Study of lysozyme by a spin-label method in the 2-mm range

Two millimeter range ESR-spectroscopy was used to measure the values of magnetic resonance parameters of egg lysozyme samples modified with nitroxyl label 4-(iodine-acetamide)-2,2,6,6-tetramethylpiperidine-1-oxyl by hist-15 residue. It has been shown that in a lyophilic sample the spin label forms a hydrogen bond with the protein group and when the sample is moistened--with water molecules. Temperature changes of the pattern of ESR line are analysed. It is concluded that in the moistened samples within 230-320 K the nitroxyl fragment of the label gets engaged in anisotropic movement with preferable rotation around Z-axis of N-O. fragment with anisotropy coefficient 5 and mean correlation time tau congruent to 5 X 10(-7) divided by 5 X 10(-8) c.     

The hinge-bending mode of a lysozyme-inhibitor complex

The hinge-bending mode of hen egg white lysozyme is studied by a constrained minimization technique. Results with and without a bound inhibitor, tri-N-acetyl-glucosamine, are obtained. The frequency of the mode with the inhibitor is found to be 4.3 cm^?1, in contrast to 3.0 cm^?1 for the free enzyme. Also, the hinge-bending angle with the lowest energy is shifted 10° towards a more closed cleft in the bound species. The main contribution to these differences arise from interactions with the residues lining the cleft and those on the back side of it. Structural details that account for the energetics are presented. The method of calculation is somewhat different from a previous study [J. A. McCammon, B. R. Gelin, M. Karplus & P. G. Wolynes, (1976) Nature 262 , 325–326] to reduce the likelihood of artifacts in the results.     

Characterisation by triple-quantum filtered 17O-NMR of water molecules buried in lysozyme and trapped in a lysozyme-inhibitor complex.

Triple-quantum filtering NMR sequences were used to study the multiexponential relaxation behaviour of H2 17O in the presence of hen egg white lysozyme. By this means, the fraction and the correlation time of water were determined in slow motion, as well as the relaxation time of water in the extreme narrowing limit. The small number of water molecules in slow motion, which is between four and five per lysozyme, seems to correspond to the 'integral' water, buried or in the cleft inside the protein, whereas water in fast motion corresponds to all other water molecules, interacting or not with the macromolecules. The same experiment was performed after addition of the inhibitor tri-N-acetylglucosamine (NAG)3. For solutions of sufficient viscosity, there were approximately three supplementary water molecules in slow motion per lysozyme, probably trapped between the protein and the inhibitor. The correlation time of these water molecules was estimated at 2 ns, which should correspond to their residence time in the complex.     

Concentration of oxygen in lipid bilayers using a spin-label method.

The concentration of oxygen in the hydrocarbon region of lipid bilayer has been determined using a novel electron spin resonance (ESR) nitroxide-radical spin-probe method. For dimyristoylphosphatidylcholine (DMPC), the partition coefficient above the main transition temperature is approximately 3. Rapid decrease to 0.2 occurs below the pretransition temperature indicating exclusion of oxygen in the crystalline phase. The differences of molar free energy, enthalpy, and entropy of mixing between water and lipid have been determined for each phase.     

Measurements of the time of rotational correlation of bovine serum albumin molecule using iodine and mercury-containing spin-labels

New spin-labels based on iodine and hydrargirum containing imidazolids were approbated on the bovine serum albumin (BSA) molecule. It is shown that all hydrargirum labels are binded to the external SH-group of BSA practically immediately in comparison with earlier known spin-labels based on piperidine with maleimide and iodacetamide groups, requiring some minutes of hours, correspondingly. Rotational correlation times and the character of relative mobility of the spin-label were measured. Values of the rotational correlation times of the protein molecule obtained by hydrargirum containing labels were found in the range of correlation times typical for the BSA molecule and represent at pH 7.0 a rigid stretch ellipsoid of rotation. The result obtained revealed that the relative reorientation nature of spin-labels is essentially different and is taken into account in different values of order parametres S according to model--fast anisotropic rotator on slow isotropic rotator. ESR spectra based on theoretical calculations by means of computer are given.     

Triclosan-lysozyme complex as novel antimicrobial macromolecule: a new potential of lysozyme as phenolic drug-targeting molecule

A novel anti-infection strategy to alleviate antibiotic-resistance problem and non-specific toxicity associated with chemotherapy is explored in this study. It is based on utilizing a bacteriolytic enzyme (lysozyme) as a carrier to allow specific targeting of a potential phenolic antimicrobial drug (triclosan) to microbial cells. Lysozyme (LZ) was complexed, via electrostatic and hydrophobic condensation at alkaline pH, to various degrees with triclosan (TCS), a negatively charged phenolic antimicrobial that inhibits bacterial fatty acid synthesis. Fluorescence and absorbance spectra analysis revealed non-covalent association of TCS with the aromatic residues at the interior of LZ molecule. The conjugation greatly promoted the lytic activity of LZ as the degree of TCS derivatization increased. The complexation with LZ turned TCS into completely soluble in aqueous solution. TCS-LZ complexes showed significantly enhanced bactericidal activity against several strains of Gram-positive and Gram-negative bacteria compared to the activity of TCS or LZ alone when tested at the same molar basis. Strikingly, TCS-LZ complex, but not LZ or TCS alone, exhibited unique specificity to scavenge superoxide radicals, generated by the natural xanthine/xanthine oxidase coupling system, without affecting the catalytic function of oxidase. This finding is the first to describe that the membrane disrupting function of lysozyme can be utilized to specifically target antimicrobial drug(s) to pathogen cells and heralding a fascinating opportunity for the potential candidacy of TCS-LZ as novel antimicrobial strategy for human therapy.     

Study of the structure of erythrocyte membrane in spontaneous genetic hypertension using the spin-label method

An analysis of ESR spectra of maleimid spin-labeled erythrocyte membranes of spontaneously hypertensive rats of SHR line and normotensive rats of the control line WKY showed differences in the structure of membrane proteins in the norm and pathology. These differences were compared with the differences between the erythrocyte membranes of SHR and WKY, found earlier by fluorescent probe method. An important role of membrane peripheric proteins in the appearance of the above differences in suggested.     

The diffusion-concentration product of oxygen in lipid bilayers using the spin-label T1 method

A method is described to measure the oxygen diffusion-concentration product, DO[O2], at any locus that can be probed or labeled using nitroxide radicals. The method is based on the dependence of the spin-lattice relaxation time T1 of the spin label on the bimolecular collision rate with oxygen. Strong Heisenberg exchange between spin label and oxygen contributes directly to T1 of the spin label, while dipolar interactions are negligible. Both time-domain and continuous wave saturation methods for studying T1 are considered. The method has been applied to phospholipid liposomes using fatty acid spin labels. A discontinuity in DO[O2] at the main phase transition was observed.     

Detection of three rotational correlation times for a rigid asymmetric molecule using frequency-domain fluorometry

We measured the frequency response of the polarized emission of Y_t-base in propylene glycol at 10 ° C. Data were obtained for excitation wavelengths of 290, 312 and 346 nm, for which the fundamental anisotropies are 0.05, 0.19 and 0.32, respectively. Additionally, data were obtained using CCl₄, to decrease the mean decay time from 9.1 to 4.2 ns. These nine sets of data were analyzed globally to recover the anisotropy decay law. Three correlation times were needed to fit the data, 0.8, 3.0 and 5.6 ns, a range of only 7-fold. We believe this is the first reported detection of three correlation times for a rigid molecule.     

Study by the spin-label method of relaxation properties of protein kinase, its subunits and the catalytic subunit--histone H1 complex

Using the spin label method, the rotational relaxation in solution of adenosine 3',5'-monophosphate-dependent protein kinase and its subunits as well as the complexes of the enzyme with the substrate, histone H1, was studied. The rotational correlation time of the spin labeled macromolecules was measured on the basis of the quantitative estimation of the label mobility in relation to the protein globule. The holoenzyme molecule was found to be a rigid sphere. Whereas the complex of the globular catalytic subunit of the enzyme with a specific protein substrate, the spin labeled histone H1, appeared a flexible formation. The relaxation properties of the histone H1 molecule selectively labeled by the spin label in its globular part were investigated.     

Rotational diffusion of a steroid molecule in phosphatidylcholine membranes: effects of alkyl chain length, unsaturation, and cholesterol as studied by a spin-label method

Rotational diffusion of cholestane spin-label (CSL), a sterol analogue, in various phosphatidylcholine (PC)-cholesterol membranes was systematically studied by computer simulation of steady-state ESR spectra as a function of chain length and unsaturation of alkyl chains, cholesterol mole fraction, and temperature for better understanding of phospholipid-cholesterol and cholesterol-cholesterol interactions. CSL motion in the membrane was treated as Brownian rotational diffusion of a rigid rod within the confines of a cone imposed by the membrane environment. The wobbling rotational diffusion constant of the long axis, its activation energy, and the cone angle of the confines are obtained for various membranes in the liquid-crystalline phase. The wobbling diffusion constant decreases in the order dilauroyl-PC greater than dimyristoyl-PC greater than dioleoyl-PC approximately dipalmitoyl-PC greater than distearoyl-PC greater than dioleoyl-PC/cholesterol = 3/1 greater than dioleoyl-PC/cholesterol = 1/1 membranes. Activation energy for the wobbling diffusion of the long axis of CSL is strongly dependent on alkyl chain length, unsaturation, and cholesterol mole fraction. It decreases with decrease in alkyl chain length and by introduction of unsaturation in the alkyl chains. In dioleoylphosphatidylcholine membranes, activation energy decreases by a factor of approximately 3 in the presence of 50 mol % cholesterol. Activation energy for wobbling diffusion of CSL in phosphatidylcholine membranes is smaller than the activation energy for translational diffusion of a phospholipid. The former is more dependent on alkyl chain length and unsaturation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Determination of cardamonin using a chemiluminescent flow-injection method

A sensitive and selective flow injection chemiluminescence method for the determination of cardamonin over the range 1.0 x 10(-8) to 8.0 x 10(-6) g/mL is described. The method is based on the enhancement by cardamonin of the chemiluminescence of the reaction between cerium (IV) and rhodamine 6G in sulphuric acid medium. The optimised flow injection procedure yielded a detection limit for cardamonin of 8.8 x 10(-9) g/mL, whilst the relative standard deviations of intraday and inter-day precision were below 2.5%. The method has the advantages of high sensitivity and a wide linear range. It was successfully applied to the determination of cardamonin in Alpinia katsumadai Hayata. The mechanism of the chemiluminescence reaction is proposed.