Оценка гидрогеодинамического влияния режима эксплуатации скважин на основе статистических функций

Исследовано воздействие работы эксплуатационных скважин полигона захоронения промышленных отходов Сибирского химического комбината на колебание напоров в наблюдательных скважинах и выделение частотных составляющих техногенного и природного колебаний в спектре. Показана возможность использования функции взаимной корреляции и Фурье-анализа для оценки гидрогеодинамического влияния режима работы эксплуатационных скважин

Metal Ion Binding and Coordination Geometry for Wild Type and Mutants of Metallo-Beta -Lactamase from Bacillus Cereus 569/H/9 (Bcii): A Combined Thermodynamic, Kinetic, and Spectroscopic Approach

peer reviewedOne high affinity (nm) and one low affinity (microM) macroscopic dissociation constant for the binding of metal ions were found for the wild-type metallo-beta-lactamase from Bacillus cereus as well as six single-site mutants in which all ligands in the two metal binding sites were altered. Surprisingly, the mutations did not cause a specific alteration of the affinity of metal ions for the sole modified binding site as determined by extended x-ray absorption fine structure (EXAFS) and perturbed angular correlation of gamma-rays spectroscopy, respectively. Also UV-visible absorption spectra for the mono-cobalt enzymes clearly contain contributions from both metal sites. The observations of the very similar microscopic dissociation constants of both binding sites in contrast to the significantly differing macroscopic dissociation constants inevitably led to the conclusion that binding to the two metal sites exhibits negative cooperativity. The slow association rates for forming the binuclear enzyme determined by stopped-flow fluorescence measurements suggested that fast metal exchange between the two sites for the mononuclear enzyme hinders the binding of a second metal ion. EXAFS spectroscopy of the mono- and di-zinc wild type enzymes and two di-zinc mutants provide a definition of the metal ion environments, which is compared with the available x-ray crystallographic data

Determination of metal–metal distances: significance and accuracy

Nature utilises a variety of metal clusters as catalytic centers. Some of them make use of two or more metals in the catalytic site. The variation of metal-metal distances plays an important role in several processes like charge transfer and weakening of bonds. X-ray absorption spectroscopy can determine these metal-metal distances in several states (crystal, solution or amorphous). However sometimes backscattering from light elements hides the metal-metal contribution to the fine structure. Here we point out significance and accuracy of metal-metal distances in a model system. Therefore a number of different refinement protocols are applied to the data. These protocols will be discussed focusing on the significance and accuracy of the metal-metal distances extracted from the data

Functional analysis of the copper-dependent quercetin 2,3-dioxygenase. 2. X-ray absorption studies of native enzyme and anaerobic complexes with the substrates quercetin and myricetin

Quercetin 2,3-dioxygenase (2,3QD) is a mononuclear copper-dependent dioxygenase which catalyzes the cleavage of the heterocyclic ring of the flavonol quercetin (5,7,3′,4′-tetrahydroxy flavonol) to produce 2-protocatechuoyl-phloroglucinol carboxylic acid and carbon monoxide. In this study, X-ray absorption spectroscopy has been used to characterize the local structural environment of the Cu2+ center of Aspergillus japonicus 2,3QD. Analysis of the EXAFS region of native 2,3QD at functionally relevant pH (pH 6.0) indicates an active site equally well-described by either four or five ligands (3N(His) + 1-20) at an average distance of 2.00 Å. Bond valence sum analysis confirms that the best model is somewhere between the two. When, however, 2,3QD is anaerobically complexed with its natural substrate quercetin, the copper environment undergoes a transition to a five-coordinated cage, which is also best modeled by a single shell of N/O scatterers at the average distance of 2.00 Å. This coordination is independently confirmed by the anaerobic complex with myricetin (5′-hydroxy quercetin). XANES analysis confirms that substrate binding does not reduce the Cu2+ ion. The present study gives the first direct insights into the coordination chemistry of the enzyme complexed with its substrates. It suggests that activation for O2 attack is achieved by monodentate substrate complexation to the copper ion through the 3-hydroxyl group. In addition, monodentate carboxylate ligation by the Glu73 side chain is likely to play a role in the fine-tuning of the equilibrium leading to the formation of the activated E·S complex

X-ray absorption spectroscopic studies on model compounds for biological iodine and bromine

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The Metal-Dependent Regulators FurA and FurB from Mycobacterium Tuberculosis

The ferric uptake regulators (Fur) form a large family of bacterial metalactivated DNA-binding proteins that control a diverse set of genes at the transcriptional level. Mycobacterium tuberculosis, the causative agent of tuberculosis, expresses two members of the Fur family, designated FurA and FurB. Although both belong to the same family, they share only approximately 25% sequence identity and as a consequence, they differ significantly in some of their key biological functions. FurA appears to be a specialized iron-dependent regulator that controls the katG gene, which encodes for a catalase-peroxidase involved in the response of M. tuberculosis to oxidative stress. KatG is also the key mycobacterial enzyme responsible for the activation of the first-line tuberculosis drug Isoniazid. FurB in contrast requires Zn2+ rather than Fe2+, to bind to its target sequence in regulated genes, which include those involved in Zn2+-homeostasis. Recent biochemical, crystallographic and spectroscopic data have now shed light on the activation and metal discrimination mechanisms in this protein family