding is attributed to some swelling of the binding site caused by water. The swelling prevents a full recovery from the denatured state.     

Interaction of tetrandrine with human serum albumin: a fluorescence quenching study.

The interaction of tetrandrine with human serum albumin (HSA) was studied by measuring fluorescence quenching spectra, synchronous fluorescence spectra and ultra-violet spectra. The fluorescence quenching spectra of HSA in the presence of tetrandrine showed that tetrandrine quenched the fluorescence of HSA. The quenching constants of tetrandrine on HSA were determined using the Stern-Volmer equation. Static quenching and non-radiation energy transfer were the two main reasons leading to the fluorescence quenching of HSA by tetrandrine. According to the F?rster theory of non-radiation energy transfer, the binding distances (r) and the binding constants (K(A)) were obtained. The thermodynamic parameters obtained in this study revealed that the interaction between tetrandrine and HSA was mainly driven by a hydrophobic force. The conformational changes of HSA were investigated by synchronous spectrum studies.     

Fluorescence spectroscopic studies on binding of a flavonoid antioxidant quercetin to serum albumins

Binding of quercetin to human serum albumin (HSA) was studied and the binding constant measured by following the red-shifted absorption spectrum of quercetin in the presence of HSA and the quenching of the intrinsic protein fluorescence in the presence of different concentrations of quercetin. Fluorescence lifetime measurements of HSA showed decrease in the average lifetimes indicating binding at a location, near the tryptophan moiety, and the possibility of fluorescence energy transfer between excited tryptophan and quercetin. Critical transfer distance (R _o ) was determined, from which the mean distance between tryptophan-214 in HSA and quercetin was calculated. The above studies were also carried out with bovine serum albumin (BSA).     

Binding of wogonin to human serum albumin: a common binding site of wogonin in subdomain IIA

The binding of wogonin to human serum albumin (HSA) has been studied by spectroscopic method including circular dichroism (CD), infrared spectra (IR) and fluorescence spectra. The fluorescence properties of HSA were examined in presence of wogonin and the fluorescence intensity of HSA was significantly decreased in the presence of wogonin. The binding parameters of wogonin were studied from the fluorescence decreasing of HSA by the fluoremetric titrations. The Stern-Volmer plots indicated that the binding of wogonin to HSA at 296, 303, 310 K is characterized by one binding site with the binding constant K(S-V) at 1.872 x 10(5), 1.561 x 10(5), 1.392 x 10(5), respectively, which are good agreement with the results from the Scatchard plots. The binding process was exothermic, enthalpy driven and spontaneous, as indicated by the thermodynamic analyses, and the major part of the binding energy is hydrophobic interaction, which were consistent with the result of molecule modelling study, and there are also a numbers of hydrogen bonds between wogonin and HSA. Furthermore, the displacement experiments indicate that wogonin can bind to the subdomain IIA, that is, the site I of HSA, which is also good agreement with the result of molecule modelling study.