Binding of the general anesthetics chloroform and 2,2,2-trichloroethanol to the hydrophobic core of a four-alpha-helix bundle proteins

Luminescent and morphological behavior of the aromatic dipeptide pair having singular structural variability

In the present manuscript, the luminescence and the self-assembly behavior of the two aromatic dipeptides having singular structure variable are investigated. The terminally protected dipeptides tryptophan-tyrosine (WY^p ) and tryptophan-phenylalanine (WF^p ) were synthesized using standard solution phase procedure. Significant solvatochromic effect was observed for both the dipeptidyl entities; while the influence was more pronounced in case of the WY^p entity when compared to WF^p . Interesting morphological variation was observed for WF^p and WY^p , wherein discrete and interconnected nanospheres were observed for the respective dipeptides. The results obtained signifies the influence of the singular structural variation on modulating the overall functional behavior of the short peptides motifs.

Activator-induced dynamic disorder and molecular memory in human two-pore domain hTREK1 K channel

Ion channels are fundamental molecules in the nervous system that catalyze the flux of ions across the cell membrane. Ion channel flux activity is comparable to the catalytic activity of enzyme molecules. Saturating concentrations of substrate induce "dynamic disorder" in the kinetic rate processes of single-enzyme molecules and consequently, develop correlative "memory" of the previous history of activities. Similarly, binding of ions as substrate alone or in presence of agonists affects the catalytic turnover of single-ion channels. Here, we investigated the possible existence of dynamic disorder and molecular memory in the single human-TREK1-channel due to binding of substrate/agonist using the excised inside-out patch-clamp technique. Our results suggest that the single-hTREK1-channel behaves as a typical Michaelis-Menten enzyme molecule with a high-affinity binding site for K(+) ion as substrate. But, in contrast to enzyme, dynamic disorder in single-hTREK1-channel was not induced by substrate K(+) binding, but required allosteric modification of the channel molecule by the agonist, trichloroethanol. In addition, interaction of trichloroethanol with hTREK1 induced strong correlation in the waiting time and flux intensity, exemplified by distinct mode-switching between high and low flux activities. This suggested the induction of molecular memory in the channel molecule by the agonist, which persisted for several decades in time. Our mathematical modeling studies identified the kinetic rate processes associated with dynamic disorder. It further revealed the presence of multiple populations of distinct conformations that contributed to the "heterogeneity" and consequently, to the molecular memory phenomenon that we observed.

ELECTRONIC SUPPLEMENTARY MATERIAL

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Kinetics of anesthetic-induced conformational transitions in a four-alpha-helix bundle protein

Inhaled anesthetics are thought to alter the conformational states of Cys-loop ligand-gated ion channels (LGICs) by binding within discrete cavities that are lined by portions of four alpha-helical transmembrane domains. Because Cys-loop LGICs are complex molecules that are notoriously difficult to express and purify, scaled-down models have been used to better understand the basic molecular mechanisms of anesthetic action. In this study, stopped-flow fluorescence spectroscopy was used to define the kinetics with which inhaled anesthetics interact with (Aalpha(2)-L1M/L38M)(2), a four-alpha-helix bundle protein that was designed to model anesthetic binding sites on Cys-loop LGICs. Stopped-flow fluorescence traces obtained upon mixing (Aalpha(2)-L1M/L38M)(2) with halothane revealed immediate, fast, and slow components of quenching. The immediate component, which occurred within the mixing time of the spectrofluorimeter, was attributed to direct quenching of tryptophan fluorescence upon halothane binding to (Aalpha(2)-L1M/L38M)(2). This was followed by a biexponential fluorescence decay containing fast and slow components, reflecting anesthetic-induced conformational transitions. Fluorescence traces obtained in studies using sevoflurane, isoflurane, and desflurane, which poorly quench tryptophan fluorescence, did not contain the immediate component. However, these anesthetics did produce the fast and slow components, indicating that they also alter the conformation of (Aalpha(2)-L1M/L38M)(2). Cyclopropane, an anesthetic that acts with unusually low potency on Cys-loop LGICs, acted with low apparent potency on (Aalpha(2)-L1M/L38M)(2). These results suggest that four-alpha-helix bundle proteins may be useful models of in vivo sites of action that allow the use of a wide range of techniques to better understand how anesthetic binding leads to changes in protein structure and function.

Structure and Dynamics of Halogenoethanol−Water Mixtures Studied by Large-Angle X-ray Scattering, Small-Angle Neutron Scattering, and NMR Relaxation

To clarify the structure of solvent clusters formed in halogenoethanol-water mixtures at the molecular level, large-angle X-ray scattering (LAXS) measurements have been made at 298 K on 2,2,2-trifluoroethanol (TFE), 2,2,2-trichloroethanol (TCE), and their aqueous mixtures in the TFE and TCE mole fraction ranges of 0.002 < or = x(TFE) < or = 0.9 and 0.5 < or = x(TCE) < or = 0.9, respectively. The radial distribution functions (RDFs) for TFE-water mixtures have shown that the structural transition from inherent TFE structure to the tetrahedral-like structure of water takes place at x(TFE) approximately 0.2. In the TCE-water mixtures inherent TCE structure remains in the range of 0.5 < or = x(TCE) < or = 1. Small-angle neutron scattering (SANS) experiments have been performed on CF(3)CH(2)OD- (TFE-d(1)-) D(2)O and CF(3)CD(2)OH- (TFE-d(2)-) H(2)O mixtures in the TFE mole fraction range of 0.05 < or = x(TFE) < or = 0.8. The SANS results in terms of the Ornstein-Zernike correlation length have revealed that TFE and water molecules are most heterogeneously mixed with each other in the TFE-water mixture at x(TFE) approximately 0.15, i.e., both TFE clusters and water clusters are most enhanced in the mixture. To evaluate the dynamics of TFE and ethanol (EtOH) molecules in TFE-water and ethanol-water mixtures, respectively, (1)H NMR relaxation rates for the methylene group within alcohol molecules have been measured by using an inversion-recovery method. The alcohol concentration dependence of the relaxation rates for the TFE-water and ethanol-water mixtures has shown a break point at x(TFE) approximately 0.15 and x(EtOH) approximately 0.2, respectively, where the structural transition from alcohol clusters to the tetrahedral-like structure of water takes place. On the basis of the present results, the most likely structure models of solvent clusters predominantly formed in TFE-water and TCE-water mixtures are proposed. In addition, effects of halogenation of the hydrophobic groups on clustering of alcohol molecules are discussed from the present results, together with the previous ones for ethanol-water and 1,1,1,3,3,3-hexafluoro-2-propanol- (HFIP-) water mixtures.

Binding of the volatile general anesthetics halothane and isoflurane to a mammalian beta-barrel protein

A molecular understanding of volatile anesthetic mechanisms of action will require structural descriptions of anesthetic-protein complexes. Porcine odorant binding protein is a 157 residue member of the lipocalin family that features a large beta-barrel internal cavity (515 +/- 30 angstroms(3)) lined predominantly by aromatic and aliphatic residues. Halothane binding to the beta-barrel cavity was determined using fluorescence quenching of Trp16, and a competitive binding assay with 1-aminoanthracene. In addition, the binding of halothane and isoflurane were characterized thermodynamically using isothermal titration calorimetry. Hydrogen exchange was used to evaluate the effects of bound halothane and isoflurane on global protein dynamics. Halothane bound to the cavity in the beta-barrel of porcine odorant binding protein with dissociation constants of 0.46 +/- 0.10 mM and 0.43 +/- 0.12 mM determined using fluorescence quenching and competitive binding with 1-aminoanthracene, respectively. Isothermal titration calorimetry revealed that halothane and isoflurane bound with K(d) values of 80 +/- 10 microM and 100 +/- 10 microM, respectively. Halothane and isoflurane binding resulted in an overall stabilization of the folded conformation of the protein by -0.9 +/- 0.1 kcal.mol(-1). In addition to indicating specific binding to the native protein conformation, such stabilization may represent a fundamental mechanism whereby anesthetics reversibly alter protein function. Because porcine odorant binding protein has been successfully analyzed by X-ray diffraction to 2.25 angstroms resolution [1], this represents an attractive system for atomic-level structural studies in the presence of bound anesthetic. Such studies will provide much needed insight into how volatile anesthetics interact with biological macromolecules.

Expression and Characterization of a Four-α-Helix Bundle Protein That Binds the Volatile General Anesthetic Halothane

The structural features of volatile anesthetic binding sites on proteins are being investigated with the use of a defined model system consisting of a four-alpha-helix bundle scaffold with a hydrophobic core. The current study describes the bacterial expression, purification, and initial characterization of the four-alpha-helix bundle (Aalpha(2)-L1M/L38M)(2). The alpha-helical content and stability of the expressed protein are comparable to that of the chemically synthesized four-alpha-helix bundle (Aalpha(2)-L38M)(2) reported earlier. The affinity for binding halothane is somewhat improved with a K(d) = 120 +/- 20 microM as determined by W15 fluorescence quenching, attributed to the L1M substitution. Near-UV circular dichroism spectroscopy demonstrated that halothane binding changes the orientation of the aromatic residues in the four-alpha-helix bundle. Nuclear magnetic resonance experiments reveal that halothane binding results in narrowing of the peaks in the amide region of the one-dimensional proton spectrum, indicating that bound anesthetic limits protein dynamics. This expressed protein should prove to be amenable to nuclear magnetic resonance structural studies on the anesthetic complexes, because of its relatively small size (124 residues) and the high affinities for binding volatile anesthetics. Such studies will provide much needed insight into how volatile anesthetics interact with biological macromolecules and will provide guidelines regarding the general architecture of binding sites on central nervous system proteins.

A calorimetric study on the binding of six general anesthetics to the hydrophobic core of a model protein

The thermodynamic parameters underlying the binding of six volatile general anesthetics to the hydrophobic core of the four-alpha-helix bundle (Aalpha(2)-L38M)(2) are determined using isothermal titration calorimetry. Chloroform, bromoform, trichloroethylene, benzene, desflurane and fluroxene are shown to bind to the four-alpha-helix bundle with dissociation constants of 880+/-10, 90+/-5, 200+/-10, 900+/-30, 220+/-10 and 790+/-40 microM, respectively. The measured dissociation constants for the binding of the six general anesthetics to the four-alpha-helix bundle (Aalpha(2)-L38M)(2) correlate with their human or animal EC(50) values. The negative enthalpy changes indicate that favorable polar interactions are achieved between bound anesthetic and the adjacent amino acid side chains. Because of its small size and the ability to bind a variety of general anesthetics, the four-alpha-helix bundle (Aalpha(2)-L38M)(2) represents an attractive system for structural studies on anesthetic-protein complexes.

An isothermal titration calorimetry study on the binding of four volatile general anesthetics to the hydrophobic core of a four-alpha-helix bundle protein

A molecular understanding of volatile anesthetic mechanisms of action will require structural descriptions of anesthetic-protein complexes. Previous work has demonstrated that the halogenated alkane volatile anesthetics halothane and chloroform bind to the hydrophobic core of the four-alpha-helix bundle (Aalpha(2)-L38M)(2) (Johansson et al., 2000, 2003). This study shows that the halogenated ether anesthetics isoflurane, sevoflurane, and enflurane are also bound to the hydrophobic core of the four-alpha-helix bundle, using isothermal titration calorimetry. Isoflurane and sevoflurane both bound to the four-alpha-helix bundle with K(d) values of 140 +/- 10 micro M, whereas enflurane bound with a K(d) value of 240 +/- 10 micro M. The DeltaH degrees values associated with isoflurane, sevoflurane, and enflurane binding were -7.7 +/- 0.1 kcal/mol, -8.2 +/- 0.2 kcal/mol, and -7.2 +/- 0.1 kcal/mol, respectively. The DeltaS degrees values accompanying isoflurane, sevoflurane, and enflurane binding were -8.5 cal/mol K, -10.4 cal/mol K, and -8.0 cal/mol K, respectively. The results indicate that the hydrophobic core of (Aalpha(2)-L38M)(2) is able to accommodate three modern ether anesthetics with K(d) values that approximate their clinical EC(50) values. The DeltaH degrees values point to the importance of polar interactions for volatile general anesthetic binding, and suggest that hydrogen bonding to the ether oxygens may be operative.

Effect of Four-α-Helix Bundle Cavity Size on Volatile Anesthetic Binding Energetics

Currently, it is thought that inhalational anesthetics cause anesthesia by binding to ligand-gated ion channels. This is being investigated using four-alpha-helix bundles, small water-soluble analogues of the transmembrane domains of the "natural" receptor proteins. The study presented here specifically investigates how multiple alanine-to-valine substitutions (which each decrease the volume of the internal binding cavity by 38 A(3)) affect structure, stability, and anesthetic binding affinity of the four-alpha-helix bundles. Structure remains essentially unchanged when up to four alanine residues are changed to valine. However, stability increases as the number of these substitutions is increased. Anesthetic binding affinities are also affected. Halothane binds to the four-alpha-helix bundle variants with 0, 1, and 2 substitutions with equivalent affinities but binds to the variants with 3 and 4 more tightly. The same order of binding affinities was observed for chloroform, although for a particular variant, chloroform was bound less tightly. The observed differences in binding affinities may be explained in terms of a modulation of van der Waals and hydrophobic interactions between ligand and receptor. These, in turn, could result from increased four-alpha-helix bundle binding cavity hydrophobicity, a decrease in cavity size, or improved ligand/receptor shape complementarity.