[Microrna, evolution and cancer].

MicroRNAs are known as a posttranscriptional negative regulators of gene expression by binding to the 3'UTP of target mRNAs in cytoplasm. More than 1600 microRNAs expressed in human cells, are involved in the regulation of embryogenesis, differentiation, cell cycle, apoptosis, senescence, thus determining cell fate. Up to 60 % of protein coding genes are under their control. Various sets of microRNAs found in different human tissues under normal and pathological conditions, including cancer, suggest that miRNAs are involved in most cellular pathways. To date, there is no doubt that regulatory potential of the genome is largely determined by miRNAs. In our study, we performed a comparative phylogenetic analysis of the origin and evolution of the total set of 1048 miRNAs in the human genome and investigated the role of certain miRNAs in carcinogenesis of thyroid and mammary glands, as potential diagnostic and prognostic biomarkers of malignancy. Analysis of phylogenetic distribution of miRNAs in the human genome has shown four peaks of appearance of new miRNA genes in the evolution from Methazoa to H. sapiens. The highest amount of new miRNA genes appeared after divergence of H. s. from common ancestor with P. t. Expansion of transposable elements in genome was accompanied by the origin of new miRNA genes on the basis of their sequences. More than 14 % from 1600 miRNAs of human genome originated from mobile elements and still remain. Profiles of expression of 5 miRNAs, pertaining to oncomicroRNAs - miR-21, -221, -222, -155 and -205 - allow distinguishing ductal invasive carcinoma of mammary gland and thyroid papillary carcinoma. The data obtained suggest different ways and roles of participation of the same miRNAs in carcinogenesis of thyroid and mammary glands. So, these miRNAs and profiles of their expression might be used in the diagnosis and prognosis of cancer.

[Leydig cell development].

This review is about the study of the testis Leydig cells formation and development in prenatal and postnatal periods. Leydig cells of testis are the main place of synthesis and secretion of androgens including testosterone--the main male sexual hormone. Testosterone plays an important role in male reproduction regulation. There are two types (two populations) of Leydig cells during ontogenesis. The first type is fetal Leydig cells, which appear and function in the prenatal masculinization period of the male urogenital system. Another type is adult Leydig cells, which originate during sexual maturation postnatally. Fetal and adult Leydig cells pass the same stages both in the prenatal and postnatal periods. They are Leydig cell progenitors, immature Leydig cells and adult Leydig cells.

[Effect of genotype on hormonal function formation of Leydig cells during mouse postnatal development]. / Vliianie genotipa na formirovanie gormonal'noi funktsii kletok Leidiga v postnatal'nom razvitii myshei.

Changes in in vitro testosterone production by Leydig cells induced by chorionic gonadotropin, dibutyryl-cAMP, and pregnenolone have been studied during postnatal development of four inbred mouse strains BALB/c, PT, CBA/Lac, and A/He, with contrast hormonal activity of testes in sexually mature males. The interlinear differences significantly change with age of the males by all studied indices indicating genotype-dependent formation of hormonal activity of Leydig cells during postnatal development. Coordinated interlinear variability between all indices of Leydig cells reactivity has been established for each studied period of postnatal development. Hence, we have established coordinated interlinear genetic variability of hormonal function of Leydig cells, which was confirmed by considerable changes in it during postnatal development at puberty. Definitive genotypic differences in hormonal activity of Leydig cells appeared by late pubertal and early postpubertal development (day 60) and coincided with termination of morphological differentiation of Leydig cells and appearance of the differentiated cell population.

[The role of genotype in the formation of Leydig cell hormone function during postnatal ontogeny in diallele crosses of laboratory mice]. / Znachenie genotipa v stanovlenii gormonal'noi funktsii kletok Leidiga v postnatal'nom ontogeneze v diallel'nykh skreshchivaniiakh u laboratornykh myshei.

Production of testosterone by Leydig cells during the postnatal ontogeny in pubescence under in vitro stimulation by chorionic gonadotropin, dibutiryl-cAMP, and pregnenolon was studied in males of four inbred mouse lines (BALB/c, RT, CBA/Lac, and A/He) and their F1 reciprocal hybrids. Highly statistically significant association between the animal genotype and age was revealed for all parameters studied, which indicates the genotype-dependent formation of the Leydig cell hormone function during the postnatal ontogeny. The effect of genotype was characterized by two specific features. First, in each postnatal ontogeny stages examined correlative genetic variability in respect of the cAMP- and substrate-dependent indices of Leydig cell reactivity was observed. Second, during postnatal ontogeny coordinated genetic variability was subjected to substantial ontogenetic rearrangements. Definite pattern of genetic differences in the Leydig cell hormone activity was formed only at the late pubertal--early post- pubertal stage (60th day after birth). This process coincided with the completion of the Leydig cell morphological differentiation and the appearance of mature cells in the population. Thus, formation of the Leydig cell hormone activity during postnatal ontogeny is under coordinated genetic control, which is also subjected to substantial changes during pubertal differentiation.