Spectroscopic studies of the interaction between hypocrellin B and human serum albumin

Previous work has proved that hypocrellin B (HB) binds to human serum albumin (HSA) at a specific site instead of distributed randomly on the surface of a protein. In the current work, further investigation by using bilirubin as a site I marker indicates that HB can compete for the same site with bilirubin, suggesting that the HB binding site is located at sub-domain IIA (site I) of HSA. Moreover, bound to HSA, the HB fluorescence was found to be pH sensitive in physiological range (pH 6.0-8.0). The increasing of binding constant of HB to HSA in the pH range 6-8 also indicates that the N<-->B transition modulates the microenvironment changes of the binding site and influences considerably the binding between HB and HSA. Furthermore, picosecond time-resolved fluorescence spectra of HB-HSA complex in PBS indicate an additional short-lived component compared to that for HB in benzene, which may be assigned to the process of electron transfer from Trp-214 to HB.     

Tween-80胶束对苝醌类光敏剂基态和激发态的保护作用

用Tween-80非离子型胶束增溶竹红菌甲素、乙素(HA、HB)及金丝桃蒽酮(HYP)等苝醌类光敏剂,发现该胶束对HA的基态和激发态都有保护作用.相对于含水有机体系,HA在胶束中基态的pKa值升高,荧光量子产率增大,光敏反应产生的活性中间体1O2和·0H的产额增加,从而提高了其光敏活性,这在光敏损伤作用中具有重要的生物学意义.实验还发现,Tween-80胶束对HB及HYP的保护作用与HA类似,而且保护作用与苝醌的结构有关,这对筛选光敏剂作为光疗药物具有指导作用.     

Interactions of hypocrellin B with hyaluronan and photo-induced interactions

In the current work, the molecular recognition and interaction were studied by taking advantages of the environmentally sensitive fluorescence of hypocrellin B (HB) and the structural knowledge of hyaluronan (HYA), a polysaccharide over-expressed in tumor cells or tissues. Interestingly, it was found that, binding to HYA, the absorbance of HB would be greatly strengthened, suggesting HB fitting to a hydrophobic environment in HYA, while the fluorescence seriously quenched at pH 7.0, which was very distinct from the binding of HB to proteins, liposome, other polysaccharide molecules or HYA at pH 2.0. Synchronously, the particle size of HYA would become bigger after interaction with HB, suggesting an aggregation of HYA. Considering the spectral responses of HB and the particle size change of HYA, a specific interaction of HB with HYA was proposed, that is, an HB molecule would link two HYA molecules not only by hydrophobic interaction but also by formations of intermolecular hydrogen bonds at physiological pH values. Furthermore, the estimated binding constant suggests a quite high affinity of HB to HYA. Besides, an oxygen-dependent degradation of HYA and photobleaching of HB were observed via photosensitization of HB.     

Photogeneration of free radicals (*OH and HB*-) and singlet oxygen (1O2) by hypocrellin B in TX-100 micelles microsurroundings

To solve the problems faced in clinical use of hypocrellins, a water-soluble preparation of Hypocrellin B (HB), HB-Triton X-100 (TX-100) micelles, was prepared. To evaluate the photodynamic activity, the free radicals (^•OH and HB^•¯) and singlet oxygen (

1

O

2

) generated via photosensitization of the preparation in aqueous solution were detected by using electron paramagnetic resonance (EPR) and spectrophotometric methods. It was observed that

1

O

2

was formed with a quantum yield of 0.72, similar to that for HB in organic solvents, further, hydroxyl radicals (

•

OH) could also be efficiently produced by the new preparation, which have never before been detected following HB photoactivities. In addition, the semiquinone anion radicals (HB^•-) could also be generated via the self-electron transfer between an excited triplet state and a ground state molecule. The accumulation of HB^•- would replace that of

•

OH or

1

O

2

with the depletion of oxygen in the system. All these findings suggested that the HB-TX-100 micelles could play the photodynamic action through not only the type I mechanism by free radicals (^•OH, O₂^•- and HB^•-) but also the type II mechanism by singlet oxygen (

1

O

2

). It can be concluded further that the new preparation basically maintains the inherent photodynamic activity of HB, or even higher.     

Characterization of the interaction between prostacyclin and human serum albumin using a fluorescent analogue, 2,6-dichloro-4-aminophenol iloprost

We synthesized a fluorescent probe, 2,6-dichloro-4-aminophenol iloprost or dichlorohydroxyphenylamide of iloprost (DCHPA-iloprost) by reacting the stable prostacyclin analog, iloprost (ZK 35 374), with 2,6-dichloro-4-aminophenol with a yield of 60%. This probe exhibited an optical spectrum which overlapped with the emission spectrum of the sole tryptophan of human serum albumin (HSA). Energy transfer from the tryptophan residue to the phenol moiety of DCHPA-iloprost was observed. We utilized this donor-quenching phenomenon to quantitate the binding stoichiometry and affinity as well as the association rate of DCHPA-iloprost binding to HSA. As DCHPA-iloprost showed similar binding characteristics similar to those of iloprost and prostacyclin and competed with iloprost for HSA binding sites, we used DCHPA-iloprost as a probe to locate the binding domain of prostacyclin (PGI2) in HSA. The distance between the tryptophan indole and the phenol group of DCHPA-iloprost was estimated to be 15-18 A. Because iloprost binding to HSA was competitive with warfarin and not with free fatty acid, we propose that PGI2 binds to the 'domain 2' of HSA was competitive with warfarin and not with free fatty acid, we propose that PGI2 binds to the 'domain 2' of HSA molecules. A possible molecular mechanism by which HSA reduces the chemical degradation of PGI2 and stabilizes its activity could be derived from this model.     

Binding of a spin-labelled photoallergen to human serum albumin

The binding site for 3,3',4',5-tetrachlorosalicylanilide (T4CS), a potent photoallergen, on human serum albumin (HSA) was studied by electron spin resonance spectroscopy using a spin-labelled analogue 3,5-dichlorosalicylamido-4-(2,2,6,6-tetramethylpiperidine 1-oxyl) (DCS-TEMPO) of T4CS in the absence of ultraviolet irradiation. DCS-TEMPO bound non-covalently (K = 5.8 X 10(6) M-1) to one major binding site on HSA. This binding site could be blocked by the photochemical binding of T4CS to the protein. Limited tryptic digestion of HSA or chemical modification of its single tryptophan residue with 2-hydroxy-5-nitrobenzyl bromide was found to reduce the binding constant of the T4CS/DCS-TEMPO-binding site. These observations are in good agreement with earlier conclusions on the nature of the T4CS-binding site and suggest a location for this site close to the single tryptophan residue of the HSA molecule.     

A novel method for the preparation of amino-substituted hypocrellin B.

A series of amino-substituted hypocrellins derived from hypocrellin B (HB) were synthesized by a novel mild method, in which the peri-hydroxylated perylenequinone structure of hypocrellin was preserved by the reaction of HB with an amine. The red absorption of the resulting products was significantly enhanced relative to the parent hypocrellins, which will significantly improve its photodynamic therapy effectiveness.     

Transport of liposomal and albumin loaded curcumin to living cells: an absorption and fluorescence spectroscopic study

Curcumin, a lipid soluble antioxidant, exhibits solvent and medium sensitive absorption and fluorescence properties. Using such changes, the average binding constants of curcumin to phosphatidylcholine (PC) liposomes and human serum albumin (HSA) were estimated to be 2.5 x 10(4) M(-1) and 6.1 x 10(4) M(-1) respectively. From the studies on temperature dependent fluorescence anisotropy of liposomal curcumin and its fluorescence quenching by acrylamide and iodide, it was concluded that curcumin is located in the gel phase of the liposomes. Similarly from the studies on quenching of tryptophan fluorescence in HSA by curcumin, it was found to be in the same domain as that of tryptophan. Both liposomal and HSA vehicles were examined for the transfer of curcumin to spleen lymphocyte cells, EL4 lymphoma cell line and compared with aqueous DMSO vehicles. From these studies it was found that liposomal vehicle is capable of loading more curcumin in to cells than HSA or aqueous-DMSO, and lymphoma cells show preferential uptake of curcumin to lymphocytes. The fluorescence of curcumin in EL4 lymphoma cells was found to be significantly higher as compared to the lymphocytes. The present study demonstrates a simple and quantitative method of estimation of curcumin delivered to cells by different vehicles using absorption and fluorescence spectroscopy.     

A spectroscopic study of the interaction of isoflavones with human serum albumin

Genistein and daidzein, the major isoflavones present in soybeans, possess a wide spectrum of physiological and pharmacological functions. The binding of genistein to human serum albumin (HSA) has been investigated by equilibrium dialysis, fluorescence measurements, CD and molecular visualization. One mole of genistein is bound per mole of HSA with a binding constant of 1.5 +/- 0.2 x 10(5) m(-1). Binding of genistein to HSA precludes the attachment of daidzein. The ability of HSA to bind genistein is found to be lost when the tryptophan residue of albumin is modified with N-bromosuccinimide. At 27 degrees C (pH 7.4), van't Hoff's enthalpy, entropy and free energy changes that accompany the binding are found to be -13.16 kcal x mol(-1), -21 cal x mol(-1) K(-1) and -6.86 kcal x mol(-1), respectively. Temperature and ionic strength dependence and competitive binding measurements of genistein with HSA in the presence of fatty acids and 8-anilino-1-naphthalene sulfonic acid have suggested the involvement of both hydrophobic and ionic interactions in the genistein-HSA binding. Binding measurements of genistein with BSA and HSA, and those in the presence of warfarin and 2,3,5-tri-iodobenzoic acid and F?rster energy transfer measurements have been used for deducing the binding pocket on HSA. Fluorescence anisotropy measurements of daidzein bound and then displaced with warfarin, 2,3,5-tri-iodobenzoic acid or diazepam confirm the binding of daidzein and genistein to subdomain IIA of HSA. The ability of HSA to form ternery complexes with other neutral molecules such as warfarin, which also binds within the subdomain IIA pocket, increases our understanding of the binding dynamics of exogenous drugs to HSA.     

Spatial relationship between the prodan site,Trp-214, and Cys-34 residues in human serum albumin and loss of structure through incremental unfolding

Prodan (6-propionyl-2-(dimethylamino)-naphthalene), a competitive inhibitor of warfarin binding to human serum albumin (HSA) at drug site I, was used to determine the inter- and intradomain distances of HSA. The fluorescence resonance energy transfer (FRET) distances between prodan and Trp-214, prodan and 7-(diethyl amino)-4-methylcoumarin 3-maleimide (CM)-modified Cys-34, and Trp-214 and CM-Cys-34 were determined to be 25.5 +/- 0.5 A, 33.1 +/- 0.8 A, and 32.4 +/- 1 A, respectively. FRET analysis showed that low concentration of palmitic acid (5 microM) increased the interdomain distance between the Trp-214 in domain II and CM-Cys-34 in domain I by approximately 5 A without perturbing the secondary structure of HSA and the immediate environment of Trp-214. Palmitic acid (5 microM) increased the prodan fluorescence by increasing the quantum yield of bound prodan without altering the tryptophan environment. However, palmitic acid (>10 microM) decreased the prodan fluorescence and increased the tryptophan fluorescence. Our results indicate that the high affinity palmitic acid binding site is located at the interface of domains I and II. On the basis of our measurements, a schematic model representing the drug site-1, Trp-214, and Cys-34 along with the palmitic acid sites has been constructed. In addition, prodan fluorescence, FRET, and ligand binding were used to monitor guanidine hydrochloride-induced denaturation of HSA. An analysis of the equilibrium unfolding data suggests that HSA undergoes a two-state unfolding transition with no detectable intermediate. However, kinetic analysis using multiple probes and thermal denaturation studies showed that the unfolding of the prodan site in HSA preceded the unfolding of tryptophan environment. In addition, the separation of domain I and II occurred before the global unfolding of the protein. The data support the idea that HSA loses its structure incrementally during its unfolding.     

Development of tryptophan-modified human serum albumin columns for site-specific studies of drug–protein interactions by high-performance affinity chromatography

Human serum albumin (HSA) is one of the main proteins involved in the binding of drugs and small solutes in blood or serum. This study examined the changes in chromatographic properties that occur for immobilized HSA following the chemical modification of HSA's lone tryptophan residue (Trp-214). Trp-214 was reacted with o-nitrophenylsulfenyl chloride, followed by immobilization of the modified protein and normal HSA onto separate silica-based HPLC supports. The binding properties of the modified and normal HSA were then analyzed and compared by using frontal analysis and zonal elution experiments employing R/S-warfarin and l-tryptophan as probe compounds for the warfarin and indole binding regions of HSA. The modified HSA was found to have the same number of binding sites as normal HSA for R-warfarin and l-tryptophan but lower association equilibrium constants for these test solutes. Zonal elution studies with R- and S-warfarin on the modified HSA column demonstrated the importance of Trp-214 in determining the stereoselective binding of HSA for these agents. These studies also indicated that tryptophan modification can alter HSA-based separations for chiral solutes.     

Amphiphilic corroles bind tightly to human serum albumin

Amphiphilic 2,17-bis-sulfonato-5,10,15(trispentafluorophenyl)corrole (2) and its Ga and Mn complexes (2-Ga and 2-Mn) form tightly bound noncovalent conjugates with human serum albumin (HSA). Protein-induced changes in the electronic absorption, emission, and circular dichroism spectra of these corroles, as well as results obtained from HPLC profiles of the conjugates and selective fluorescence quenching of the single HSA tryptophan, are interpreted in terms of multiple corrole:HSA binding sites. High-affinity binding sites, close to the unique tryptophan, are fully occupied at very low concentrations. At biologically relevant HSA concentrations (2-3 orders of magnitude larger than those employed in our studies), all corroles (2, 2-Ga, and 2-Mn) may be considered as fully conjugated.     

Deciphering the binding of carbendazim (fungicide) with human serum albumin: A multi-spectroscopic and molecular modelling studies

Carbendazim is a benzimidazole fungicide used to control the fungal invasion. However, its exposure might lead to potential health problems. The present study evaluates the interaction of carbendazim (CAR) with human serum albumin (HSA) which is an important drug carrier protein and plays a very crucial role in the transportation of small molecules. A number of biophysical techniques were employed to investigate the binding of CAR with HSA. The increased UV-absorption of HSA on titrating with CAR suggests the formation of HSA–CAR complex and it could be due to the exposure of aromatic residues. The fluorescence study confirmed that CAR quenches the fluorescence of HSA and showed the static mode of quenching. CAR (50 µM) quenches around 56.14% of the HSA fluorescence. The quenching constant, binding constant, number of binding site and free energy change was calculated by fluorescence quenching experiment. Competitive displacement assay showed Sudlow’s site I as the primary binding site of CAR on HSA. The synchronous fluorescence study revealed the perturbation in the microenvironment around tyrosine and tryptophan residues upon binding of CAR to HSA. The circular dichroism results suggested that the binding of CAR to HSA altered its secondary structure. Molecular docking experiment demonstrated the binding of CAR to Sudlow’s site I of HSA. Docking studies suggested that the hydrogen bonding, van der Waals and pi-alkyl are playing role in the interaction of CAR with HSA. The study confirmed the conformational changes within HSA upon binding of CAR.     

Interaction of the photosensitization products of oestrone with DNA: comparison with the horseradish peroxidase catalyzed reaction

The interaction with DNA of [4-14C]oestrone upon photosensitization with hematoporphyrin (HP) as a photosensitizer has been investigated. By means of Sephadex LH-20 gel filtration and extraction with dichloromethane it was found that, after irradiation (lambda greater than 425 nm) of a solution of HP, DNA and [4-14C]oestrone 21% of the radiolabel was associated with DNA. If DNA was added after irradiation 23% was bound to DNA, whereas 25% of the oestrone remained after photoreaction under the conditions applied. The binding occurs via the reactive 10 beta-hydroperoxy-1,4-estradien-3,17-dione, which is the only product after photosensitization of oestrone. The hydroperoxide has a strong interaction with DNA compared with that of other steroids. By repeated precipitation with 5 M NaCl and ethanol the association can be broken. It is reported, that binding of oestrone to protein induced by both photosensitization and horseradish peroxidase (HRPO)/H2O2 is irreversible, but that the amount of binding to DNA is dependent on the method of determination. However, neither the hydroperoxide nor its reduced product, a p-quinol, is intermediate or product in the HRPO catalyzed reaction of oestrogens. The tight association of the hydroperoxide product of oestrone with DNA, which may proceed via hydrogen bonding between the -OOH group and oxygen atoms of the backbone phosphate groups or of the furanose ring, might be a cause of chemical modification of DNA and of mutagenic effects.     

Role of salt bridge(s) in the binding and photoconversion of bilirubin bound to high affinity site on human serum albumin

The role of salt bridge(s) (between epsilon-NH(2) groups of lysine residues of human serum albumin (HSA) and carboxyl groups of bilirubin) in the binding and photoconversion of bilirubin bound to high affinity site on HSA was investigated by covalent modification of approximately 20% internal (buried) lysine residues of HSA with acetic anhydride, succinic anhydride and O-methylisourea and white light irradiation of their complexes with bilirubin. The different HSA derivatives, namely, acetylated HSA (aHSA), succinylated HSA (sHSA) and guanidinated HSA (gHSA), thus obtained, were found to be homogeneous with respect to charge and size and characterized in detail in terms of mean residue ellipticity, Stokes radius, tryptophan fluorescence, bilirubin binding and the photochemistry of their complexes with bilirubin. All the three derivatives retained helical contents and molecular size (Stokes radius) similar to HSA except for sHSA which showed a slight increase in the Stokes radius from 3.56 to 3.64 nm. Further, fluorescence properties of aHSA and sHSA were also found to be different from HSA and gHSA. Based on difference spectral change, fluorescence quenching and fluorescence enhancement results of bilirubin bound to HSA and its derivatives, nearly 46 and 48% reduction in bilirubin binding was observed in the case of aHSA and sHSA, respectively. Both aHSA and sHSA showed a decrease of 8- and 10-fold, respectively, in association constant compared to native HSA. Although the bisignate circular dichroism (CD) spectra of an equimolar (1:1) bilirubin-HSA complex was retained by all three HSA derivatives, the intensity of both positive and negative CD Cotton effects decreased significantly in both aHSA and sHSA. gHSA which retained net charge identical to native HSA, showed little decrease in bilirubin binding and the intensity of bisignate CD Cotton effects. The photochemical reaction of bilirubin bound to aHSA and sHSA produced opposite results to those observed with HSA and gHSA. A brief (2 min) irradiation of an equimolar complex of bilirubin with both aHSA and sHSA accompanied a rapid shift (14-15 nm) in the absorption spectrum of the bound pigment towards the blue region and almost complete elimination of negative CD Cotton effects while only moderately affecting the magnitude of positive CD Cotton effects. On the other hand, similar treatment of the complexes of bilirubin with HSA and gHSA did not show any change in the absorption spectrum, only a slight decrease in the intensity of both positive and negative CD Cotton effects was observed. The fluorescence intensity of bilirubin bound to HSA and gHSA was increased upon irradiation with white light and after 30 min it was nearly twice the value observed at 0 min irradiation. Interestingly, no change in the fluorescence intensity of bilirubin bound either to aHSA or sHSA was observed upon irradiation, even on increasing the duration of irradiation to 1 h. Taken together, the results on fluorescence quenching, fluorescence enhancement, CD spectral changes and visible absorption spectroscopy suggest that salt bridge(s) of the type (-COO(-).(+)H(3)N-) in which the epsilon-NH(2) group(s) contributed by lysine residues, are not only involved in the enantioselective binding of bilirubin but also in the stereospecific photoisomerization of bilirubin bound to a high affinity site on HSA.     

Interaction of bovine (BSA) and human (HSA) serum albumins with ionic surfactants: spectroscopy and modelling

The binding of several different categories of small molecules to bovine (BSA) and human (HSA) serum albumins has been studied for many years through different spectroscopic techniques to elucidate details of the protein structure and binding mechanism. In this work we present the results of the study of the interactions of BSA and HSA with the anionic sodium dodecyl sulfate (SDS), cationic cethyltrimethylammonium chloride (CTAC) and zwitterionic N-hexadecyl-N,N-dimethyl-3-ammonium-1-propanesulfonate (HPS) monitored by fluorescence spectroscopy of the intrinsic tryptophans at pH 5.0. Similarly to pH 7.0 and 9.0, at low concentrations, the interaction of BSA with these surfactants shows a quenching of fluorescence with Stern-Volmer quenching constants of (1.1+/-0.1)x10(4) M(-1), (3.2+/-0.1)x10(3) M(-1) and (2.1+/-0.1)x10(3) M(-1) for SDS, HPS and CTAC, respectively, which are associated to the 'effective' association constants to the protein. On the interaction of these surfactants with HSA, an opposite effect was observed as compared to BSA, i.e., an enhancement of fluorescence takes place. For both proteins, at low surfactant concentrations, a positive cooperativity was observed and the Hill plot model was used to estimate the number of surfactant binding sites, as well as the association constants of the surfactants to the proteins. It is worthy of notice that the binding constants for the surfactants at pH 5.0 are lower as compared to pH 7.0 and 9.0. This is probably due to fact that the protein at this acid pH is quite compact reducing the accessibility of the surfactants to the hydrophobic cavities in the binding sites. The interaction of myristic acid with both proteins shows a similar fluorescence behaviour, suggesting that the mechanism of the interaction is the same. Recently published crystallographic studies of HSA-myristate complex were used to perform a modelling study with the aim to explain the fluorescence results. The crystallographic structure reveals that a total of five myristic acid molecules are asymmetrically bound in the macromolecule. Three of these sites correspond to higher affinity ones and correlate with high association constants described in the literature. Our models for BSA and HSA with bound SDS suggest that the surfactant could be bound at the same sites as those reported in the crystal structure for the fatty acid. The differences in tryptophan vicinity upon surfactant binding are explored in the models in order to explain the observed spectroscopic changes. For BSA the quenching is due to a direct contact of a surfactant molecule with the indole of W131 residue. It is clear that the binding site in BSA which is very close, in contact with tryptophan W131, corresponds to a lower affinity site, explaining the lower binding constants obtained from fluorescence studies. In the case of HSA the enhancement of fluorescence is due to the removal of static quenching of W214 residue in the intact protein caused by nearby residues in the vicinity of this tryptophan.     

The role of electrostatic interactions in human serum albumin binding and stabilization by halothane

Electrostatic interactions have been proposed as a potentially important force for anesthetics and protein binding but have not yet been tested directly. In the present study, we used wild-type human serum albumin (HSA) and specific site-directed mutants as a native protein model to investigate the role of electrostatic interactions in halothane binding. Structural geometry analysis of the HSA-halothane complex predicted an absence of significant electrostatic interactions, and direct binding (tryptophan fluorescence and zonal elution chromatography) and stability experiments (hydrogen exchange) confirmed that loss of charge in the binding sites, by charged to uncharged mutations and by changing ionic strength of the buffer, generally increased both regional (tryptophan region) and global halothane/HSA affinity. The results indicate that electrostatic interactions (full charges) either do not contribute or diminish halothane binding to HSA, leaving only the more general hydrophobic and van der Waals forces as the major contributors to the binding interaction.     

Chromatographic analysis of carbamazepine binding to human serum albumin

In this study, high-performance affinity chromatography was used to characterize the binding of carbamazepine to an immobilized human serum albumin (HSA) column. Frontal analysis was first used to determine the association equilibrium constant and binding capacity for carbamazepine on this column at various temperatures. The non-specific binding of carbamazepine within the column was also considered. The results indicated that carbamazepine had a single binding site on HSA with an association equilibrium constant of 5.3 x 10(3)M(-1) at pH 7.4 and 37 degrees C. This was confirmed through zonal elution self-competition studies. The value of DeltaG for this reaction was -5.35 kcal/mol at 37 degrees C, with an associated change in enthalpy (DeltaH) of -6.45 kcal/mol and a change in entropy (DeltaS) of -3.56 cal/molK. The location of this binding region was examined by competitive zonal elution experiments using probe compounds with known sites on HSA. It was found that carbamazepine had direct competition with l-tryptophan, a probe for the indole-benzodiazepine site of HSA, but allosteric interactions with probes for the warfarin, tamoxifen and digitoxin sites. Changes in the pH, ionic strength, and organic modifier content of the mobile phase were used to identify the predominant forces in the carbamazepine-HSA interaction.     

厄他培南与人血清清蛋白体外相互作用的理化特性

研究新型碳青霉烯类抗菌素厄他培南（ertapenem, ERT）与人血清清蛋白（human serum albumin,HSA）的体外相互作用的物理化学特性。模拟生理条件下,计算机模拟技术结合荧光光谱和紫外光谱,研究ERT与HSA相互作用机制,荧光光谱实验中,Kq 值远大于2.0×1010 L·(mol·s)-1,ERT对HSA荧光猝灭的Stern-Volmer 曲线有良好的线性关系,表明ERT与HSA的相互作用表现为静态结合过程。HSA的最大发射波长发生轻微红移,说明HSA的微环境发生了改变。ERT与HSA的分子结合距离r值较小,说明发生能量转移现象。同步荧光技术解析出ERT对HSA的结构域微区构象产生影响,使色氨酸残基周围的微区构象及结合位域的疏水性发生改变。荧光相图技术解析出ERT与HSA相互反应呈线性,说明HSA构象型态的变迁为“二态”模型。HSA与ERT相互作用的热力学参数及分子模拟技术建立ERT-HSA结合模型,表明ERT与HSA的相互作用力主要是疏水作用力,兼有氢键作用力的存在。荧光偏振定量证明,HSA与ERT相互作用过程中生成了非共价复合物。光谱实验与计算机模拟结果基本一致,其结果可为研究ERT与HSA相互作用本质提供一定参考。