[INDUCTION OF DECIDUAL DIFFERENTIATION OF ENDOMETRIAL MESENCHYMAL STEM CELLS].

In this study, we compared the ability of human mesenchymal stem cells derived from menstrual blood (eMSCs) and mesenchymal stem cells (MSCs) from other tissues to differentiate into decidual cells in vitro. It was demonstrated that during differentiation secretion of decidualization markers (prolactin and insulin-like growth factor binding protein-1) increases in eMSCs from adipose tissue (MSC-AD). Thus, the ability of eMSCs to differentiate into decidual cells is much higher than MSC-BM or MSC-AD. It makes eMSCs promising for application in cellular therapy of infertility associated with decidualzation insufficiency.

[CHARACTERISTIC OF ENDOMETRIAL MESENCHYMAL STEM CELLS IN CULTURE OBTAINED FROM PATIENT WITH ADENOMYOSIS].

Adenomyosis is form of endometriosis, common diseases of female reproductive system, which can lead to infertility in women. in this study we are obtained and characterized cell line endometrial mesenchymal stem cells from a patient with adenomyosis, and compare obtained cells with the cell line of healthy donor. Aim of this study was to assesses the extent of differences between cells from donor with adenomyosis and cells from healthy donor. Was established that compared lines had morphology like fibroblasts, were differentiated in adipocytes, were expressed mesenchymal markers and didn't expressed haematopoietic markers. Cytogenetic analysis of differentially stained metaphase chromosomes on G-banding (passage 6-7) showed that healthy donor's cells had predominantly normal karyotype. The cellular line from a patient with diagnosis of "adenomyosis" had a lot of cells with changes in karyotype's structure. These changes were related with aneuploidy of cellular population and the presence non-random chromosomal breaks, often in chromosomes 7 and 11. Analysis of this data allows the cells from adenomyosis characterized physiological stability in culture and karyotypic instability with non-random involvement certain chromosomal set. The cellular line obtained from donor with adenomyosis showed signs destabilization of he genome, typical for cell transformation. Division of adenomyosis cells to the 26th passage is stopped and these cells entered into a phase of replicative aging. Based on this, we can conclude that founded karyotype's hanges do not lead to transformation and immortalization of cells in vitro.

[DNA CONTENT IN INDIVIDUAL CHROMOSOMES OF NORMAL CHINESE HAMSTER KARYOTYPE AND CHROMOSOMES OF CONSTANT HAMSTER CELL LINES CHL V-79 RJK AND Vebr-5].

Using cytometry and an microfluorimetry, we have determined the genome size in Chinese hamster Cricetulus griseus, as well as absolute and relative DNA content of its individual chromosomes and of chromosomes in the transformed Chinese hamster cell lines V-79 RJK and Vebr-5 after prolonged cultivation. It has been shown that the genome size in male and female Chinese hamster is 6.660 and 6.746 pg, respectively. Absolute content of chromosomal DNA of both studied cell lines differed significantly from the content of the corresponding chromosomal DNA of the Chinese hamster normal karyotype. During long-term cellular cultivation, changes in the DNA content of certain chromosomes in both cell lines (generally upward) reached 20-25 %. The level of DNA amplification in the p-arm of chromosome Z6, registered at the beginning of the experiment, in the course of further cellular cultivation (over 20 years) remained stable. The data obtained allow us to conclude that the malignant transformation of cells and subsequent adaptation to the conditions in vitro leads to a profound restructuring of its genome, which affects almost all chromosomes.

[Long-term cultivation of Chinese hamster fibroblasts of line V-79 RJK under elevated temperature leads to karyotype structure destabilization].

In this article we show that long-term cultivation of Chinese hamster fibroblasts of line V-79 RJK at elevated temperature resulted in the selection of variants with genetic changes at the level of karyotype. From the first steps of resistance selection to elevated temperature we identified population of cells with changes in karyotype (polyploidy cells, deletions, inversions, translocations of chromosomes, and some cells with DM-chromosomes). Further cultivation was accompanied with selection of cells with paracentrical chromosome breakages and HSR's on chromosomes. Nonspecific destabilization of the karyotype (on first steps of selection) was associated with increased expression of hsc70 and pgp. After long-term incubation at an elevated temperature, the cells with karyotypic changes had the basal level of hsc70 and pgp expression.

High doses of synthetic antioxidants induce premature senescence in cultivated mesenchymal stem cells.

Stress-induced premature senescence program is known to be activated in cells by various genotoxic stressors, and oxidative stress is considered to be the main of those. To this end, many studies discover antioxidants as protective anti-aging agents. In the current study, we examined the effects of different antioxidants (Tempol, resveratrol, NAC, DPI) on the mesenchymal stem cells maintained in normal physiological conditions. We used high, but non-cytotoxic antioxidant doses which are widely used in laboratory practice to protect cells from oxidative damage. We show that these substances induce reversible block of cell proliferation and do not cause any genotoxic effects when applied to the quiescent cells. However, the same doses of the same substances, when applied to the proliferating cells, can induce irreversible cell cycle arrest, DNA strand breaks accumulation and DNA damage response activation. As a consequence, antioxidant-induced DNA damage results in the stress-induced premature senescence program activation. We conclude that high doses of antioxidants, when applied to the proliferating cells that maintain physiological levels of reactive oxygen species, can cause DNA damage and induce premature senescence which suggests to re-estimate believed unconditional anti-aging antioxidant properties.

Quiescent Human Mesenchymal Stem Cells Are More Resistant to Heat Stress than Cycling Cells.

Quiescence is the prevailing state of many cell types under homeostatic conditions. Yet, surprisingly, little is known about how quiescent cells respond to environmental challenges. The aim of the present study is to compare stress responses of cycling and quiescent mesenchymal stem cells (MSC). Human endometrial mesenchymal cells (eMSС) were employed as adult stem cells. eMSC quiescence was modeled by serum starvation. Sublethal heat shock (HS) was used as a stress factor. Both quiescent and cycling cells were heated at 45°C for 30 min and then returned to standard culture conditions for their recovery. HS response was monitored by DNA damage response, stress-induced premature senescence (SIPS), cell proliferation activity, and oxidative metabolism. It has been found that quiescent cells repair DNA more rapidly, resume proliferation, and undergo SIPS less than proliferating cells. HS-enforced ROS production in heated cycling cells was accompanied with increased expression of genes regulating redox-active proteins. Quiescent cells exposed to HS did not intensify the ROS production, and genes involved in antioxidant defense were mostly silent. Altogether, the results have shown that quiescent cells are more resistant to heat stress than cycling cells. Next-generation sequencing (NGS) demonstrates that HS-survived cells retain differentiation capacity and do not exhibit signs of spontaneous transformation.

Molecular Genetic Analysis of Human Endometrial Mesenchymal Stem Cells That Survived Sublethal Heat Shock.

High temperature is a critical environmental and personal factor. Although heat shock is a well-studied biological phenomenon, hyperthermia response of stem cells is poorly understood. Previously, we demonstrated that sublethal heat shock induced premature senescence in human endometrial mesenchymal stem cells (eMSC). This study aimed to investigate the fate of eMSC-survived sublethal heat shock (SHS) with special emphasis on their genetic stability and possible malignant transformation using methods of classic and molecular karyotyping, next-generation sequencing, and transcriptome functional analysis. G-banding revealed random chromosome breakages and aneuploidy in the SHS-treated eMSC. Molecular karyotyping found no genomic imbalance in these cells. Gene module and protein interaction network analysis of mRNA sequencing data showed that compared to untreated cells, SHS-survived progeny revealed some difference in gene expression. However, no hallmarks of cancer were found. Our data identified downregulation of oncogenic signaling, upregulation of tumor-suppressing and prosenescence signaling, induction of mismatch, and excision DNA repair. The common feature of heated eMSC is the silence of MYC, AKT1/PKB oncogenes, and hTERT telomerase. Overall, our data indicate that despite genetic instability, SHS-survived eMSC do not undergo transformation. After long-term cultivation, these cells like their unheated counterparts enter replicative senescence and die.