Investigation of Human Albumin-Induced Circular Dichroism in Dansylglycine

Induced circular dichroism (ICD), or induced chirality, is a phenomenon caused by the fixation of an achiral substance inside a chiral microenvironment, such as the hydrophobic cavities in proteins. Dansylglycine belongs to a class of dansylated amino acids, which are largely used as fluorescent probes for the characterization of the binding sites in albumin. Here, we investigated the ICD in dansylglycine provoked by its binding to human serum albumin (HSA). We found that the complexation of HSA with dansylglycine resulted in the appearance of an ICD band centred at 346 nm. Using this ICD signal and site-specific ligands of HSA, we confirmed that dansylglycine is a site II ligand. The intensity of the ICD signal was dependent on the temperature and revealed that the complexation between the protein and the ligand was reversible. The induced chirality of dansylglycine was susceptive to the alteration caused by the oxidation of the protein. A comparison was made between hypochlorous acid (HOCl) and hypobromous acid (HOBr), and revealed that site II in the protein is more susceptible to alteration provoked by the latter oxidant. These findings suggest the relevance of the aromatic amino acids in the site II, since HOBr is a more efficient oxidant of these residues in proteins than HOCl. The three-dimensional structure of HSA is pH-dependent, and different conformations have been characterised. We found that HSA in its basic form at pH 9.0, which causes the protein to be less rigid, lost the capacity to bind dansylglycine. At pH 3.5, HSA retained almost all of its capacity for binding to dansylglycine. Since the structure of HSA at pH 3.5 is expanded, separating the domain IIIA from the rest of the molecule, we concluded that this separation did not alter its binding capacity to dansylglycine.     

Fluorescence investigation of the sex steroid binding protein of rabbit serum: steroid binding and subunit dissociation

The relationship between steroid binding and protein subunit interactions of rabbit sex steroid binding protein (rSBP) has been studied by steady-state and time-resolved fluorescence spectroscopy. The high-affinity (Ka approximately 10(8) M-1 at 4 degrees C), fluorescent estrogen d-1,3,5(10),6,8-estrapentaene-3,17 beta-diol [dihydroequilenin (DHE)] was used as a fluorescent probe of the steroid-binding site. Perturbation of the binding site with guanidinium chloride (Gdm.Cl) was monitored by changes in the steady-state fluorescence anisotropy of DHE as well as by changes in fluorescence quenching of DHE with acrylamide. The results of acrylamide quenching at 11 degrees C show that, while between 0 and 1 M Gdm.Cl the steroid-binding site is completely shielded from bulk solvent, there is decreased DHE binding. To study the subunit-subunit interactions, rSBP was covalently labeled with dansyl chloride in the presence of saturating 5 alpha-dihydrotestosterone (DHT), which yielded a dansyl-conjugated protein that retained full steroid-binding activity. The protein subunit perturbation was monitored by changes in the steady-state fluorescence anisotropy of the dansyl group. At 11 degrees C, the dansyl anisotropy perturbation, reflecting changes in global and segmental motions of the dimer protein, occurs at concentrations of Gdm.Cl above 1 M. The Gdm.Cl titration in the presence of steroids with equilibrium association constants less than 10(8) M-1 shows a plateau near 3 M Gdm.Cl at 11 degrees C; at this Gdm.Cl concentration, no DHE is bound. No plateau is observed at 21 degrees C. At higher Gdm.Cl concentrations, the dansyl fluorescence anisotropy decreases further and shows no steroid dependence. Recovery of steroid-binding activity (assayed by saturation binding with [3H]DHT), under renaturation conditions, is dependent on both steroid concentration and affinity. Both unlabeled and dansyl-labeled protein recovery the same amount of activity, and according to fluorescence anisotropy, dansyl-labeled rSBP re-forms a dimer upon dilution below 1 M or removal of Gdm.Cl. From the steroid requirement for recovery of steroid-binding activity, it appears that a conformational template is required for the dimeric protein to re-form a steroid-binding site with native-like properties.     

The interaction of cyclosporin and calmodulin

The interaction of cyclosporin A and dansyl cyclosporin A with bovine and wheat germ calmodulin has been monitored by measurements of induced changes in dansyl and bound toluidinyl naphthalene sulfonate fluorescence. The interaction is Ca2(+)-dependent and 1:1. Measurements of the efficiency of radiationless energy transfer from bound dansyl cyclosporin A to an acceptor group located on Cys-27 of wheat germ calmodulin suggest that the primary binding site is not located on the N-terminal lobe (residues 1-65). However, studies with proteolytic fragments of calmodulin indicate that elements of the N-terminal half-molecule (residues 1-77) may be involved in the stabilization of the binding site. The binding of cyclosporin alters the physical properties of calmodulin and, in particular, reduces the localized rotational mobility of a fluorescent probe.     

The distances separating Tyr-69 from the high-affinity nucleotide and metal binding sites in actin

The nucleotide binding site in actin was occupied with the fluorescent analogue formycin A 5' triphosphate which acted as a fluorescent donor for the acceptor chromophore dansyl chloride attached to Tyr-69. The distance separating the two chromophores was calculated to be 2.1 nm from the fluorescence energy transfer measurements. Similar measurements were made of the distances separating dansyl chloride, acting as donor, on Tyr-69 from Co2+ occupying the metal binding site. A distance of 2.1 nm was similarly obtained.     

Orientation of substrate and two conformations of lactose permease

The accessibility of substrate bound to lactose permease of Escherichia coli was investigated by using the fluorescent substrate dansyl galactoside and a membrane-impermeable fluorescence quencher. To determine the orientation of bound substrate, both cells and inside-out vesicles were used. The substrate is oriented with the dansyl group toward the cytoplasm and the galactoside group toward the periplasm. Only half of the dansyl groups are accessible to quencher, irrespective of their orientation. This is interpreted as evidence for two different conformations of lactose permease, one with the binding site open to the cytoplasm and closed to the periplasm and vice versa for the other state.     

N-Methyl-D-Aspartate Recognition Site Ligands Modulate Activity at the Coupled Glycine Recognition Site

In synaptic plasma membranes from rat forebrain, the potencies of glycine recognition site agonists and antagonists for modulating [3H]1-[1-(2-thienyl)cyclohexyl]piperidine ([3H]TCP) binding and for displacing strychnine-insensitive [3H]glycine binding are altered in the presence of N-methyl-D-aspartate (NMDA) recognition site ligands. The NMDA competitive antagonist, cis-4-phosphonomethyl-2-piperidine carboxylate (CGS 19755), reduces [3H]glycine binding, and the reduction can be fully reversed by the NMDA recognition site agonist, L-glutamate. Scatchard analysis of [3H]glycine binding shows that in the presence of CGS 19755 there is no change in Bmax (8.81 vs. 8.79 pmol/mg of protein), but rather a decrease in the affinity of glycine (KD of 0.202 microM vs. 0.129 microM). Similar decreases in affinity are observed for the glycine site agonists, D-serine and 1-aminocyclopropane-1-carboxylate, in the presence of CGS 19755. In contrast, the affinity of glycine antagonists, 1-hydroxy-3-amino-2-pyrrolidone and 1-aminocyclobutane-1-carboxylate, at this [3H]glycine recognition site increases in the presence of CGS 19755. The functional consequence of this change in affinity was addressed using the modulation of [3H]TCP binding. In the presence of L-glutamate, the potency of glycine agonists for the stimulation of [3H]TCP binding increases, whereas the potency of glycine antagonists decreases. These data are consistent with NMDA recognition site ligands, through their interactions at the NMDA recognition site, modulating activity at the associated glycine recognition site.     

Fluorescent probes for retinoic acid receptors: molecular measures for the ligand binding pocket.

Two fluorescent probes for nuclear retinoic acid receptors (RARs) have been developed, both containing a biologically active retinoid moiety and a fluorescent dansyl moiety, but differing in the length of the spacer arm connecting the two moieties. Both probes bind RARs at their retinoid-binding sites, revealing the usefulness of the compounds as fluorescent RAR probes. By measuring the specific increase of the probes' fluorescence intensity caused by the binding to RARs, the linearized length of the RAR's retinoid-binding pocket could be estimated.     

Interactions of troponin I and its inhibitory fragment (residues 104-115) with troponin C and calmodulin

Fluorescent probes have been used to study the interaction of troponin I and its inhibitory peptide TnIp with troponin C, calmodulin, and the proteolytic fragments of calmodulin. The probes used included the noncovalently bound ligand TNS and the covalently attached labels dansyl and AEDANS. The fluorescence intensity of TNS bound to troponin C, calmodulin, or the calmodulin fragments was greatly enhanced by the presence of TnIp. This effect was used to estimate the corresponding binding constants. It was found that TnIp is bound by the C-terminal half-molecule of calmodulin, TR2C, with an affinity comparable to that of intact calmodulin or troponin C, while the binding affinity of the N-terminal half-molecule, TR1C, was an order of magnitude less, suggesting that the TnIp-containing portion of troponin I combines with the C-terminal half of calmodulin or troponin C. The fluorescence properties of an AEDANS group linked to Cys-98 of troponin C were modified by interaction with troponin I or TnIp. The fluorescence properties of the same group linked to Cys-27 of wheat germ calmodulin were affected by TnI, but not TnIp. TnI had a small effect upon the fluorescence of a dansyl group linked to Met-25 of troponin C. TnIp also inhibited the tryptic hydrolysis of the midpoint of the central connecting strand of calmodulin and troponin C.(ABSTRACT TRUNCATED AT 250 WORDS)     

Recognition and Binding of a Helix-Loop-Helix Peptide to Carbonic Anhydrase Occurs via Partly Folded Intermediate Structures

We have studied the association of a helix-loop-helix peptide scaffold carrying a benzenesulfonamide ligand to carbonic anhydrase using steady-state and time-resolved fluorescence spectroscopy. The helix-loop-helix peptide, developed for biosensing applications, is labeled with the fluorescent probe dansyl, which serves as a polarity-sensitive reporter of the binding event. Using maximum entropy analysis of the fluorescence lifetime of dansyl at 1:1 stoichiometry reveals three characteristic fluorescence lifetime groups, interpreted as differently interacting peptide/protein structures. We characterize these peptide/protein complexes as mostly bound but unfolded, bound and partly folded, and strongly bound and folded. Furthermore, analysis of the fluorescence anisotropy decay resulted in three different dansyl rotational correlation times, namely 0.18, 1.2, and 23 ns. Using the amplitudes of these times, we can correlate the lifetime groups with the corresponding fluorescence anisotropy component. The 23-ns rotational correlation time, which appears with the same amplitude as a 17-ns fluorescence lifetime, shows that the dansyl fluorophore follows the rotational diffusion of carbonic anhydrase when it is a part of the folded peptide/protein complex. A partly folded and partly hydrated interfacial structure is manifested in an 8-ns dansyl fluorescence lifetime and a 1.2-ns rotational correlation time. This structure, we believe, is similar to a molten-globule-like interfacial structure, which allows segmental movement and has a higher degree of solvent exposure of dansyl. Indirect excitation of dansyl on the helix-loop-helix peptide through Förster energy transfer from one or several tryptophans in the carbonic anhydrase shows that the helix-loop-helix scaffold binds to a tryptophan-rich domain of the carbonic anhydrase. We conclude that binding of the peptide to carbonic anhydrase involves a transition from a disordered to an ordered structure of the helix-loop-helix scaffold.     

Effect of metal ions on the fluorescence of leucine aminopeptidase and its dansyl-peptide substrates

The effect of Cu(II), Ni(II), Zn(II), Mg(II), and Mn(II) on the fluorescence of porcine kidney cytosol leucine aminopeptidase and three of its dansyl(Dns) peptide substrates, Leu-Gly-NHNH-Dns, Leu-Gly-NH(CH2)2NH-Dns, and Leu-Gly-NH(CH2)6NH-Dns, has been investigated. These five metal ions were chosen for study because each binds to the regulatory metal binding site of leucine aminopeptidase. Since the binding is relatively weak, kinetic studies of the different metalloderivatives of the enzyme are normally carried out in the presence of large molar excesses of these metal ions that can potentially affect both the enzyme and substrate. The fluorescence of all of the dansyl-peptides, as well as several other dansyl species, is quenched by Ni(II) and Cu(II), but not by Mg(II), Mn(II), or Zn(II). The absorption spectra of these dansyl substrates are also perturbed by Ni(II) and Cu(II). The rate at which maximal quenching for some dansyl species is attained after mixing with Ni(II) and Cu(II) is slow and the quenching is reversed on addition of EDTA. These results indicate that the quenching is the result of complex formation between the fluorophores and these metal ions. The association constants for the metal complexes have been determined from Stern-Volmer plots. In addition to complex formation, Ni(II) and Cu(II) cause the degradation of Leu-Gly-NHNH-Dns through a two step mechanism involving loss of dansic acid. Ni(II) and Cu(II) also partially quench the fluorescence of leucine aminopeptidase through contact with its surface accessible Trp residues. These observations indicate that care must be taken in stopped flow fluorescence studies of reactions between this enzyme and its dansyl substrates to avoid adverse effects brought about by Ni(II) and Cu(II).     

Fitting fluorescence emission spectra of probes bound to biological membranes

We show that fluorescence emission spectra for molecules containing the dansyl fluorophor can be accurately described as skewed Gaussians, and that spectra for dansyl probes bound to biological membranes can be resolved using least-squares techniques into two components, representing probe bound to the lipid and protein sites in the membrane.     

Antibody-hapten interactions: circular and linear polarization of the fluorescence of dansyl bound to anti-dansyl antibodies

The fluorescence spectra of several dansyl derivatives (dansylamide, ?-N-dansyl-l-lysine, dansyl-l-alanine, and α-N-dansyl-l-alanine amide) bound to anti-dansyl antibodics (induced by an α-N-dansyl-poly d,l-alanine-poly l-lysine conjugate) are shifted by about 60 nm to the blue, and the quantum yields are markedly enhanced, compared to their respective fluorescence properties in water. The light emitted by the bound haptens is partly circularly polarized, reflecting the asymmetry induced in the bound chromophores by the antibody combining site. In contradistinction, the fluorescence spectrum of 1-dansyl-2-alanine diaminoethane bound to anti-alanine antibodies is similar to that of the free fluorophore in water and lacks circular polarization. These results imply that in this case the fluorophore of the hapten protrudes out of the site into the aqueous solvent. No circular dichroism is observed in the 300 to 400 nm region for the dansyl-anti-dansyl complex. Thus a change in the mode of interaction between the chromophore and its binding site takes place upon electronic excitation. The heterogeneity of the antibody binding sites is expressed by the dependence of the circular polarization of fluorescence on excitation wavelength. Differences in the circular polarization of luminescence were also observed when the residues attached to the dansyl group have been varied. This may reflect differences in the alignment of the fluorophore within the binding sites for the different dansyl derivatives.The linear polarization of dansylamide dissolved in glycerol is not constant across the emission band, indicating that the transition dipole moments related to the various vibronic states do not have the same spatial directions. Vibronic mixing of the emitting excited state with higher electronic states is thus indicated. Dansyl-l-alanine bound to anti-dansyl antibodies exhibitsan even more pronounced variation of the linear polarization across the emission band. In this case, the dependence of the linear polarization of the emitted light on excitation wavelength is anomalous, which is again a reflection of the heterogeneity of the population of the antibody molecules. The implications of these results to the studies of the fluorescence polarization of dansyl-protein complexes are discussed.     

Reactive affinity probes for the mapping of the glycine-binding site of the NMDA receptor NR1 subunit

The glycine co-agonist binding site of the NMDA receptor is a target for the prevention and treatment of neurotoxic and neurodegenerative conditions. Until now, the interactions taking place at this site, and its structure, have been investigated by ligand structure-activity relationships and by site-directed mutagenesis. On the basis of a structural model which is currently proposed for this site, we have designed and synthesized six affinity markers by substituting electrophilic reactive groups in the 4, the 7 and the 3' positions of L 701,324, a high-affinity glycine site antagonist. These compounds compete with 3H-DCKA binding to rat brain membranes at equilibrium with nanomolar to low-micromolar affinities, and antagonize glycine-evoked currents in oocytes transfected with wild-type NR1-NR2B. However, they do not induce a time-shift in binding equilibria, and do not inactivate irreversibly the glycine evoked currents. Since they react only with cysteine at physiological pH, we conclude that there is no such residue in the site, in agreement with the model. Our affinity markers therefore represent potential topological probes for NMDA receptors with sequence positions related to the glycine-binding site mutated into cysteine.     

Identification of two residues essential for the stringent substrate specificity and active site stability of the prokaryotic l-arginine:glycine amidinotransferase CyrA

A novel prokaryotic l-arginine:glycine amidinotransferase (CyrA; EC2.1.4.1) is involved in the biosynthesis of the polyketide-derived cytotoxin cylindrospermopsin in the cyanobacterium Cylindrospermopsis raciborskii AWT250, and was previously characterized with regard to kinetic mechanism and substrate specificity [Muenchhoff J et al. (2010) FEBS J277, 3844-3860]. In order to elucidate the structure-function-stability relationship of this enzyme, two residues in its active site were replaced with the residues that occur in the human l-arginine:glycine amidinotransferase (h-AGAT) at the corresponding positions (F245N and S247M), and a double variant carrying both substitutions was also created. In h-AGAT, both of these residues are critical for the function of this enzyme with regard to substrate binding, ligand-induced structural changes, and stability of the active site. In this study, we demonstrated that both single residue replacements resulted in a dramatic broadening of substrate specificity, but did not affect the kinetic mechanism. Experiments with substrate analogues indicate that donor substrates require a carboxylate group for binding. Evidence from initial velocity studies suggests that CyrA undergoes ligand-induced structural changes that involve Phe245. Stability parameters (T(opt) and T(max) ) of the CyrA variants differed from those of wild-type CyrA. Structural flexibilities of the wild type and all three variants were comparable on the basis of dynamic fluorescence quenching, indicating that changes in T(opt) are most likely attributable to localized effects within the active site. Overall, the results indicated that these two residues are essential for both stringent substrate specificity and the active site stability and flexibility of this unique cyanobacterial enzyme.     

Interaction of cartilage proteoglycans with hyaluronic acid. The role of the hyaluronic acid carboxyl groups.

Hyaluronic acid-derived oligomers of five to fifteen repeat dissaccharides effectively bind to bovine nasal-cartilage proteoglycan and inhibit the interaction between proteoglycans and high-molecular-weight hyaluronic acid. If, however, the hyaluronic acid oligosaccharides are modified by reaction with diazomethane to form the carboxyl methyl esters of the glucuronic acid residues, their inhibitory activity is abolished. The binding capacity can be fully restored by saponification. The amide derivative, which is formed by condensation of the oligosaccharide carboxyl groups with glycine methyl ester, is also ineffective in blocking the proteoglycan-hyaluronic acid interaction. In this case, binding activity is not restored when the amidated oligomers are subjected to saponification to yield the free carboxylate groups on the glycine residues. Thus the displacement of the carboxylate groups on the polysaccharide chain by the interposition of a glycine residue blocks the interaction between the proteoglycans and the hyaluronic acid oligomers. When the oligosaccharide methyl ester is reduced with NaBH4, the resultant glucose-containing oligomers exhibit decreased binding to proteoglycans. Thus it appears that the hyaluronic acid carboxylate anion in a specific spatial orientation is required for hyaluronic acid-proteoglycan interaction.     

Fluorescence energy transfer between Tyr 69 and Cys 374 in actin

Modification of Tyr 69 with the chromophore dansyl chloride was found to completely block exchange of the bound ATP on actin. No significant conformational change was detected in the actin after labelling thus indicating that the dansyl chloride is close to and probably sterically blocks the ATP site. The distance separating dansyl chloride attached to Tyr 69 and IAEDANS attached to Cys 374 on actin was found using fluorescence energy transfer to be 3.9 nm. This result is consistent with the known distance between the ATP site and Cys 374.     

The active site of factor IXa is located far above the membrane surface and its conformation is altered upon association with factor VIIIa. A fluorescence study.

The topography of membrane-bound blood coagulation factor IXa (fIXa) and the nature of its interaction with its cofactor, factor VIIIa (fVIIIa), were examined using fluorescent derivatives of fIXa. A fluorescein dye was covalently attached to the active-site histidine of fIXa via a D-Phe-Pro-Arg tripeptide tether to form Fl-A-FPR-fIXa; similarly, a 5-dimethylaminonaphthalene-1-sulfonyl (dansyl) dye was covalently attached via Glu-Gly-Arg to form DEGR-fIXa. When either Fl-A-FPR-fIXa or DEGR-fIXa was titrated with phosphatidylcholine-phosphatidylserine vesicles containing octadecylrhodamine in the presence of Ca2+, fluorescence energy transfer was observed. Assuming a random orientation of dyes, the distance of closest approach between the donor dyes in the active sites of the membrane-bound enzymes and the acceptor dyes at the membrane surface was found to be 89 +/- 3 A for Fl-A-FPR-fIXa and 73 +/- 4 A for DEGR-fIXa. Although the exact distance remains uncertain, it is clear that the active site of fIXa is positioned more than 70 A above the surface, and hence that the elongated fIXa molecule projects approximately perpendicularly from the surface when bound to the membrane. The binding of fVIIIa to membrane-bound Fl-A-FPR-fIXa or DEGR-fIXa did not alter the location of the active site relative to the membrane surface, but did alter both the emission intensity and anisotropy of the fluorescein and dansyl probes and hence their environments. Cofactor stimulation of fIXa activity therefore appears to be mediated, at least in part, by a conformational change in the active site that occurs when fVIIIa binds to the enzyme on the phospholipid surface.     

Neurophysin-neurohypophyseal hormone interactions: studies using a dansylated vasotocin analogue.

We have synthesized a neurohypophyseal hormone analogue containing an extrinsic fluorescence probe by linking a dansyl (DNS) group to the epsilon-amino group of the lysine at residue 8 of vasotocin. The fluorescence properties of this analogue have been characterized by steady-state and time-resolved spectroscopic methods and compared with those of epsilon-DNS-lysine and the dansylated carboxyl terminal tripeptide Pro-Lys(DNS)-GlyNH2. The binding of this hormone analogue to purified isoforms of bovine neurophysins, the natural carrier proteins of the neurohypophyseal hormones, results in changes in several fluorescence parameters of the dansyl probe. These changes include an increase in intensity and average lifetime, a shift of the emission band to higher energies, and an increase in the emission anisotropy. Anisotropy changes have been used to determine dissociation constants for binding to these neurophysin isoforms. Based on the changes in the fluorescence properties of the dansyl probe, the dansyl group itself interacts with the protein. The degree of the dansyl-neurophysin interaction, however, appears to be different for the full sequence isoform of neurophysin I and the Val89 isoform of neurophysin II.     

Mechanism of the binding of Z-L-tryptophan and Z-L-phenylalanine to thermolysin and stromelysin-1 in aqueous solutions

The chemical shift of the carboxylate carbon of Z-tryptophan is increased from 179.85 to 182.82 ppm and 182.87 ppm on binding to thermolysin and stromelysin-1 respectively. The chemical shift of Z-phenylalanine is also increased from 179.5 ppm to 182.9 ppm on binding to thermolysin. From pH studies we conclude that the pK(a) of the inhibitor carboxylate group is lowered by at least 1.5 pK(a) units when it binds to either enzyme. The signal at ~183 ppm is no longer observed when the active site zinc atom of thermolysin or stromelysin-1 is replaced by cobalt. We estimate that the distance of the carboxylate carbon of Z-[1-(13)C]-L-tryptophan is ≤3.71? from the active site cobalt atom of thermolysin. We conclude that the side chain of Z-[1-(13)C]-L-tryptophan is not bound in the S(2)' subsite of thermolysin. As the chemical shifts of the carboxylate carbons of the bound inhibitors are all ~183 ppm we conclude that they are all bound in a similar way most probably with the inhibitor carboxylate group directly coordinated to the active site zinc atom. Our spectrophotometric results confirm that the active site zinc atom is tetrahedrally coordinated when the inhibitors Z-tryptophan or Z-phenylalanine are bound to thermolysin.