A method has been developed that combines electrospray ionization mass spectrometry with pH control to provide analysis of metals in native or reconstituted metallothioneins. These metalloproteins cooperatively bind seven divalent metal ions, most commonly Zn2+ and Cd2+. Since the protein is denatured and metal ions are lost below pH3, the pH of the electrospray solution is critical to successful results. The metal-free apoprotein was detected with its most abundant ions in a charge state of 6+, while the folded metallothionein-metal complexes were observed with lower charge states. The retention of seven metals in the molecular ions detected is consistent with the hypothesis that metallothionein retains its conformation in the gas phase. This mass spectrometric technique can be used to determine rapidly and accurately how many and what cations are incorporated per molecule of protein. Information about molar distributions and estimates of relative abundances of various complexes in the sample can be acquired in a single measurement.
Fimbrial adhesins of pathogenic bacteria are linear protein associates responsible for binding to the specific host cell receptors. They are assembled via the chaperone/usher pathway conserved in Gram-negative bacteria. These adhesive organelles are characterized by the high resistance to dissociation and unfolding caused by temperature or chemical denaturants. The self-complemented (SC) recombinant subunits of adhesive structures make up the minimal model used to analyze stability phenomena of these organelles. The SC subunits are both highly stabilized thermodynamically and kinetically. They are characterized by a standard free energy of unfolding of 70-80 kJ/mol and a rate constant of unfolding of 10(-17) s(-1) (half-life of unfolding of 10(8) years at 25 degrees C). The DraE subunit of Dr fimbriae is characterized by a disulfide bond that joins the beginning of the A1 strand with the end of the B strand. Such localization is unique and differentiates this protein from other proteins of the Ig-like family. Sequence analysis shows that many protein subunits of adhesive structures possess cysteines that may form a potential disulfide bond homologous to that of DraE. In this paper, we investigate the influence of this noncanonical disulfide bond on the stability of DraE-sc by constructing a DraE-sc-DeltaSS mutant protein (Cys/Ala mutant). This construct unfolds thermally at a T(m) of 65.4 degrees C, more than 20 degrees C lower than that of the native DraE-sc protein, and possesses a different unfolding mechanism. The calculated standard free energy of unfolding of DraE-sc-DeltaSS is equal to 30 +/- 5 kJ/mol. This allows us to suggest that the disulfide bond is an important stabilizing feature of many fimbrial subunits.
Abstract:We have developed a simple docking procedure that is able to utilize low-resolution models of proteins created by structure prediction algorithms such as threading or ab initio folding to predict the conformation of receptor-small ligand complexes. In our approach, using only approximate, discretized models of both molecules, we search for the steric and quasi-chemical complementarity between a ligand and the receptor molecules. This averaging procedure allows for the compensation of numerous structural inaccuracies resulting from the theoretical predictions of the receptor structure. The best relative orientation of these two models is obtained by an exhaustive scan over the rigid body's six-dimensional translational and rotational degrees of freedom. The search method is based on a real space grid-searching algorithm, unlike docking methods based on the fast Fourier Transform algorithm. We have applied this algorithm to rebuild structures of several complexes available in the Protein Data Bank. The structures of the receptors are produced by means of our threading algorithm PROSPECTOR, subsequently refined, and then utilized in the docking experiment. In many cases, not only is the localization of the binding site on the receptor surface correctly identified, but the proper orientation of the bounded ligand is also reasonably well reproduced within the level of accuracy of the modeled receptor itself.
In this paper, the hydration of a model protein--hen egg white lysozyme in aqueous solution has been presented. The leading method used was FTIR spectroscopy with an application of a technique of semi-heavy water (HDO) isotope dilution. Analysis of spectra of HDO isotopically diluted in water solution of lysozyme allowed us to isolate HDO spectra affected by lysozyme, and thus to characterise the energetic state of water molecules and their arrangement around protein molecules. The number of water molecules and the shape of the affected HDO spectrum were obtained using a classical and a chemometric method. This shape showed that the HDO spectrum affected by lysozyme may be presented as a superposition of two spectra corresponding to HDO affected by N-methylacetamide and the carboxylate anion (of the formic acid). Moreover, based on the difference in intermolecular distances distribution of water molecules (obtained from spectral data), we demonstrated that the lysozyme molecule causes a decrease in population of weak hydrogen bonds, and concurrently increases the probability of an occurrence of short hydrogen bonds in water affected by lysozyme. This conclusion was also confirmed by the molecular dynamics (MD) simulation.
Square-wave anodic stripping voltammetry (SWASV) of nanomolar concentration levels of lead and calcium at glassycarbon-based thin mercury film electrodes was Investigated In the presence of dissolved oxygen. Anodic stripping measurements In nondeaerated solutions were possible because of the depletion of oxygen at the electrode surface prior to the stripping step and because of the fast-scanning ability of square-wave voltammetry, which allows for the completion of the stripping step before any significant oxidation of the amalgam by diffusing oxygen can occur. Similar measurements by differential pulse anodic stripping voltammetry are not possible unless oxygen Is removed from solution. Thin mercury films showed good stability In the presence of dissolved oxygen. Linear calibration curves were obtained for lead and cadmium In acidic media (HCI and acetate buffer, pH 4.8), with no significant loss In stripping current sensitivity due to dissolved oxygen. The SWASV method was successfully used for the determination of lead In untreated, air-saturated tap water samples containing added 0.01 M HCI. The determinations by SWASV agreed very well with the results obtained by electrothermal atomic absorption spectrophotometry. With the time-consuming solution purging step absent and the very fast stripping step, the deposition step Is the only time-limiting factor of the method.
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