Vol 10, No 2 (2016)

The aim of this study was to estimate effects of some chemotherapy drugs on the elasticity and deformability of the membrane of a red blood cell (RBC). It was found that incubation of red blood cells (RBCs) with cisplatin or epoetin alpha led to considerable (by 10–17%; p < 0.05) increase in the RBC deformability and that cisplatin could activate tyrosine protein kinases (TPKs). Preincubation of RBCs with a specific inhibitor of EGF-R and Src kinase, lavendustin A, almost completely prevented the cisplatin effect. Tyrosine phosphatase inhibitor, sodium orthovanadate, increased the RBC deformability (p < 0.05). This effect was also abandoned by lavendustin A. To test a hypothesis on the involvement of protein kinases of mature RBCs in control of their membrane elasticity, the cells were incubated with phorbol 12-myristate 13-acetate (PMA) activating protein kinase Cα (PKCα). PMA increased the RBC deformability only moderately (by 8%, p < 0.05) and the effect was canceled by nonselective and selective PKC inhibitors staurosporin and 4-(1-methylindol-3-yl)maleimide hydrochloride. Erythropoietin is known to inhibit the nonselective cation channels of the RBC membrane; however, preincubation of the cells with verapamil did not cancel the increase in their deformability. Hence, this increase in deformability could be a result of the action of tyrosine protein kinases, the more so that this effect was almost completely canceled by lavendustion A. The results suggest that the presence of functionally active protein kinases and phosphatases in the membranes of mature RBC makes them a target for the addressed effects of signal molecules, including some chemotherapy drugs, causing consecutive alterations in the RBC membrane elasticity, microrheological properties, and transport potential.

The mechanisms of hyperexcitability of neuronal networks by ammonium ions and inhibition of this activity by coenzyme NAD were investigated on mixed neuro-glial cultures of rat hippocampus. Ammonium ions cause activation of silent or spontaneously active neuronal networks inducing a bursting electrical activity of neurons and high-frequency synchronous calcium oscillations. In control conditions NAD completely inhibits spontaneous activity of the neuronal network. NAD added after NH₄Cl disrupts synchronous oscillation in neurons and splits the network into five populations of neurons. In 4% of cells NAD decreased the amplitude of Ca²⁺ oscillations, preserving initial mode of oscillations. In 32% of cells, a transient suppression of the neuronal oscillations was observed: inhibition was followed by restoration of the synchronous periodic activity. In 10% of cells, NAD produced a gradual decrease of Ca²⁺ oscillations down to a complete termination of the initial periodic activity induced by ammonium. Fast and total inhibition of Ca²⁺ oscillations by NAD was observed in two small groups of neurons. First group (A) participated in the initial spontaneous network activity (5% of cells) with a period of 66–100 s. Second group (B), on the contrary, did not participate in the spontaneous activity. This group of neurons began to pulse with a high frequency (with a period of 6–8 s) synchronously with other neurons in the network after the addition of NH₄Cl. Based on the comparison of calcium responses of different cell groups to the depolarization caused by KCl and NH₄Cl and to the application of domoic acid, as well as on the results obtained in experiments with fluorescent antibodies against GAD 65/67, parvalbumin, calretinin, and calbindin, we propose that neurons of populations (A) and (B) may belong to GABAergic neurons containing calbindin and parvalbumin, respectively. Further analysis of specificity of the NAD effect on these neuronal groups may allow identification of the main targets of the ammonium toxic action in the brain. Thus, we have shown that NAD selectively inhibits neuronal activity and high-frequency synchronous Ca²⁺ oscillations in GABAergic neurons containing calcium-binding proteins. The inhibition is accompanied by desynchronization of oscillations and dissociation of neuronal network into several populations.

The EGFR/HER receptor family of an epidermal growth factor represents an important class of the receptor tyrosine kinases playing the key role in the control of cell growth and differentiation in mammalian cells, as well as in the development of a number of pathological processes, including oncogenesis. Binding of a ligand to the extracellular domains initiates switching of the EGFR/HER receptor between the alternative dimeric states that causes the allosteric activation of kinase domains in cell cytoplasm. The transmembrane (TM) domain and adjacent flexible regions alternatively interacting with either membrane surface or kinase domains are directly involved in the complex conformational transition in EGFR/HERs. Here we report on a highly efficient system of the cell free production of the EGFR/HER TM domains with functionally important juxtamembrane (JM) regions for the investigation of the molecular basis of biochemical signal transduction across the cell membrane. To increase the efficiency of synthesis of the EGFR/HER TM-JM fragments of the receptors, we used two N-terminal expression tags, which significantly increased the protein yield. In the case of the TM-JM fragments of EGFR (residues 638–692) and HER2 (residues 644–700), the method allowed us to obtain milligram quantities of the ¹³C,¹⁵N-labeled protein for structural and biophysical investigations in the membrane-mimicking environments using high-resolution heteronuclear NMR spectroscopy.

Exposure to heavy metals can initiate the development of negative effects in different organs and systems, including the immune system, and can be manifested as dysfunction of receptor systems and intracellular signaling. The participation of stable strontium (Sr²⁺) in the regulation of apoptotic signals in immunocompetent cells was analyzed. Various mechanisms of strontium-induced modulation of the apoptotic lymphocyte reaction were described, and the formation of intracellular signal transduction involving Sr²⁺ was defined. The flow cytometry method was used to study changes in membrane and intracellular markers of apoptosis in children who consumed drinking water with the elevated levels of strontium. It was shown that the content of strontium in blood in the range of 0.0129–0.173 mg/dm³ affected different ways of apoptosis regulation (CD95-, p53-, and TNF-induced apoptosis) and their integration sites, thereby reducing the transmission of apoptotic signal in immunocompetent cells, and formed an alternative pathway of the cell elimination based on the mechanism of necrosis.

The roles of glia and polyamines (PA) in brain function and dysfunction are highlighted in this review. We emphasize that PA accumulation preferentially in glia, but not in neurons, is clearly evolutionarily determined; it is found throughout the brain, retina, peripheral nervous system, and in glial-neuronal co-cultures of multiple species, including man. This phenomenon raises key questions: (i) What are the mechanisms that underlie such uneven distribution, accumulation and release from glia? (ii) What are the consequences of PA fluxes within the brain on neuronal function? (iii) What are the roles of PAs in brain disorders and diseases? This review includes suggestions on the roles of PAs, such as putrescine (PT), spermidine (SPD), spermine (SPM) and their derivatives as novel glio-transmitters in brain since PA affect many neuronal and glial receptors, channels and transporters. Polyamines hitherto have been neglected, although it is evident that these molecules are key elements for normal brain function and their metabolic disorders, apparently, cause the development of many pathological syndromes and diseases. The study of endogenous PA allows one to put forward the basic principles of scientific research on glio-neuronal interactions and clinical therapies, which are based on the exclusivity of glial cells in terms of accumulation of PA and PA-dependent functions.