Vol 10, No 3 (2016)

Cells of almost all tissues secrete to the extracellular environment a variety of vesicular structures. The most interesting vesicles are exosomes–microvesicles ranging from 30 to 100 nm in size. These vesicles contain various RNA, including mRNA, microRNA, as well as membrane and cytoplasmic proteins that can be transported in these particles to nearby and distantly located cells of various tissues using physiological fluids (blood, urine, saliva, etc.). Exosomes are necessary for normal functioning of the organism and their repertoire changes during the development of pathologies. This review presents the data on generation, secretion, and transport of exosomes, their structure and roles in normal conditions and in the process of the malignant tumor development. Prospects of the application of exosomal biomarkers for the development of early non-invasive cancer diagnosis are also discussed.

Expression of transcription factors FOXP3 and RORγt in CD4⁺ thymocytes of children with different severity of congenital heart disease (CHD) related with the level of hypoxia was studied. Expression of FOXP3 and RORγt was evaluated in 72-h culture of CD4⁺ thymocytes isolated from thymus fragments of children under twelve months with CHD of different severity (white defect, n = 7; blue malformation, n = 7) in the conditions of the specific induction of the formation of natural regulatory T lymphocytes (nTreg) and IL-17-producing T lymphocytes (Th17). It was found that in CD4⁺ thymocytes of children with blue type CHD the expression of both FOXP3 and RORγt was increased as compared to CD4⁺ thymocytes of the children with white type CHD. An increase in the Th17 level in the children with blue type CHD was accompanied by an increase in the intracellular expression and concentrations of IL-17A in supernatants of cultured CD4⁺ thymocytes. The results point to an important role of the severity of hypoxia in the regulation of the expression of FOXP3 and RORγt in CD4⁺ thymocytes of children, as well as in the formation of nTreg and Th17 in the thymus.

The effect of palmitic acid on the oxidation of dopamine, i.e., on the monoamine oxidase (MA-oxidase) activity, was investigated on deenergized liver mitochondria, upon energization by ATP and also in the presence of an oxidizing agent tert-butylhydroperoxide (TBH). It was found that palmitic acid reduces the value of the apparent K_m for dopamine without alteration of the apparent V_max. This points to stimulation of the mitochondrial MA-oxidase activity by palmitic acid at low concentrations of dopamine. Stimulatory effect of palmitic acid may be related to the ability of amphiphilic compounds to increase the negative charge density on the outer mitochondrial membrane. This leads to an increase in the local concentration of positively charged ions of dopamine in the layer adjacent to the membrane near the active site of monoamine oxidase. ATP eliminates the ability of palmitic acid to stimulate the MA-oxidase activity of mitochondria. This effect of ATP is not observed in the presence of the F_OF₁-ATP-synthase inhibitor oligomycin. Apparently, in the case of vector transport of H⁺ from the matrix induced by ATP-hydrolysis, protonation of palmitic acid anions occurs on the outer mitochondrial membrane, followed by the movement of the neutral molecules to the outer and then to the inner monolayer of the inner membrane. It was found that TBH at a concentration of 300 μM has no significant effect on the ATPase activity of mitochondria and in the presence of ATP and palmitic acid reduces the value of the apparent K_m for dopamine without alteration of the apparent V_max. Antioxidant thiourea eliminates this effect of TBH. We propose that the TBH-induced oxidative stress in the case of ATP-energized mitochondria results in the movement of palmitic acid molecules from the inner to the outer membrane. This leads to an increase in the density of negative charges on the surface of this membrane and, therefore, to the stimulation of the dopamine oxidation.

The aim of this work was to study the influence of aging, obesity, metabolic syndrome (MS), hypertension (HT), and type 2 diabetes (T2D) on the endogenous rhythmic activity and the development acetylcholine resistance in aorta rings of male rats. T2D was produced by a free access to fat (lard). It was shown that phenylephrine (PE) or 5-hydroxytryptamine (5-HT) induces two types of rhythmic contractions: with periods T₁ = 3–10 s and T₂ = 50–70 s and amplitudes A₁ = 1–5% and A₂ = 20–40% of the maximal contraction force (F_max), respectively. Such periodic modes can be caused by the operation of two known positive feedback loops (PFL) based on the Ca²⁺-induced activation of IP3 receptor (IP3R) or phospholipase C PFL1 and PFL2, respectively, and are not eliminated by L-NAME. Slow rhythmic activity induced by acetylcholine (Ach) with period T₃ = 7–20 min and amplitude A₃ = 20–30% of F_max was observed only in young animals (under 6 months) and can be determined by the operation of PFL3, involving Ca²⁺, NO, kinase G, cADP-ribose, and the ryanodine receptor (RyR). Fast mode of contractions (T₁, A₁) is maintained regardless of age and the presence of MS and HT (140 mm Hg and higher) and disappears only at later stages of the T2D development. Probability of intermediate mode of contractions (T₂, A₂) decreases to 0.20–0.25 at the age of 14–16 months or during the development of HT and MS. In these circumstances, Ach could cause relaxation of preconstricted rings only to 40 and 60% of F_max, respectively. At the stages of the T2D development characterized by high values of arterial pressure (above 150 mm Hg) and of the glucose (10–12 mM), ammonium (120–180 μM), and blood lipid levels, as well as by liver dysfunction (fibrosis/cirrhosis), the rhythmic activity of any type is lost and dysfunction of the initial part of the signaling cascade with the participation of PFL3 is manifested by the absence of responses to Ach or L-NAME. Coenzyme NAD (agonist of the P2Y receptors, К⁺ channel activator and a precursor of cADP-ribose) can exert a partial relaxation of aorta rings from healthy animals and animals with MS. Nicotinamide (product and an inhibitor of ADP-ribosyl cyclase) and SNP (donor of NO) produce an effective relaxation of aorta rings from healthy animals and animals with T2D. Relaxing effect of nicotinamide may suggest a tandem operation of IP3R and RyR in the control of intracellular Ca²⁺ stores in vascular cells.

Using vesicles of symbiosome membrane (SM), it was shown that the Ca²⁺-ATPase can function as an ATP-energized Ca²⁺/H⁺ antiporter. The initial rate of the acidic shift inside the vesicles, as well as the rate of the ITP-dependent alkalization of the medium inside them markedly increased in the presence of valinomycin. This process was rapidly stopped by eosin Y, a known inhibitor of the type IIB Ca²⁺-ATPase. ITP-dependent uptake of Ca²⁺ was blocked after the addition to the reaction mixture of nigericin in the presence of K⁺. Under these conditions, the alkaline shift of pH inside the vesicles occurred, leading to the inhibition of operation of the calcium pump in SM. Evaluation of the pH shifts inside the vesicles by using pH-indicator pyranine confirmed the ion-exchange mechanism of the Ca²⁺-ATPase functioning in the SM.

The use of fluorescent reagents for the histochemical detection of catecholamines or histamine, as well as luminescent antagonists of the intracellular neurotransmitters revealed that they can bind to certain cellular compartments. After the treatment with glyoxylic acid (a reagent used for the detection of catecholamines), blue fluorescence with maximum at 460–475 nm was visualized in nuclei and chloroplasts (in control preparations no emission in this spectral region was recorded), as well as an intense fluorescence, exceeding the control level, in the vacuoles. After the exposure to ortho-phthalic aldehyde (a reagent used for the histamine detection), blue emission was more noticeable in nuclei and chloroplasts, which correlates with previously observed effects on intact cells, such as pollen and vegetative microspores. A comparison of the intensities of the biogenic amine-related emission in various organelles showed that the greatest emission was in vacuoles and the weakest, in chloroplasts. Thus, on the surface, and possibly within the organelles, fluorescence could demonstrate the presence of biogenic amines. Antagonists of the neurotransmitters (dtubocurarine for acetylcholine; yohimbine for dopamine; norepinephrine and inmecarb for serotonin), which fluoresce in the blue and blue-green region and usually bind with the plasmalemma of intact cells, also interacted with the membranes of the organelles studied. Fluorescence intensity depended on the object; most prominent it was for yohimbine in the outer membrane of the nucleus, vacuoles, and chloroplasts.