Identification and Characterization of a Novel Evolutionarily Conserved Lysine-specific Methyltransferase Targeting Eukaryotic Translation Elongation Factor 2 (eEF2)

The components of the cellular protein translation machinery, such as ribosomal proteins and translation factors, are subject to numerous post-translational modifications. In particular, this group of proteins is frequently methylated. However, for the majority of these methylations, the responsible methyltransferases (MTases) remain unknown. The human FAM86A (family with sequence similarity 86) protein belongs to a recently identified family of protein MTases, and we here show that FAM86A catalyzes the trimethylation of eukaryotic elongation factor 2 (eEF2) on Lys-525. Moreover, we demonstrate that the Saccharomyces cerevisiae MTase Yjr129c, which displays sequence homology to FAM86A, is a functional FAM86A orthologue, modifying the corresponding residue (Lys-509) in yeast eEF2, both in vitro and in vivo. Finally, Yjr129c-deficient yeast cells displayed phenotypes related to eEF2 function (i.e. increased frameshifting during protein translation and hypersensitivity toward the eEF2-specific drug sordarin). In summary, the present study establishes the function of the previously uncharacterized MTases FAM86A and Yjr129c, demonstrating that these enzymes introduce a functionally important lysine methylation in eEF2. Based on the previous naming of similar enzymes, we have redubbed FAM86A and Yjr129c as eEF2-KMT and Efm3, respectively.     

Ultrastructure and hydrolase activity in tobacco leaves exposed to chitosan

The mesophyll ultrastructure and hydrolase activity in leaves of tobacco cv. Samsun exposed to chitosan were studied. It was shown that, in many cells, chitosan treatment stimulated the protein-synthesizing apparatus (nucleolus size and amount of both mitochondria and membranes of rough endoplasmic reticulum increased). At the same time, we observed activation of the lytic compartment displayed as stimulated production of dictyosomes, smooth ER elements, and cytoplasmic vacuoles, which are prominent constituents of this compartment. Biochemical experiments showed that, in the leaves, chitosan substantially enhanced activity of hydrolases (acid phosphatase, RNase, proteases) as compared to untreated leaves. In some cells, chitosan treatment caused considerable destructive changes (condensation of nuclear chromatin, collapse of cytoplasm, etc.) that can be classified as development of programmed cell death.     

Simulation of individual risk based on the results of exercise tests and analysis of risk factors

The materials of a cross-sectional and prospective Russian-US population study (the Russian Lipid Research Clinics Prevalence Study) have been used to develop models intended for estimating the probability of death from coronary heart disease, all cardiovascular disease, and all causes over 10 and 20 years. The prediction was performed by constructing artificial neural networks. Testing on an independent sample has shown an accuracy of 66–73%.     

The microelemental composition of Magnitogorsk reservoir bottom sediments: Methodological aspects and paragenetic associations

The total content of 35 elements has been determined in the bottom sediments of the Magnitogorsk reservoir using SR XRF, and the number of mobile forms of 10 metals has been assessed using atomic absorption spectrometry. The characteristics of incomplete data statistical analysis as well as the reasons of similarity and discrepancies of data obtained by different chemical analytical methods have been considered. Four paragenetic associations of elements have been revealed using principal component analysis in the structure of bottom sediments: those related to organic matter, to the pelite fraction, pollutants from Magnitogorsk Iron and Steel Works, and motor transport pollutants.     

Allosteric transitions in cytochrome P450eryF explored with pressure-perturbation spectroscopy, lifetime FRET, and a novel fluorescent substrate, Fluorol-7GA

To establish a direct method for monitoring substrate binding in cytochrome P450eryF applicable at elevated hydrostatic pressures, we introduce a laser dye Fluorol-7GA (F7GA) as a novel fluorescent ligand. The high intensity of fluorescence and the reasonable resolution of the excitation band from the absorbance bands of P450 allowed us to establish highly sensitive binding assays compatible with pressure perturbation. The interactions of F7GA with P450eryF cause an ample spin shift revealing cooperative binding ( S50 = 8.2 +/- 1.3 microM; n = 2.3 +/- 0.1). Fluorescence resonance energy transfer (FRET) experiments suggest the presence of at least two substrate binding sites with apparent K D values in the ranges of 0.1-0.3 and 6-9 microM. Similar to that observed earlier with CYP3A4, increasing hydrostatic pressure does not cause either a complete dissociation of the substrate complexes or a displacement of the spin equilibrium toward the low-spin state. Rather, increased pressure enhances the cooperativity of the F7GA-induced spin shift, so that the Hill coefficient approaches 3 at 2 kbar. Lifetime FRET experiments revealed an important increase in the affinity of the enzyme for F7GA at elevated pressures, suggesting that the binding of the ligand induces a conformational transition associated with an important increase in the level of protein hydration. This transition largely attenuates the solvent accessibility of the heme pocket and causes an unusual stability of the high-spin, substrate-bound enzyme at elevated pressures.     

Effect of glutathione on homo- and heterotropic cooperativity in cytochrome P450 3A4

Glutathione (GSH) exerted a profound effect on the oxidation of 7-benzyloxy-4-(trifluoromethyl)coumarin (BFC) and 7-benzyloxyquinoline (BQ) by human liver microsomes as well as by CYP3A4-containing insect cell microsomes (Baculosomes). The cooperativity in O-debenzylation of both substrates is eliminated in the presence of 1-4 mM GSH. Addition of GSH also increased the amplitude of the 1-PB induced spin shift with purified CYP3A4 and abolished the cooperativity of 1-PB or BFC binding. Changes in fluorescence of 6-bromoacetyl-2-dimethylaminonaphthalene attached to the cysteine-depleted mutant CYP3A4(C58,C64) suggest a GSH-induced conformational changes in proximity of α-helix A. Importantly, the K_S value for formation of the GSH complex and the concentrations in which GSH decreases CYP3A4 cooperativity are consistent with the physiological concentrations of GSH in hepatocytes. Therefore, the allosteric effect of GSH on CYP3A4 may play an important role in regulation of microsomal monooxygenase activity in vivo.     

Replication Protein RepN Encoded by the RC Plasmid of Thermophilic Bacterium Thermoanaerobacterium saccharolyticum: Mutation Analysis and Deletion Mapping of Domains Responsible for Its Lethal Effect

Amino acid sequence analysis of the product encoded by repN of Thermoanaerobacterium saccharolyticum (Clostridium thermosaccharolyticum) pNB2, which is capable of rolling-circle (RC) replication, revealed all known motifs conserved among replication (Rep) proteins that initiate RC replication of plasmids related to pC194/pUB110. Using the T7 expression system in Escherichia coli, RepN was identified as a 35K protein. Its lethal effect on bacterial cells was unusually high for a protein of the kind. Mutation analysis of the potential active centers (Y85F and Y211F) showed that the lethal effect of RepN is not associated with its putative topoisomerase (relaxase) activity. On evidence of deletion mapping, the lethal effect was attributed to the N- and C-terminal domains, each accounting for about 30% of the total protein. The RepN fragments essential for the lethal effect were found to share a motif without appreciable homology to known conserved motifs. The high lethal effect of RepN was assumed to result from duplication of the motif and to play an adaptive role, providing for stable maintenance of the AT-rich plasmid in thermophilic bacterial cells.     

Contribution of native phosphorous-solubilizing bacteria of acid soils on phosphorous acquisition in peanut (<Emphasis Type="Italic">Arachis hypogaea</Emphasis> L.)

The present investigation analyzes the in vitro P solubilization [Ca-P, Al-P, Fe(II)-P, and Fe(III)-P] efficiency of native PSB strains from acid soils of Odisha and exploitation of the same through biofertilization in peanut (Arachis hypogaea L.) growth and P acquisition. One hundred six numbers of soil samples with pH ≤ 5.50 were collected from five districts of Odisha viz., Balasore, Cuttack, Khordha, Keonjhar, and Mayurbhanj. One bacterial isolate from each district were selected and analyzed for their P solubilization efficiency in National Botanical Research Institute Phosphate broths with Ca, Al, and Fe-complexed phosphates. CTC12 and KHD08 transformed more amount of soluble P from Ca-P (CTC12 393.30 mg/L; KHD08 465.25 mg/L), Al-P (CTC12 40.00 mg/L; KHD08 34.50 mg/L), Fe(III)-P (CTC12 175.50 mg/L; KHD08 168.75 mg/L), and Fe(II)-P (CTC12 47.40 mg/L; KHD08 42.00 mg/L) after 8 days of incubation. The bioconversion of P by all the five strains in the broth medium followed the order Ca-P > Fe(III)-P > Fe(II)-P > Al-P. The identified five strains were Bacillus cereus BLS18 (KT582541), Bacillus amyloliquefaciens CTC12 (KT633845), Burkholderia cepacia KHD08 (KT717633), B. cepacia KJR03 (KT717634), and B. cepacia K1 (KM030037) and further studied for biofertilization effects on peanut. CTC12 and KHD08 enhanced the soil available P around 65 and 58% and reduced the amount of each Al³⁺ about 79 and 81%, respectively, over the uninoculated control pots in the peanut rhizosphere. Moreover, all tested PSB strains could be able to successfully mobilize P from inorganic P fractions (non-occluded Al-P and Fe-P). The strains CTC12 and KHD08 increased the pod yield (114 and 113%), shoot P (92 and 94%), and kernel P (100 and 101%), respectively, over the control. However, B. amyloliquefaciens CTC12 and B. cepacia KHD08 proved to be the potent P solubilizers in promoting peanut growth and yield.