[Low-Molecular Thiols as a Factor Improving the Sensitivity of Escherichia coli Mutants with Impaired ADP-Heptose Synthesis to Antibiotics].

Low molecular-weight thiols as glutathione and cysteine are an important part of the cell's redox regulation system. Previously, we have shown that inactivation of ADP-heptose synthesis in Escherichia coli with a gmhA deletion induces the oxidative stress. It is accompanied by rearrangement of thiol homeostasis and increased sensitivity to antibiotics. In our study, we found that restriction of cysteine metabolism (ΔcysB and ΔcysE) and inhibition of glutathione synthesis (ΔgshAB) lead to a decrease in the sensitivity of the ΔgmhA mutant to antibiotics but not to its expected increase. At the same time, blocking of the export of cysteine (ΔeamA) or increasing import (Ptet-tcyP) into cells of the oxidized form of cysteine-cystine leads to an even greater increase in the sensitivity of gmhA-deleted cells to antibiotics. In addition, there is no correlation between the cytotoxic effect of antibiotics and the level of reactive oxygen species (ROS), the total pool of thiols, or the viability of the initial cell population. However, a correlation between the sensitivity to antibiotics and the level of oxidized glutathione in cells was found in our study. Apparently, a decrease in the content of low-molecular-weight thiols saves NADPH equivalents and limits the processes of protein redox modification. This leads to increasing of resistance of the ΔgmhA strain to antibiotics. An increase in low-molecular-weight thiols levels requires a greater expenditure of cell resources, leads to an increase in oxidized glutathione and induces to greater increase in sensitivity of the ΔgmhA strain to antibiotics.

[Metabolic Stress of Red Blood Cells Induces Hemoglobin Glutathionylation].

Metabolic stress caused by a lack of glucose significantly affects the state of red blood cells, where glycolysis is the main pathway for the production of ATP. Hypoglycemia can be both physiological (occurring during fasting and heavy physical exertion) and pathological (accompanying a number of diseases, such as diabetes mellitus). In this study, we have characterized the state of isolated erythrocytes under metabolic stress caused by the absence of glucose. It was established that 24 h of incubation of the erythrocytes in a glucose-free medium to simulate blood plasma led to a two-fold decrease in the ATP level into them. The cell size, as well as intracellular sodium concentration increased. These findings could be the result of a disruption in ion transporter functioning because of a decrease in the ATP level. The calcium level remained unchanged. With a lack of glucose in the medium of isolated erythrocytes, there was no increase in ROS and a significant change in the level of nitric oxide, while the level of the main low-molecular weight thiol of cells, glutathione (GSH) decreased by almost 2 times. It was found that the metabolic stress of isolated red blood cells induced hemoglobin glutathionylation despite the absence of ROS growth. The cause was the lack of ATP, which led to a decrease in the level of GSH because of the inhibition of its synthesis and, probably, due to a decrease in the NADPH level required for glutathione (GSSG) reduction and protein deglutathionylation. Thus, erythrocyte metabolic stress induced hemoglobin glutathionylation, which is not associated with an increase in ROS. This may have an important physiological significance, since glutathionylation of hemoglobin changes its affinity for oxygen.

[Blood-Brain Barrier Transwell Modeling].

In vitro blood-brain barrier (BBB) modeling with the use of the brain endothelial cells grown on a transwell membrane is widely used to investigate BBB disorders and factors intended to ameliorate these pathologies. Endothelial cells, due to tight junction proteins, ensure selective permeability for a number of substances. The low integrity (i.e., high permeability) of the BBB model, as compared to the physiological one, complicates evaluation of the effects caused by different agents. Thus, the selection of conditions to improve barrier integrity is an essential task. In this study, mouse brain endothelial cells bEnd.3 are used in experiments on transwell modeling. To determine which factors enhance BBB integrity, the effects of the cultivation medium, the number of cells during seeding, the state of the transwell membrane, and cultivation in the presence or in the absence of primary mouse neurons and matrigel as a matrix on the passage of a fluorescent label through the cell monolayer were assessed. The effect of fetal bovine serum on the tight junction protein claudin-5 was analyzed by immunocytochemistry. The obtained cultivation parameter data facilitate the solution to the problem of low integrity of the BBB transwell model and bring the model closer to the physiologically relevant indicators.

[Combination of RNase Binase and AKT1/2 Kinase Inhibitor Blocks Two Alternative Survival Pathways in Kasumi-1 Cells].

Treatment of malignant neoplasms often requires the use of combinations of chemotherapeutic agents. However, in order to select combinations that are effective against specific tumor cells, it is necessary to understand the mechanisms of action of the drugs that make up the combination. Bacillus pumilus ribonuclease (binase) is considered as an adjuvant antitumor agent, and the sensitivity of malignant cells to the apoptogenic effect of binase depends on the presence of certain oncogenes. In the acute myelogenous leukemia cell line Kasumi-1, binase blocks the proliferation pathway mediated by the mutant tyrosine kinase KIT, which, as shown in our work, activates an alternative proliferation pathway through AKT kinase. In Kasumi-1 cells, binase in combination with an Akt1/2 inhibitor induces apoptosis, and their toxic effects add up: the Akt1/2 inhibitor blocks the binase-induced pathway after suppression of the KIT-dependent pathway. Thus, a combination of binase and AKT kinase inhibitors can effectively block various pathways of tumor cell proliferation and be used for their elimination.

[Enhancement of Na,K-ATPase Activity as a Result of Removal of Redox Modifications from Cysteine Residues of the al Subunit: the Effect of Reducing Agents].

Na,K-ATPase is a transmembrane enzyme that creates a gradient of sodium and potassium, which is necessary for the viability of animal cells. The activity of Na,K-ATPase depends on the redox status of the cell, decreasing with oxidative stress and hypoxia. Previously, we have shown that the key role in the redox sensitivity of Na,K-ATPase is played by the regulatory glutathionylation of cysteine residues of the catalytic alpha subunit, which leads to the inhibition of the enzyme. In this study, the effect of reducing agents (DTT, ME, TCEP) on the level of glutathionylation of the alpha subunit of Na,K-ATPase from rabbit kidneys and the enzyme activity has been evaluated. We have found that the reducing agents partially deglutathionylate the protein, which leads to its activation. It was impossible to completely remove glutathionylation from the native rabbit kidney protein. The treatment of a partially denatured protein on the PVDF membrane with reducing agents (TCEP, NaBH4) also does not lead to the complete deglutathionylation of the protein. The obtained data indicate that Na,K-ATPase isolated from rabbit kidneys has both regulatory and basal glutathionylation, which appears to play an important role in the redox regulation of the function of Na, K-ATPase in mammalian tissues.

[Isomerization of Asp7 increases the toxic effects of amyloid ß and its phosphorylated form in SH-SY5Y neuroblastoma cells].

The generation of amyloid ß (Aß) toxic oligomers during the formation of senile plaques and amyloid fibrils is thought to play a central role in the onset and progression of Alzheimer's disease. Aß production is a physiological process, but the factors that trigger a transition to pathogenic Aß aggregation remain unknown. Posttranslational modifications of Aß could potentially induce the transition. The effects of Aß and its modified forms containing isomerized Asp7, phosphorylated Ser8, or both, were studied in SH-SY5Y human neuroblastoma cells. Asp7 isomerization of was shown to increase cytotoxicity of both the intact and phosphorylated Aß. An increase in cytotoxicity was not associated with an increased internalization of the isomerized Asp7-containing Aß or an influence on the function of mitochondria or reduced glutathione and reactive oxygen species levels. The nitric oxide (NO) level was identified as a determinant of the cytotoxic effect of isomerized Asp7-containing peptides, a decrease in NO level correlating with an increase in cytotoxicity.

Identification of a Region of the Polypeptide Chain of Na,K-ATPase α-Subunit Interacting with 67-kDa Melittin-Like Protein.

It was shown earlier that a 67-kDa protein purified from mouse kidney using polyclonal antibodies against melittin (a peptide from bee venom) interacted with Na,K-ATPase from rabbit kidney. In this study, a 43-kDa proteolytic fragment of Na,K-ATPase α-subunit interacting with the 67-kDa melittin-like protein was found. The α-subunit was hydrolyzed by trypsin in the presence of 0.5 mM ouabain (E2-conformation of Na,K-ATPase). A proteolytic fragment interacting with the 67-kDa melittin-like protein that was identified by mass-spectrometry is a region of the cytoplasmic domain of Na,K-ATPase α-subunit located between amino acid residues 591 and 775. The fragment includes a conservative DPPRA motif that occurs in many P-type ATPases. It was shown earlier that this motif of H,K-ATPase from gastric mucosa binds to melittin. We suggest that namely this motif of P-type ATPases is able to interact with proteins containing melittin-like modules.

[Ribonuclease binase induces death in T-cell acute lymphoblastic leukemia cells by apoptosis].

Bacterial ribonuclease binase is a potential anticancer agent. In the present study, we have determined the toxic effect of binase towards cell lines of T-cell acute lymphoblastic leukemia Jurkat and CEMss. We have shown that binase induces apoptosis in these cells. At the same time, binase does not cause toxic effects in leukocytes of healthy donors, which suggests that binase activity towards leukemic cells is selective. We have found that the treatment of cancer cells with binase leads to a reduction in reactive oxygen species and transcription factor NFκB levels, and demonstrated that these effects are a common feature of the action of RNases on cancer cells.

Glutathionylation of the alpha-subunit of Na,K-ATPase from rat heart by oxidized glutathione inhibits the enzyme.

A partially purified Na,K-ATPase preparation from rat heart containing α1- and α2-isoforms of the enzyme was shown to include both subunits in S-glutathionylated state. Glutathionylation of the α1-subunit (but not of the α2-subunit) was partially removed when the preparation was isolated in the presence of dithiothreitol. The addition of oxidized glutathione irreversibly inhibited both isoforms. Inhibition of the enzyme containing the α1-subunit was biphasic, and the rate constants of the inhibition were 3745 ± 360 and 246 ± 18 M(-1)·min(-1). ATP, ADP, and AMP protected the Na,K-ATPase against inactivation by oxidized glutathione.