Changes in the lipid and protein components of thymus cell membrane during lipid peroxidation]

Nonenzymatic lipid peroxidation in thymus cell plasma membranes was studied. The composition of lipid and protein components, intensity of fluorescence of the membrane probes (1-anilinonaphthalene-8-sulfonate, 4-dimethylaminochalcon, eosin, pyronin and rhodamine), fluorescence polarization of tryptophan residues of membrane proteins and quenching by acrylamide of intrinsic fluorescence of proteins were determined. Induction of lipid peroxidation by the Fe(2+)-ascorbate system caused changes in the composition and structure of lipids. This was paralleled with changes in the structural-dynamic organization of membrane proteins, transition of some peripheral proteins to the water phase and increased solubilization of integral proteins by Triton X-100.     

Some aspects of studies of thermal transitions in proteins by means of their intrinsic fluorescence

The changes in intrinsic fluorescence parameters induced by thermal transitions in proteins are developed on the background of the common thermal fluorescence quenching due to an activation of collisions between the excited chromophores and neighbouring quenching groups. Two methods of separation of the thermai quenching and conformational change contributions to the temperature dependence of the fluorescence parameters are presented. One is based on the use of the linearity of the plots of the reciprocal fluorescence quantum yield, l/q, vs. the t/η ratio (T. temperature; η, solvent viscosity) for native proteins containing a single fluorescing chromophore (T.L. Bushueva, E.P. Busel and E.A. Burstein, Biochim. Biophys. Acta 534 (1978) 141). The other method is based on a consideration of the phase plots for the tryptophan fluorescence of proteins (fluorescence intensity at a fixed wavelength vs. intensity at any other fixed wavelength). The methods have been used for a study of the thermal transitions in Mg²⁺-loaded whiting parvalbumin (tryptophan fluorescence), Mg²⁺-loaded pike parvalbumins pI 4.2 (tyrosine fluorescence) and pI 5.0 (phenylalanine fluorescence), and Ca²⁺-loaded bovine α-lactalbumin (tryptophan fluorescence). The thermal denaturation curves for the parvalbumins show two-stepped character. The main change of the protein conformation occurs at the higher temperature step. Comparison of the fluorescence data with the microcalorimetry results shows that the maxima of the asymmetric heat sorption peaks for pike parvalbumins correlate with the mid-points of the higher temperature steps of the fluorimetric curves.     

HIV-1 integrase catalytic core: molecular dynamics and simulated fluorescence decays.

Two molecular dynamics simulations have been carried out on the HIV-1 integrase catalytic core starting from fully determined crystal structures. During the first one, performed in the absence of divalent cation (6-ns long), the catalytic core took on two main conformations. The conformational transition occurs at approximately 3.4 ns. In contrast, during the second one, in the presence of Mg(2+) (4-ns long), there were no such changes. The molecular dynamics simulations were used to compute the fluorescence intensity decays emitted by the four tryptophan residues considered as the only chromophores. The decay was computed by following, frame by frame, the amount of chromophores that remained excited at a certain time after light absorption. The simulation took into account the quenching through electron transfer to the peptide bond and the fluorescence resonance energy transfer between the chromophores. The fit to the experimental intensity decays obtained at 5 degrees C and at 30 degrees C is very good. The fluorescence anisotropy decays were also simulated. Interestingly, the fit to the experimental anisotropy decay was excellent at 5 degrees C and rather poor at 30 degrees C. Various hypotheses such as dimerization and abnormal increase of uncorrelated internal motions are discussed.     

Mechanisms of tryptophan fluorescence shifts in proteins

Tryptophan fluorescence wavelength is widely used as a tool to monitor changes in proteins and to make inferences regarding local structure and dynamics. We have predicted the fluorescence wavelengths of 19 tryptophans in 16 proteins, starting with crystal structures and using a hybrid quantum mechanical-classical molecular dynamics method with the assumption that only electrostatic interactions of the tryptophan ring electron density with the surrounding protein and solvent affect the transition energy. With only one adjustable parameter, the scaling of the quantum mechanical atomic charges as seen by the protein/solvent environment, the mean absolute deviation between predicted and observed fluorescence maximum wavelength is 6 nm. The modeling of electrostatic interactions, including hydration, in proteins is vital to understanding function and structure, and this study helps to assess the effectiveness of current electrostatic models.     

Fluorescence of Alexa Fluor Dye Tracks Protein Folding

Fluorescence spectroscopy is an important tool for the characterization of protein folding. Often, a protein is labeled with appropriate fluorescent donor and acceptor probes and folding-induced changes in Förster Resonance Energy Transfer (FRET) are monitored. However, conformational changes of the protein potentially affect fluorescence properties of both probes, thereby profoundly complicating interpretation of FRET data. In this study, we assess the effects protein folding has on fluorescence properties of Alexa Fluor 488 (A488), which is commonly used as FRET donor. Here, A488 is covalently attached to Cys69 of apoflavodoxin from Azotobacter vinelandii. Although coupling of A488 slightly destabilizes apoflavodoxin, the three-state folding of this protein, which involves a molten globule intermediate, is unaffected. Upon folding of apoflavodoxin, fluorescence emission intensity of A488 changes significantly. To illuminate the molecular sources of this alteration, we applied steady state and time-resolved fluorescence techniques. The results obtained show that tryptophans cause folding-induced changes in quenching of Alexa dye. Compared to unfolded protein, static quenching of A488 is increased in the molten globule. Upon populating the native state both static and dynamic quenching of A488 decrease considerably. We show that fluorescence quenching of Alexa Fluor dyes is a sensitive reporter of conformational changes during protein folding.     

Can pyrene probes be used to measure lateral pressure profiles of lipid membranes? Perspective through atomistic simulations

The lateral pressure profile of lipid bilayers has gained a lot of attention, since changes in the pressure profile have been suggested to shift the membrane protein conformational equilibrium. This relation has been mostly studied with theoretical methods, especially with molecular dynamics simulations, since established methods to measure the lateral pressure profile experimentally have not been available. The only experiments that have attempted to gauge the lateral pressure profile have been done by using di-pyrenyl-phosphatidylcholine (di-pyr-PC) probes. In these experiments, the excimer/monomer fluorescence ratio has been assumed to represent the lateral pressure in the location of the pyrene moieties. Here, we consider the validity of this assumption through atomistic molecular dynamics simulations in a DOPC (dioleoylphosphatidylcholine) membrane, which hosts di-pyr-PC probes with different acyl chain lengths. Based on the simulations, we calculate the pyrene dimerization rate and the lateral pressure at the location of the pyrenes. The dimerization rates are compared with the results of di-pyr-PC probes simulated in vacuum. The comparison indicates that the lateral pressure is not the dominant determinant of the excimer/monomer fluorescence ratio. Thus, the results do not support the usage of di-pyr-PC molecules to measure the shape of the lateral pressure profile. We yet discuss how the probes could potentially be exploited to gain qualitative insight of the changes in pressure profile when lipid composition is altered.     

Molecular basis of action of HyBeacon fluorogenic probes: a spectroscopic and molecular dynamics study

HyBeacons, novel DNA probes for ultra-rapid detection of single nucleotide polymorphisms, contain a fluorophore covalently attached via a linker group to an internal nucleotide. As the probe does not require a quencher or self-complementarity to function, this study investigates the molecular-level mechanism underlying the increase of fluorescence intensity on hybridization of HyBeacons with target DNA. Spectroscopic ultraviolet-visible and fluorimetric studies, combined with molecular dynamics simulations, indicate projection of the fluorophore moiety away from the target-probe duplex into aqueous solution, although specific linker-DNA interactions are populated. Based on evidence from this study, we propose that for HyBeacons, the mechanism of increased fluorescence on hybridization is due to disruption of quenching interactions in the single-stranded probe DNA between the fluorophore and nucleobases. Hybridization leads to an extended linker conformation, removing the fluorophore from the immediate vicinity of the DNA bases.     

Distance mapping in proteins using fluorescence spectroscopy: the tryptophan-induced quenching (TrIQ) method

Studying the interplay between protein structure and function remains a daunting task. Especially lacking are methods for measuring structural changes in real time. Here we report our most recent improvements to a method that can be used to address such challenges. This method, which we now call tryptophan-induced quenching (TrIQ), provides a straightforward, sensitive, and inexpensive way to address questions of conformational dynamics and short-range protein interactions. Importantly, TrIQ only occurs over relatively short distances (～5-15 ?), making it complementary to traditional fluorescence resonance energy transfer (FRET) methods that occur over distances too large for precise studies of protein structure. As implied in the name, TrIQ measures the efficient quenching induced in some fluorophores by tryptophan (Trp). We present here our analysis of the TrIQ effect for five different fluorophores that span a range of sizes and spectral properties. Each probe was attached to four different cysteine residues on T4 lysozyme, and the extent of TrIQ caused by a nearby Trp was measured. Our results show that, at least for smaller probes, the extent of TrIQ is distance dependent. Moreover, we also demonstrate how TrIQ data can be analyzed to determine the fraction of fluorophores involved in a static, nonfluorescent complex with Trp. Based on this analysis, our study shows that each fluorophore has a different TrIQ profile, or "sphere of quenching", which correlates with its size, rotational flexibility, and the length of attachment linker. This TrIQ-based "sphere of quenching" is unique to every Trp-probe pair and reflects the distance within which one can expect to see the TrIQ effect. Thus,TrIQ provides a straightforward, readily accessible approach for mapping distances within proteins and monitoring conformational changes using fluorescence spectroscopy.     

Gangliosides asymmetrically alter the membrane order in cultured PC-12 cells

Exogenous gangliosides readily associate with the cell membranes and produce marked effects on cell growth and differentiation. We have studied the effect of bovine brain gangliosides (BBG) on the membrane dynamics of intact cells. The structural and dynamic changes in the cell membrane were monitored by the fluorescence probes DPH, TMA-DPH and laurdan. Incorporation of BBG into the cell membrane decreased the fluorescence intensity, lifetime and the steady state anisotropy of TMA-DPH. Analysis of the time resolved anisotropy decay by wobbling in the cone model revealed that BBG decreased the order parameter, and increased the cone angle without altering the rotational relaxation rate. The fluorescence intensity and lifetime of DPH were unaffected by BBG incorporation, however, a modest increase was observed in the steady state anisotropy. BBG incorporation reduced the total fluorescence intensity of laurdan with pronounced quenching of the 440-nm band. The wavelength sensitivity of generalized polarization of laurdan manifested an ordered liquid crystalline environment of the probe in the cell membrane. BBG incorporation reduced the GP values and augmented the liquid crystalline behavior of the cell membrane. BBG incorporation also influenced the permeability of cell membranes to cations. An influx of Na+ and Ca2+ and an efflux of K+ was observed. The data demonstrate that incorporation of gangliosides into the cell membrane substantially enhances the disorder and hydration of the lipid bilayer region near the exoplasmic surface. The inner core region near the center of the bilayer becomes slightly more ordered and remains highly hydrophobic. Such changes in the structure and dynamics of the membrane could play an important role in modulation of transmembrane signaling events by the gangliosides.     

Fluorescein-labeled oligonucleotides for real-time pcr: using the inherent quenching of deoxyguanosine nucleotides

Fluorescein-labeled oligonucleotide probes can be used to continuously monitor the polymerase chain reaction. Depending on the sequence, the fluorescence intensity of the probe is either increased or decreased by hybridization. The greatest effect is probe quenching by hybridization to amplicons containing deoxyguanosine nucleotides (Gs), giving a sequence-specific decrease in fluorescence as product accumulates. Quenching of the probes by Gs is position dependent. A 25% decrease in fluorescence of 5'-labeled probes was observed with a G at the first position of the 3'-dangling end. Additional Gs can increase quenching to about 40%. This change in fluorescence with hybridization allows real-time quantification and mutation detection with a simple single labeled probe. Quantification of the initial template copy number is possible by monitoring fluorescence at each cycle at a constant temperature. Mutation detection by Tm estimates from melting curve analysis for factor V Leiden, hemoglobin C, hemoglobin S, the thermolabile mutation of methylenetetrahydrofolate reductase, and the cystic fibrosis-associated deletion F508del is demonstrated. By using the inherent quenching of deoxyguanosine nucleotides in the amplicon, complicated probe designs involving internal quenching can be avoided.     

Joint determination by Brownian dynamics and fluorescence quenching of the in-depth location profile of biomolecules in membranes

The in-depth molar distribution function of fluorophores is revealed by a new methodology for fluorescence quenching data analysis in membranes. Brownian dynamics simulation was used to study the in-depth location profile of quenchers. A Lorentzian profile was reached. Since the Stern-Volmer equation is valid at every depth in the membrane for low quencher concentrations, the molar distribution of the fluorophore (also regarded as a Lorentzian) can be achieved. The average location and the broadness of the fluorophore distribution can be calculated. The importance of the knowledge of the location width is demonstrated and discussed, since this parameter reveals important conclusions on structural features of the interaction of membranes with probes and biomolecules (e.g., conformational freedom in proteins), as well as photophysical properties (e.g., differential fluorophore quantum yields). Subsequent use of this methodology by the reader does not, necessarily, involve the performance of simulations and is not limited to the use of Lorentzian function distributions.     

Mutation in hinge region of lactose repressor protein alters physical and functional properties

A mutant of the Escherichia coli lactose repressor (BG124) in which serine at position 77 is replaced by leucine has been examined by physical methods. Consistent with the phenotypic character of this i-d mutant, BG124 protein did not bind lactose operator specifically, but did bind to DNA nonspecifically. Titration with inducer monitoring tryptophan fluorescence changes yielded a biphasic saturation curve, and Scatchard and Hill plots of the fluorescence and equilibrium dialysis data demonstrated heterogeneity of inducer binding sites. Although ultraviolet difference spectra and potassium iodide quenching of fluorescence indicated that BG124 repressor has structural distinctions from wild-type protein, circular dichroism spectra and acrylamide quenching of fluorescence for the two proteins were quite similar. A significantly greater increase of 1-anilino-8-naphthalenesulfonate fluorescence was observed in the presence of mutant versus wild-type repressor. Unlike wild-type behavior, changes in both 1-anilino-8-naphthalenesulfonate fluorescence intensity and maximum emission wavelength in response to inducer were found for the BG124 protein. These results are consistent with conformational alterations in the interface between NH2-terminal and core domains of this mutant repressor. The single amino acid alteration in the hinge between the core and NH2 terminus yields conformational effects which influence physical and functional properties associated with both domains.     

Use of fluorescence probes 1-aniline-8-naphthalene sulfonate and pyrene for studying the localisation of proteins in inner membranes from wheat etioplasts

The fluorescence probes 1-aniline-8-naphthalene sulfonate (ANS) and pyrene were applied for characterisation of the light-induced changes in etioplast inner membranes (EPIMs) from 7 d-old dark-grown wheat seedlings (Triticum aestivum L. cv. Pobeda). The major aim was to obtain information about the localisation of membrane proteins in the EPIMs, using probes situated in different regions of the membranes. The quenching of tryptophan fluorescence showed tha the main parts of proteins were accessible to the pyrene buried in the lipid bilayer which suggests that most of the proteins also enter the lipid bilayer. The substantial quenching of the tryptophan fluorescence by the surface-situated ANS demonstrated that a part of the tryptophan residues was probably localised close to the membrane surface. The registered changes after irradiation could be explained by the presence of large aggregates of NADPH-protochlorophyllide oxidoreductase (POR), protochlorophyllide (PChlide) and NADPH in membranes that start to disconnect and redistribute along the prothylakoids. This revised version was published online in August 2006 with corrections to the Cover Date.     

Multisite phosphorylation and binding alter conformational dynamics of the 4E-BP2 protein

Intrinsically disordered proteins (IDPs) play critical roles in regulatory protein interactions, but detailed structural/dynamic characterization of their ensembles remain challenging, both in isolation and when they form dynamic “fuzzy” complexes. Such is the case for mRNA cap-dependent translation initiation, which is regulated by the interaction of the predominantly folded eukaryotic initiation factor 4E (eIF4E) with the intrinsically disordered eIF4E binding proteins (4E-BPs) in a phosphorylation-dependent manner. Single-molecule Förster resonance energy transfer showed that the conformational changes of 4E-BP2 induced by binding to eIF4E are non-uniform along the sequence; while a central region containing both motifs that bind to eIF4E expands and becomes stiffer, the C-terminal region is less affected. Fluorescence anisotropy decay revealed a non-uniform segmental flexibility around six different labeling sites along the chain. Dynamic quenching of these fluorescent probes by intrinsic aromatic residues measured via fluorescence correlation spectroscopy report on transient intra- and inter-molecular contacts on nanosecond-to-microsecond timescales. Upon hyperphosphorylation, which induces folding of ～40 residues in 4E-BP2, the quenching rates decreased at most labeling sites. The chain dynamics around sites in the C-terminal region far away from the two binding motifs significantly increased upon binding to eIF4E, suggesting that this region is also involved in the highly dynamic 4E-BP2:eIF4E complex. Our time-resolved fluorescence data paint a sequence-level rigidity map of three states of 4E-BP2 differing in phosphorylation or binding status and distinguish regions that form contacts with eIF4E. This study adds complementary structural and dynamics information to recent studies of 4E-BP2, and it constitutes an important step toward a mechanistic understanding of this important IDP via integrative modeling.     

Structural determinants of the intrinsic fluorescence emission in notexin and phospholipase A2 enzymes

Fluorescence measurements of the homologous proteins, notexin and PLA₂ enzymes fromNaja naja atra, Naja nigricollis, and Hemachatus haemachatus venoms, showed that the wavelength of maximum emission and the quantum yield of their intrinsic fluorescence emission spectra were different. To verify the factors which affected their fluorescence characteristics, the dynamics of tryptophan residues in those homologous proteins were studied by quenching with acrylamide, iodide, and cesium. The degrees of exposure of tryptophanyl groups in notexin and PLA₂ enzymes assessed by acrylamide quenching were found to be the major factor that determined their fluorescence characteristics. However, the positively charged groups surrounding tryptophan residues of PLA₂ enzymes fromN. naja atra andN. nigricollis venoms might affect the quantum yield of their fluorophores. Tryptophan residues of notexin were in an environment with less fluctuation, which did not allow free diffusion of ionic quencher. This might render its typtophan residues to fluoresce at a shorter wavelength. These results suggested that the structural determinants affecting the intrinsic fluorescence emission of homologous proteins can be easily assessed by quenching studies.     

Structural determinants of the intrinsic fluorescence emission in notexin and phospholipase A2 enzymes

Fluorescence measurements of the homologous proteins, notexin and PLA₂ enzymes fromNaja naja atra, Naja nigricollis, and Hemachatus haemachatus venoms, showed that the wavelength of maximum emission and the quantum yield of their intrinsic fluorescence emission spectra were different. To verify the factors which affected their fluorescence characteristics, the dynamics of tryptophan residues in those homologous proteins were studied by quenching with acrylamide, iodide, and cesium. The degrees of exposure of tryptophanyl groups in notexin and PLA₂ enzymes assessed by acrylamide quenching were found to be the major factor that determined their fluorescence characteristics. However, the positively charged groups surrounding tryptophan residues of PLA₂ enzymes fromN. naja atra andN. nigricollis venoms might affect the quantum yield of their fluorophores. Tryptophan residues of notexin were in an environment with less fluctuation, which did not allow free diffusion of ionic quencher. This might render its typtophan residues to fluoresce at a shorter wavelength. These results suggested that the structural determinants affecting the intrinsic fluorescence emission of homologous proteins can be easily assessed by quenching studies.     

Aurovertin fluorescence changes of the mitochondrial F1-ATPase during multi- and uni-site ATP hydrolysis

The aurovertin-F1 complex was used to monitor fluorescence changes of the mitochondrial adenosine triphosphatase during multi- and uni-site ATP hydrolysis. It is known that the fluorescence intensity of the complex is partially quenched by addition of ATP or Mg2+ and enhanced by ADP (Chang, T., and Penefsky, H. S. (1973) J. Biol. Chem. 248, 2746-2754). In the present study low concentrations of ATP (0.03 mM) induced a marked fluorescence quenching which was followed by a fast fluorescence recovery. This recovery could be prevented by EDTA or an ATP regenerating system. The rate of ATP hydrolysis by the aurovertin-F1 complex and the reversal of the ATP-induced fluorescence quenching were determined in these various conditions. ITP hydrolysis also resulted in fluorescence quenching that was followed by a recovery of fluorescence intensity. Under conditions for single site catalysis, fluorescence quenching was observed upon the addition of ATP. This strongly indicates that fluorescence changes in the aurovertin-F1 complex are due to the binding and hydrolysis of ATP at a catalytic site. Therefore the resulting ADP molecule bound at this catalytic site possibly induces the fluorescence recovery observed.     

The resolution of heterogeneous fluorescence of multitryptophan-containing proteins studied by a fluorescence-quenching method

From acrylamide quenching results, analyzed by an itterative non-linear least-squares method, we have shown that the fluorescence of multitryptophan-containing proteins, such as horse-liver alcohol dehydrogenase, 3-phosphoglycerate kinase and lysozyme, can be resolved for different segmental contributions, each characterized by collisional (Ki) and static (Vi) quenching constants. The ability to resolve the heterogeneous fluorescence of proteins makes it possible to follow changes in dynamics of the individual residues. In yeast 3-phosphoglycerate kinase, which contains only two tryptophan residues, three fluorescent fractions, characterized by different accessibility to the quencher, were observed. Two of them are assigned to one of the tryptophan residue. This may be interpreted in terms of conformational fluctuations, which facilitate the access of acrylamide molecules to the buried tryptophan residues.     

Use of nonradiative decays of extrinsic fluorophores as structural and dynamical probes in protein environments: Fluorescence quenching

In this work a combined pulsed-laser, time-resolved photoacoustic calorimetry (PAC) and fluorescence study is presented on two widely used covalent protein probes, fluorescein-5-isothiocyanate (FITC) and 6-acryloyl-2-dimethylaminonaphtalene (acrylodan). Three proteins that contain a single free thiol, namely carbonic anhydrase, bovine serum albumin (BSA) and papain, have been selectively labelled with FITC and acrylodan, and their fluorescence emission was quenched with KI. Nonradiative decays of the excited states of FITC are used to complement the information usually obtained by monitoring the quenching of fluorescence emssion. Data analysis evidences the dependence of the nonradiative quenching constants on the exposure of the dye to the solvent, and shows the involvement of a triplet state of FITC in the non radiative deexcitation. The shielding of the binding sites from the solvent is demonstrated also by the fluorescence emission of acrylodan and by the Stern-Volmer analysis of fluorescence quenching by KI. From photoacoustic data, an estimate of the fluorescent quantum yield of bound FITC is obtained. This work demonstrates the complete equivalence of quenching data obtained by fluorescence and photoacoustics measurements and shows that this combined approach allows a better control of the photophysics of the dyes involved in the quenching process.     

Single-molecule fluorescence studies from a bioinorganic perspective

In recent years, single-molecule methods have enabled many innovative studies in the life sciences, which generated unprecedented insights into the workings of many macromolecular machineries. Single-molecule studies of bioinorganic systems have been limited, however, even though bioinorganic chemistry represents one of the frontiers in the life sciences. With the hope to stimulate more interest in applying existing and developing new single-molecule methods to address compelling bioinorganic problems, this review discusses a few single-molecule fluorescence approaches that have been or can be employed to study the functions and dynamics of metalloproteins. We focus on their principles, features and generality, possible further bioinorganic applications, and experimental challenges. The fluorescence quenching via energy transfer approach has been used to study the O₂-binding of hemocyanin, the redox states of azurin, and the folding dynamics of cytochrome c at the single-molecule level. Possible future applications of this approach to single-molecule studies of metalloenzyme catalysis and metalloprotein folding are discussed. The fluorescence quenching via electron transfer approach can probe the subtle conformational dynamics of proteins, and its possible application to probe metalloprotein structural dynamics is discussed. More examples are presented in using single-molecule fluorescence resonance energy transfer to probe metallochaperone protein interactions and metalloregulator-DNA interactions on a single-molecule basis.