Structural and spectroscopic studies of the native hemocyanin from Maia squinado and its structural subunits

The dodecameric hemocyanin of the crab Maia squinado contains five major electrophoretically separable polypeptide chains (structural subunits) which have been purified by FPLC ion exchange chromatography. The various proteins have been characterized by fluorescence spectroscopy, combined with fluorescence quenching studies, using acrylamide, caesium chloride and potassium iodide as tryptophan quenchers. The results show that the tryptophyl side chains of dodecameric Hc are deeply buried in hydrophobic regions of the hemocyanin aggregates and the quenching efficiency values for the native Hc in comparison with those from the constituent subunits are two to four times less. The conformational stabilities of the native dodecameric aggregate and its isolated structural subunits towards various denaturants (pH, temperature, guanidinium hydrochloride) indicate that the quaternary structure is stabilized by hydrophilic and polar forces, whereby, both, the oxy- and apo-forms of the protein have been considered. The critical temperatures for the structural subunits, Tc, determined by fluorescence spectroscopy, are in the region of 50-60 degrees C, coinciding with the melting temperatures, Tm, determined by CD spectroscopy. The free energy of stabilization in water, deltaG(D)H2O, toward guanidinium hydrochloride is about two times higher for the dodecamer as compared to the isolated subunits. These studies reveal that oligomerization between functional subunits has a stabilizing effect on the whole molecule and differences in the primary structures result in different stabilities of the subunits.     

A novel Cu,Zn superoxide dismutase from the fungal strain Humicola lutea 110: isolation and physico-chemical characterization

The fungal strain Humicola lutea 110 produces a mangan- and a copper zinc-containing superoxide dismutases (SOD). In this study, the purification, N-terminal sequence and spectroscopic properties of the new Cu,Zn SOD are described. The preparation of the pure metalloenzyme was achieved via treatment of the strain with acetone followed by gel and ion exchange chromatography. The protein consists of 302 amino acid residues and has a molecular mass of approximately 32 kDa, as determined by PAG electrophoresis and 3100 U mg-1 protein-specific activity. It is a dimeric enzyme with two identical subunits of 15,950 Da, as indicated by SDS-PAGE, mass spectroscopic and amino acid analysis. The N-terminal sequence analysis of the Cu,Zn SOD from the fungal strain revealed a high degree of structural homology with enzymes from other eukaryotic sources. Conformational stability and reversibility of unfolding of the dimeric enzyme were determined by fluorescence and circular dichroism (CD) spectroscopy. The critical temperature of deviation from linearity (Tc) of the Arrhenius plot ln (Q-1(-1)) vs. 1/T was calculated to be 68 degrees C and the respective activation energy for the thermal deactivation of the excited indole chromophores is 42 kcal mol-1. The melting temperatures (Tm) were determined by CD measurements to be 69 degrees C for the holo- and 61 degrees C for the apo-enzyme. The fluorescence emission of the Cu,Zn SOD is dominated by 'buried' tryptophyl chromophores. Removal of the copper-dioxygen system from the active site caused a 4-fold increase of the fluorescence quantum yield and a 10 nm shift of the emission maximum position towards higher wavelength.     

Structure and stability of arthropodan hemocyanin Limulus polyphemus

In the hemolymph of many arthropodan species, respiratory copper proteins of high molecular weight, termed hemocyanins (Hcs) are dissolved. In this communication, we report on the protein stability of different hemocyanin species (Crustacea and Chelicerata) using fluorescence spectroscopy. Five to seven major electrophoretically separable protein chains (structural subunits) were purified by fast protein liquid chromatography (FPLC) ion exchange chromatography from different hemocyanins with very high sequence homology of the active site regions binding copper ions (CuA and CuB), and especially the relative sequence positions of histidine (His) and tryptophan (Trp) residues of these protein segments are in all cases identical. The conformational stabilities of the native dodecameric aggregates and their isolated structural subunits towards various denaturants (pH and guanidine hydrochloride (Gdn.HCl)) indicate that the quaternary structure is stabilized by hydrophilic and polar forces, whereby both, the oxy- and apo-forms of the protein are considered. These two classes of Crustacea and Chelicerata Hcs have the similar Trp-fluorescence quantum yields, but different values of lambda(max) emission (about 325 and 337 nm, respectively). Differences in the quantum yields are observed of the oxy- and apo-forms, which must be attributed to the fluorescence quenching effect of the two copper ions (CuA and CuB) in the active site. The position of emission maximum indicates tryptophan side chains are situated in a non-polar environment. Denaturation studies of Hcs by Gdn.HCl indicate that the denaturation process consists of two steps: dissociation of the native molecule into its structural subunits and denaturation of the subunits at concentrations >1.5M Gdn.HCl. Two steps of denaturation are also observed after keeping the protein in buffer solutions at different pH values with different pH-stability for holo-oxy and apo-Hc forms.     

Structural studies of LNA:RNA duplexes by NMR: conformations and implications for RNase H activity

We have used NMR and CD spectroscopy to study the conformations of modified oligonucleotides (locked nucleic acid, LNA) containing a conformationally restricted nucleotide (T(L)) with a 2'-O,4'-C-methylene bridge. We have investigated two LNA:RNA duplexes, d(CTGAT(L)ATGC):r(GCAUAUCAG) and d(CT(L)GAT(L)AT(L)GC):r(GCAUAUCAG), along with the unmodified DNA:RNA reference duplex. Increases in the melting temperatures of +9.6 degrees C and +8.1 degrees C per modification relative to the unmodified duplex were observed for these two LNA:RNA sequences. The three duplexes all adopt right-handed helix conformations and form normal Watson-Crick base pairs with all the bases in the anti conformation. Sugar conformations were determined from measurements of scalar coupling constants in the sugar rings and distance information derived from 1H-1H NOE measurements; all the sugars in the RNA strands of the three duplexes adopt an N-type conformation (A-type structure), whereas the sugars in the DNA strands change from an equilibrium between S- and N-type conformations in the unmodified duplex towards more of the N-type conformation when modified nucleotides are introduced. The presence of three modified T(L) nucleotides induces drastic conformational shifts of the remaining unmodified nucleotides of the DNA strand, changing all the sugar conformations except those of the terminal sugars to the N type. The CD spectra of the three duplexes confirm the structural changes described above. On the basis of the results reported herein, we suggest that the observed conformational changes can be used to tune LNA:RNA duplexes into substrates for RNase H: Partly modified LNA:RNA duplexes may adopt a duplex structure between the standard A and B types, thereby making the RNA strand amenable to RNase H-mediated degradation.     

A mechanistic approach on the self-organization of the two-component thermoreversible hydrogel of riboflavin and melamine

The riboflavin (R) and melamine (M) supramolecular complex in the mole ratio of 3:1 (RM31) produces a thermoreversible gel in aqueous medium. The gelation mechanism has been elucidated from morphological investigations using optical, electron, and atomic force microscopy together with time-dependent circular dichroism (CD) and photoluminescence (PL) spectroscopy. Optical microscopy indicates spherulitic morphology at lower gelation temperature (相似文献   

光谱法研究核壳量子点CdTe/CdS与牛血清白蛋白的相互作用

应用荧光光谱、圆二色光谱和紫外吸收光谱等技术研究核壳量子点CdTe/CdS与牛血清白蛋白(BSA)相互作用的结果表明,CdTe/CdS对BSA的荧光猝灭机理为静态猝灭。根据不同温度下量子点对BSA的荧光猝灭作用计算了结合常数、热力学参数,证明了量子点与BSA相互作用力主要是范德华力或氢键作用力。探讨了量子点对BSA构象的影响。     

Comparative studies of structural properties and conformational changes of proteins by analytical ultracentrifugation and other techniques

Analytical ultracentrifugation is a powerful tool for investigating the size of proteins in solution, especially by measuring sedimentation and diffusion coefficients and molar masses. Several further molecular parameters such as frictional ratios, axial ratios of hydrodynamic models, and Stokes radii allow a rough estimate of the protein overall structure. Sedimentation analysis may also be applied efficaciously for monitoring conformational changes of proteins occurring upon ligand binding or denaturation. For the determination of very small changes in shape, however, great care and a series of precautions are required. We investigated the enzymes citrate synthase and malate synthase in the absence and in the presence of ligands, in order to study the structural properties of the proteins and their ligand complexes. We also compared the results of the ultracentrifugal analysis with the results of other solution techniques such as UV absorption, fluorescence spectroscopy, circular dichroism, and small-angle x-ray scattering on the one hand, and the crystallographic 3D structure of citrate synthase on the other. The spectroscopic methods may be used as efficient and rapid tools for screening the occurrence of conformational changes caused by alterations of chromophores and fluorophores. The structural information provided by small-angle scattering (e.g., radii of gyration, maximum particle diameters, vclumes and surface areas) can be used to establish quantitative correlations between solution scattering and hydrodynamic data. In this context, however, knowledge or qualified assumptions of partial specific volumes and hydration are additionally required. Good agreement was reached between small-angle scattering and ultracentrifugal data, and also with crystallographic data if protein hydration was considered properly. The given approaches may be used to predict hydrodynamic properties if x-ray data are available, and for many verifications of other structural data, e.g., Stokes radii, diffusion coefficients, axial and frictional ratios determined by independent methods.Abbreviations materials AcCoA acetyl coenzyme A - CoA coenzyme A - CS citrate synthase (EC 4.1.3.7) - DTT dithiothreitol - GdrnCl guanidinium chloride - MS malate synthase (EC 4.1.3.2.)Methods - AUC analytical ultracentrifugation - CD circular dichroism - EM fluorescence emission spectroscopy - EX fluorescence excitation spectroscopy - SAS small-angle scattering - SAXS small-angle x-ray scattering - UV ultraviolet absorption spectroscopy - XD x-ray diffraction Models OE oblate ellipsoidal model - PE prolate ellipsoidal model     

Adsorption, desorption, and conformational changes of lysozyme from thermosensitive nanomagnetic particles

Adsorption of globular protein, lysozyme, on thermosensitive poly(N-isopropylacrylamide) coated nanomagnetic particles was studied at different temperatures and pHs. It was observed that a maximum amount of lysozyme was adsorbed at a temperature above the lower critical solution temperature (LCST) (32 degrees C ) of the polymer and at the isoelectric point (pI=11) of lysozyme. Desorption was carried out using either NaH2PO4 (pH 4) or NaSCN (pH 6) as the desorbing agents. Conformational changes in lysozyme on desorption from nanomagnetic particles was studied by circular dichroism and intrinsic fluorescence spectroscopy. Lysozyme desorbed by NaH2PO4 showed very little conformational changes while lysozyme desorbed by NaSCN showed significant conformational changes, and 87% enzymatic activity was retained in the desorbed enzyme for desorption by NaH2PO4.     

Conformational dynamics at the active site of alpha-chymotrypsin and enzymatic activity

The role of dynamical flexibility at the active site of a proteolytic enzyme alpha-chymotrypsin (CHT) has been correlated with its catalytic activity. The temperature-dependent efficiency of catalysis reveals a bell-shaped feature with a peak at 37 degrees C, the typical body temperature of homeothermal animals. The overall structural integrity of the enzyme in our experimental temperature range has been confirmed from dynamic light scattering (DLS) and circular dichroism (CD) studies. We have followed the dynamical evolution at the active site of CHT with temperature using picosecond-resolved fluorescence anisotropy of anthraniloyl probe (covalently attached to the serine-195 residue) and a substrate mimic (inhibitor) proflavin. The conformational dynamics at the active site is found to have a distinct connection with the enzyme functionality. The conformational flexibility of the enzyme is also evidenced from the compressibility studies on the enzyme. The site selective fluorescence detected circular dichroism (FDCD) studies reveal that the conformational flexibility of the enzyme has an effect on the structural perturbation at the active site. We have also proposed the possible implications of the dynamics in the associated energetics.     

Effects of guanidinium ions on the conformational structure of glucose oxidase studied by electrochemistry, spectroscopy, and theoretical calculations: towards developing a chemical-induced protein conformation assay

Understanding conformation transitions of proteins in the presence of a chemical denaturant is a topic of great interest because the rich information contained in chemical unfolding is of fundamental importance for proteomic and pharmaceutical research. In this work, the conformational structure changes of glucose oxidase (GOx) induced by guanidinium ions (Gdm(+)) were studied in detail by a combination of electrochemical methods, various spectroscopic techniques including ultraviolet-visible (UV-vis) absorption, fluorescence, Fourier transform infrared (FTIR), and circular dichroism (CD) spectroscopy, molecular dynamics (MD) simulations, and density functional theory (DFT) calculations with the purpose of revealing the mechanism of chemical unfolding of proteins. The results indicated that GOx underwent substantial conformational changes both at the secondary and tertiary structure levels after interacting with Gdm(+) ions. The interaction of GOx with the chemical denaturant resulted in a disturbance of the structure of the flavin prosthetic group (FAD moiety) that induced the moiety to become less exposed to solvent than that in the native protein molecule. The calculation from quantitative second-derivative infrared and CD spectra showed that Gdm(+) ions induced the conversion of α-helix to β-sheet structures. MD simulations and DFT calculations revealed that Gdm(+) ions could enter the active pocket of the GOx molecule and interact with the FAD group, leading to a significant alteration in the structural characteristics and hydrogen bond networks formed between FAD and the surrounding amino acid residues. These alterations in the conformational structure of GOx resulted in a significant decrease in the catalytic activity of the enzyme to glucose oxidation. The study essentially provides an effective way for investigating the mechanism of chemical denaturant-induced protein unfolding, and this approach can be used for assessing the effect of drug molecules on proteins.     

Effect of pH and guanidine hydrochloride on the conformation of 57 kDa rat liver nuclear thyroid hormone binding protein measured by fluorescence.

The denaturation of the 57 kilodalton (kDa) rat liver nuclear thyroid hormone binding protein (NTHB) by pH and guanidine hydrochloride (GdnHCl) has been investigated with the fluorescence method. The acid and alkaline fluorescence quenching suggests that the structure of NTHB is invariant in the relatively narrow pH region of approximately pH 7-9. A cooperative conformational transition occurred in GdnHCl concentrations of 1.5-2.5 m. The apparent free energy of unfolding of NTHB, delta G(appH2O) was evaluated as 6.31 (+/- 0.12) kcal.mol-1 at pH 7.7, 25 degrees C.     

Spectroscopic studies on the effect of temperature on pH-induced folded states of human serum albumin

Human serum albumin (HSA) is a very important multi-domain transporter protein in the circulatory system responsible for carriage of various kinds of ligands within the physiological system. HSA is also known to undergo conformational transformation at different pH(s) and temperatures. In this report we have studied the binding interactions of a photosensitizing drug, protoporphyrin IX (PPIX) with various conformers of HSA at different temperatures using picosecond time-resolved fluorescence spectroscopy. Also, using dynamic light scattering (DLS) and circular dichroism (CD) spectroscopy we have followed the structural transition of various conformers of HSA at different temperatures. Ensuring the intact binding of PPIX to various conformers of HSA at different temperatures as revealed through time-resolved fluorescence anisotropy decay and significant spectral overlap of emission of Trp214 residue (donor) in domain-IIA and absorption of PPIX (acceptor) bound to domain-IB of HSA, we have applied F?rster's resonance energy transfer (FRET) technique to determine the interdomain separation under various environmental conditions. The alkali-induced conformer of HSA shows almost no change in donor-acceptor distance in contrast to the native and acid-induced conformers of HSA, which show a decrease in distance with increase in temperature. Through this study the non-covalently bound PPIX is shown to be an efficient FRET probe in reporting the different temperature-induced folded states of HSA in buffer solutions of widely differing pH values.     

Study on the interaction of puerarin with lysozyme by spectroscopic methods

The interaction between lysozyme (LYSO) and puerarin has been studied at three temperatures (294, 302 and 310K) through/using fluorescence spectroscopy and circular dichroism (CD). The LYSO fluorescence was quenched by the binding of puerarin to LYSO. The binding constants and the number of binding sites can be calculated from the data obtained from fluorescence quenching experiments. According to the van't Hoff equation, the standard enthalpy change (DeltaH degrees ) and standard entropy change (DeltaS degrees ) for the reaction were calculated to be 17.47kJ/mol and 163.5J/molK. It indicated that the hydrophobic interactions play a main role in the binding of puerarin to LYSO. In addition, the distance between puerarin (acceptor) and tryptophan residues of LYSO (donor) was estimated to be 1.47nm on the basis of fluorescence energy transfer. The changes of LYSO secondary structure in the presence of puerarin were observed from CD spectroscopy.     

Restricting the conformational heterogeneity of RNA by specific incorporation of 8-bromoguanosine

In an effort to reduce the conformational heterogeneity of RNA, the modified nucleobase 8-bromoguanosine (8BrG) was introduced into oligonucleotides having the hairpin tetraloop motif YNMG (Y = U or C and M = C or A). Purine nucleobases with bromine at position eight are known to preferentially adopt the syn conformation as nucleosides. The hairpin tetraloop motif YNMG was chosen as a model system because it has a syn guanosine at position four of the loop that is essential for thermodynamic stability. Thermodynamic and structural characterization of modified oligonucleotides with the hairpin sequences UUCG, CGCG, and CGAG by UV-melting and NMR spectroscopy revealed that 8BrG substitution has a small effect upon the hairpin conformation, while the duplex conformation is strongly destabilized (DeltaDeltaG degrees 37 approximately +4.7 kcal mol-1), thus inhibiting dimerization. These results support a model in which 8BrG substitution shifts the hairpin-duplex equilibrium constant toward the hairpin conformation by destabilizing the duplex. This methodology should be useful for limiting conformational heterogeneity in large RNAs, with potential applications in structural biology and enzymology.     

Fluorescence properties and stability of dioxygen--binding functional units from the Rapana thomasiana hemocyanin subunit RHSS2

Molecular aggregates of the Rapana thomasiana hemocyanin are composed of two structural subunits, RHSS1 and RHSS2, each of which contains eight functional units (FUs) reversibly binding dioxygen. Multiunit fragments and individual 50-60 kDa FUs from RHSS2 were isolated and characterized by electron and fluorescence spectroscopy. The units have similar fluorescence parameters demonstrating that the tryptophyl side chains are located in the hydrophobic core of the globular folded regions. The copper-dioxygen system at the binuclear active site stabilizes considerably the native protein structure and quenches the indole emission. The removal of this system decreased the 'melting points' drastically Tm by 13-20 degrees C and increased 2-4 times the fluorescence quantum yields. The individual FUs differ considerably in their thermostability. The activation energy for the thermal deactivation of the excited tryptophyl residues of the apo-FUs is lower compared to that of the whole molluscan apo-Hcs.     

Determination of antifungal proteins in soil by liquid chromatography

A liquid chromatography method was developed for the determination of antifungal/antimicrobial proteins Rs-AFP1 and Dm-AMP1 in sandy loam soils. The extraction of these highly basic proteins was achieved by mechanical shaking with aqueous Tris buffer pH 9 containing guanidinium thiocyanate salt (4.1 M), EDTA and nonionic polyoxyethylene 20 cetyl ether, Brij-58 detergent. The extracts were cleaned up on Oasis HLB polymer solid-phase extraction cartridges and quantified by liquid chromatography fluorescence detection based on the fluorescence properties of the tryptophan content of these proteins. The detector response was linear for 0.3-10 microg mL(-1). Procedural recoveries were tested in the range 10-100 mg kg(-1). The limit of quantification was 10 mg kg(-1 )protein in the soil sample representing the lowest validated fortification level. The antifungal proteins were found to be stable in soil extract tested up to 9 days when stored at 4 degrees C.     

Native and unfolded cytochrome c--comparison of dynamics using 2D-IR vibrational echo spectroscopy

Unfolded vs native CO-coordinated horse heart cytochrome c (h-cyt c) and a heme axial methionine mutant cyt c552 from Hydrogenobacter thermophilus ( Ht-M61A) are studied by IR absorption spectroscopy and ultrafast 2D-IR vibrational echo spectroscopy of the CO stretching mode. The unfolding is induced by guanidinium hydrochloride (GuHCl). The CO IR absorption spectra for both h-cyt c and Ht-M61A shift to the red as the GuHCl concentration is increased through the concentration region over which unfolding occurs. The spectra for the unfolded state are substantially broader than the spectra for the native proteins. A plot of the CO peak position vs GuHCl concentration produces a sigmoidal curve that overlays the concentration-dependent circular dichroism (CD) data of the CO-coordinated forms of both Ht-M61A and h-cyt c within experimental error. The coincidence of the CO peak shift curve with the CD curves demonstrates that the CO vibrational frequency is sensitive to the structural changes induced by the denaturant. 2D-IR vibrational echo experiments are performed on native Ht-M61A and on the protein in low- and high-concentration GuHCl solutions. The 2D-IR vibrational echo is sensitive to the global protein structural dynamics on time scales from subpicosecond to greater than 100 ps through the change in the shape of the 2D spectrum with time (spectral diffusion). At the high GuHCl concentration (5.1 M), at which Ht-M61A is essentially fully denatured as judged by CD, a very large reduction in dynamics is observed compared to the native protein within the approximately 100 ps time window of the experiment. The results suggest the denatured protein may be in a glassy-like state involving hydrophobic collapse around the heme.     

Conformational substates of horse heart cytochrome c exhibit different thermal unfolding of the heme cavity

The charge transfer (CT) band at 695 nm in the spectrum of ferri-cytochrome c is highly asymmetric, indicating conformational heterogeneity due to the coexistence of different conformational substates. We have measured the respective band profile of horse heart ferri-cytochrome c as a function of temperature between 283 K (10 degrees C) and 333 K (60 degrees C) and found that the well-known decrease of the absorptivity is wavenumber-dependent and exhibits a biphasic behavior. This indicates that the underlying conformational substates differ in their thermodynamic stability with respect to the structural changes associated with the disappearance of the 695 nm band, which eventually (at high temperatures) involves the replacement of M80 by a nearby lysine residue. Our data further indicates that the thermal unfolding process involves two structurally different intermediate states.     

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.     

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.