Том 52, № 2 (2016)

The review discusses structural features of T-cadherin (T-cad) that allow it to perform functions other than cell–cell adhesion. T-cad is a receptor of the significant metabolic components, low-density lipoproteins and high-molecular-weight adiponectin. Association of cardiovascular and metabolic diseases with the T-cad gene polymorphism, as well as predominant T-cad expression in the cardiovascular system, cardioprotection and ischemic limb revascularization, depending on T-cad interaction with adiponectin, suggest a major role of this receptor in vascular and cardiac cell functioning. Possible mechanisms of T-cad-mediated regulation of metabolic processes are discussed.

A comparative enzymological investigation of inhibitory specificity of the liver monoamine oxidases (MAO) from the two frog species, lake frog Rana ridibunda and grass frog Rana temporaria, revealed certain interspecies similarities and distinctions of this enzyme. The anti-monoamine oxidase effect of five derivatives of acridine, three derivatives of phenothiazine and one derivative of xanthene (pyronine G) was comparatively analyzed. The tested six-membered tricyclic compounds were shown to exert an irreversible inhibitory effect on the enzyme from both biological sources, displaying the same substrate deamination specificity. Thus, the rate of interaction of acridine and phenothiazine derivatives with the MAO active center in both frog species was considerably higher when activity was determined using noradrenaline versus N-methylhistamine, while that of pyronine G—when activity was determined using N-methylhistamine versus noradrenaline. Interspecies quantitative differences were found in the inhibitory efficacy and degree of selectivity of the tested tricyclic compounds, indicative of the differences in catalytic properties of liver MAO at the interspecies level in the representatives of the genus Rana, family Ranidae. The data of substratespecific inhibitory analysis provide indirect evidence of the existence of two molecular MAO forms in the liver of the studied frog species.

To understand the emergence and evolutionary selection of the efficient mechanisms of innate immunity it is necessary to accumulate knowledge about the structural and functional properties of antimicrobial peptides in different animal species. The cationic antimicrobial peptides, α-defensins, were isolated from leukocytic extracts of the lower narrow-nosed monkey, hamadryas baboon Papio hamadryas, using ultrafiltration, preparative electrophoresis and reverse-phase highperformance liquid chromatography. Analysis of the antimicrobial properties of α-defensins showed that they display a wide spectrum of antimicrobial activity, comparable with that of human α-defensin HNP1, and exert bactericidal and fungicidal effects at micromolar concentrations. A study of the influence of different medium conditions on antimicrobial activity of α-defensins revealed that a higher ionic strength or the presence of blood serum leads to a marked decrease in antimicrobial activity of α-defensins, while pH has no appreciable effect on it. We found that hamadryas baboon α-defensins are able to increase the permeability of the outer and inner membranes of E. coli, suggests that the bacterial membrane is one of the major targets of the antimicrobial effects of these peptides. The revealed differences in antimicrobial activity of α-defensins may result from their structural heterogeneity, which reflects different pathways of evolution of α-defensins in primates and underlies the selectivity of their antimicrobial effect.

The genetic basis of rest–activity circadian alternation in animal behavior is considered in the evolutionary range from bacteria to mammals. We scrutinize various concepts of sleep development in the animal world evolution as well as the I.G. Karmanova’s theory of the sleep–wake cycle evolution in vertebrates, beginning from wakefulness–primary sleep (or protosleep) in fish and amphibians through wakefulness–intermediate sleep in reptiles to wakefulness–slow wave sleep (SWS) and paradoxical sleep (PS) in birds and mammals. Primary sleep is represented by the three major sleep-like immobility states: catalepsy, catatonia and cataplexy. The main behavioral, somatovegetative and neurophysiological characteristics of primary sleep and the ancient activation pattern during primary sleep are described. The issues of which of these sleep manifestations are homologous to SWS, PS, hibernation and stress response are discussed. In conclusion, the general diagram of sleep evolution in vertebrates is presented, and the I.G. Karmanova’s contribution to evolutionary somnology is highlighted.

Based on her studies of sleep disorders in patients with cataleptic schizophrenia syndrome, narcolepsy and Gille de la Tourette disease, I.G. Karmanova proposed an evolutionary-dissolution approach to sleep analysis. It helps not only identify the type of sleep–wake cycle abnormalities, but also analyze pathogenetic mechanisms of CNS disorders.