Kinase assay based on thiophosphorylation and biotinylation

Protein kinases catalyze the transfer of the gamma-phosphate group from ATP to a serine, threonine or tyrosine residue of an acceptor protein. These enzymes play an important role in signal transduction. New inhibitors for these enzymes are actively being sought. In this article, we present a novel approach for detecting the activity of protein kinases, which could be useful for the high-throughput screening of chemical libraries. The method is based on the use of ATP gamma S instead of ATP in the phosphorylation reaction. This results in the transfer of a thiophosphate group onto a fluorescein-labeled acceptor peptide substrate. The mixture is then treated with a sulfur-reactive iodoacetyl derivative of biotin, which leads to the modification of the nucleophilic sulfur of the thiophosphate group and the generation of a fluorescently labeled, biotinylated molecule. Finally, streptavidin is added to the mixture and it binds to all biotinylated molecules present. The binding of streptavidin to the thiophosphorylated and biotinylated kinase substrate can be conveniently detected by measuring the change in fluorescence polarization of the fluorescent dye attached to the peptide. The detection of kinase inhibitors is demonstrated. The method is completely homogeneous and does not require any separation steps.     

Unified two-metal mechanism of RNA synthesis and degradation by RNA polymerase

In DNA-dependent RNA polymerases, reactions of RNA synthesis and degradation are performed by the same active center (in contrast to DNA polymerases in which they are separate). We propose a unified catalytic mechanism for multisubunit RNA polymerases based on the analysis of its 3'-5' exonuclease reaction in the context of crystal structure. The active center involves a symmetrical pair of Mg(2+) ions that switch roles in synthesis and degradation. One ion is retained permanently and the other is recruited ad hoc for each act of catalysis. The weakly bound Mg(2+) is stabilized in the active center in different modes depending on the type of reaction: during synthesis by the beta,gamma-phosphates of the incoming substrate; and during hydrolysis by the phosphates of a non-base-paired nucleoside triphosphate. The latter mode defines a transient, non-specific nucleoside triphosphate-binding site adjacent to the active center, which may serve as a gateway for polymerization of substrates.     

Horizontal transfer of mercury resistance genes in natural bacterial populations

The results of studying the horizontal transfer of mercury resistance determinants in environmental bacterial populations are reviewed. Identical or highly homologous mercury resistance (mer) operons and transposons were found in bacteria of different taxonomic groups from geographically distant regions. Recombinant mer operons and transposons were revealed. The data suggest high frequencies of horizontal transfer and of recombination for mercury resistance determinants. The mechanisms of horizontal gene transfer were elucidated in Gram-negative and Gram-positive bacteria. New transposons were found and analyzed.     

Oligodeoxynucleotides containing 4-thiothymidine and 6-thiodeoxyguanosine as affinity labels for the Eco RV restriction endonuclease and modification methylase.

4-Thiothymidine and 6-thiodeoxyguanosine were incorporated into synthetic dodecamers containing the recognition site d(GATATC) of the enzymes Eco RV endonuclease and Eco RV methyltransferase. Upon irradiation with long wavelength UV light (340-360 nm), these oligodeoxynucleotides were photochemically crosslinked to both enzymes. The yields were up to 35% with the methyltransferase, but lower (up to 6%) with the endonuclease. Oligodeoxynucleotides containing 4-thiothymidine generally gave higher yields of crosslinking than those containing 6-thiodeoxyguanosine. Although both specific (i.e. those containing the d(GATATC) sequence) and non-specific (lacking this sequence) photoreactive oligodeoxynucleotides gave rise to crosslinked products, the use of a non-reactive, competitive substrate oligodeoxynucleotide suppressed the crosslinking, indicating that the reaction takes place at the enzymes' active sites. Oligodeoxynucleotides containing 4-thiocyanatothymidine or 6-thiocyanatodeoxyguanosine were also prepared by treatment of the title oligomers with CNBr and KCN. The dodecamers containing 4-thiocyanatothymidine were found to covalently modify both enzymes under study, with levels of crosslinking reaching up to 42% with the endonuclease and up to 12% with the methyltransferase. No crosslinking was observed with oligodeoxynucleotides containing 6-thiocyanatodeoxyguanosine.     

Anxiety as a risk factor of anthropogenic occupational malfunctions: Typological and corrective-prophylactic aspects

During the past one to two decades, practicing physicians and clinical researchers have shown an increasing interest in the psychogenic factors (especially chronic anxiety) that contribute to the development of emotional behavior disorders and anthropogenic occupational malfunctions. A comprehensive medical psychological assessment of 80 patients with high levels of predominantly deep-seated anxiety who had various (mainly indirect) complaints of the overall state of health and inadequate professional capacity was conducted. It has been found that the pathogenic effect of anxiety on the neuropsychological function increases with age and leads to professional failures and arterial hypertension and other psychosomatic dysfunctions (mainly in men prone to psychological suppression and ignoring anxiety). From a psychoprophylactic perspective (considering Leonhard’s personality accentuations), chronic anxiety demands comprehensive medical-psychological care in a timely manner.