Mesenchymal stem cells: a brief review of classis concepts and new factors of osteogenic differentiation

Molecular genetic mechanisms, signaling pathways, cultural conditions, factors, and markers of osteogenic differentiation of mesenchymal stem cells (MSC) are actively studied despite numerous works in this area of cellular technologies. This is largely due to the accumulating contradictions in seemingly classical knowledge, as well as permanent updating of the results in the field. In this regard, we focused on the main classical concepts and some new factors and mechanisms that have a noticeable regulatory effect on the differentiation potential of postnatal MSCs. The present review considers the significance of MSC sources for their differentiation capacity, as well as the role of the cellular microenvironment. The issues of classification, terminology, and functional activity of MSCs from various sources are discussed. The paracrine potential of MSCs in tissue regeneration has been considered; sufficient importance of inflammation in osteogenesis is noted, in particular, the presence of inflammatory cytokines and chemokines in the lesion focus, produced not only by microenvironmental cells but also by blood cells, including mononuclear leukocytes, migrating to the affected site. An important role in this review is given to biomechanical signals and to influence of conformational changes in cell cytoskeleton (cell shape) upon MSC differentiation, since the morphological features of cells and the structure of cytoskeleton are modulated by interactions of the cell surface with environmental factors, including hydrostatic pressure, fluid flow, compression/stretching loads. The data are presented concerning elasticity of extracellular matrix being a determining factor of cell differentiation. We conclude that one should switch from point studies of individual gene effects to multiple measurements of the gene-regulatory profile and biomolecules responsible for multiple, still poorly studied osteogenic factors of endogenous and exogenous origin. Among cornerstones in future (epi)genetic studies will be to decide if osteomodulatory effects are realized through specific signaling pathways and/or via cross-signaling with known genes controlling osteogenic differentiation of MSCs

STIMULATING EFFECT OF HIGH DOSE HEPARIN ON MIGRATION ACTIVITY AND MSC STEMNESS PRESERVATION IN THE PRESENCE OF BONE-SUBSTITUTING MATERIALS

Synthetic materials used in regenerative medicine, upon implantation, induce the development of an inflammatory reaction necessary for the effective regeneration of damaged bone tissue. Implant contact with tissues is accompanied by the deposition of blood proteins and interstitial fluid on its surface, contributing to the activation of the complement system, components of innate immunity, initiating coagulation hemostasis, leading to the formation of a fibrin clot. An extracellular matrix based on fibrin, collagen and elastin forms on the implant’s surface, which provides the basis for the formation of tissue structure through the adhesion of stem cells to the forming bone callus before the formation of bone regenerate. To prevent the development of postoperative pathological conditions caused by hypercoagulable syndrome, therapeutic strategies are used to use anticoagulants (heparin, warfarin). However, their use limits the normal formation of a fibrin clot in vivo. This can slow down the migration of mesenchymal stem cells (MSC) and disrupt the formation of callus, inhibiting the processes of osseointegration of the implant and bone healing. The study’s goal was to study the effect of heparin in a gradient of low and high concentrations on the migration activity and stem capacity of human MSCs under in vitro cultivation conditions. According to the results of flow cytometry, it was revealed that high concentrations of heparin (130, 260 IU/ml) in a 2D cultivation model contribute to an increase in the number of cells expressing surface markers CD73 and CD90, which indicates that MSCs retain high clonogenic potential. A 3D model of in vitro cultivation with the addition of heparin and osteosubstituting implants bearing a CF coating with a roughness index of Ra = 2.6-4.9 μm contributed to preserving the “stemness” character of MSCs through the expression of surface markers CD73 and CD90. According to the results obtained using the xCELLigence system, heparin at a later time (from 20-40 hours) increases the invasion of MSCs through micropores that simulate the state of the blood vessel walls. However, in the presence of HAP nanoparticles that mimic the remodeling processes of the mineral bone matrix and/or resorption of bone cement, the effect of heparin was less pronounced. The results can be used in the field of regenerative medicine associated with the introduction of MSCs. The data can serve as a prerequisite for developing new therapeutic strategies for surgical patients with a high risk of postoperative thrombosis after osteosynthesis

Significance of nutrient media choice for the long-term cultures of leukemic T-lymphoblasts

Correct choice of nutrient media for culturing different types of cells in various applications is one of the most important aspects of modern biotechnology, since chemical composition of the culture media largely contains the necessary metabolites to support certain cells’ growth lines outside the body. Jurkat line of human leukemic T-lymphoblast-like cells (hereinafter Jurkat T-cells) is actively used for in vitro modeling of intracellular signaling and activation of normal blood T-lymphocytes mediated by the T-cell receptor/CD3/ CD4 complex in toxicological studies of immune and secretory responses, to test medicinal substances and ions. Also, Jurkat T-cells are widely used for ex vivo testing in immunology, oncology, toxicology, orthopedics, and traumatology. The existing standards and numerous studies are mainly based on short-term in vitro cultivation of Jurkat T-cells in RPMI 1640 nutrient medium. Meanwhile, the issues of long-term maintenance of the growth of Jurkat T-cells culture are poorly presented in the research literature. This study aimed for studying the activity of Jurkat T-cells over 7 to 14 days of in vitro culture and comparing the relative value of RPMI 1640 and αMEM media for the behavior of immunocompetent tumor cells. Using flow cytometry, multiplex analysis, and phase contrast Cell-IQ microscopy, the proportions of living cells and those dying by apoptosis and necrosis, secretion of cytokines and chemokines, and the dynamics of cell biomass propagation were studied. It was found that the αMEM medium in the complete nutrient medium, as compared with RPMI 1640, is more appropriate to in vitro promotion of cell viability (increased proportion of viable cells by 13.5% at the day 14), their secretory ability for 23 из 27 tested biomolecules, shortened adaptation time (на 32%) in culture before growth initiation, 5-fold increase of the Jurkat Т-cell cellularity by the day 7. Potential significance of the chemical components of nutrient media and secreted biomolecules for these results is discussed. As based on the results obtained, we concluded on superior properties of αMEM medium for long-term in vitro cultures of Jurkat T-cells. Consequently, the in vitro testing of medical devices intended for long-term contact with the body, including those for cancer patients, using Jurkat T-cell leukemia line in RPMI 1640 medium, may lead to wrong predictions on their biocompatibility and potential antitumor activity

Моделирование микроокружения мезенхимных стволовых клеток как перспективный подход к тканевой инженерии и регенеративной медицине (краткий обзор)

One of the promising areas is the design and modification of materials for control over the fate of multipotent mesenchymal stromal cells (MMSCs) that will allow stroma of various human and animal organs and tissues to be constructed. However, the discussion about the existence and functioning of microenvironment for the MMSCs is just beginning to develop. The design of artificial materials that are able to reproduce biomimetically the cellular and tissue microenvironment and based on ideas and main elements borrowed from wildlife is current direction in a development of medical materials technology and tissue bioengineering. Scaffold technology is a promising experimental approach to simulate the properties of natural microenvironment of stem cells. Our aim is a short review of key elements of MMSC microterritories, its advanced investigations and the attempts of modeling in application to tissue bioengineering and regenerative medicine.Одним из перспективных направлений являются разработка и модификация материалов для контроля жизнедеятельности мультипотентных мезенхимных стромальных клеток (ММСК), которые (ре)конструируют строму различных органов и тканей человека и животных. Тем не менее обсуждение вопроса о существовании и функционировании микроокружения ММСК только начинается. Это тормозит дальнейшее развитие клеточной биологии и тканевой инженерии. Дизайн искусственных материалов, способных к биомиметическому воспроизведению клеточного и тканевого микроокружения, основанный на идеях и элементах, заимствованных у природы, является современным направлением в развитии медицинского материаловедения и тканевой инженерии. Скеффолд-технологии – многообещающий экспериментальный подход к моделированию свойств природного микроокружения для стволовых клеток. Цель – краткий обзор ключевых элементов микротерриторий ММСК, его перспективных исследований и попыток моделирования в приложении к тканевой инженерии и регенеративной медицине.

Modeling of the mesenchymal stem cell microenvironment as a prospective approach to tissue bioengineering and regenerative medicine (a short review)

One of the promising areas is the design and modification of materials for control over the fate of multipotent mesenchymal stromal cells (MMSCs) that will allow stroma of various human and animal organs and tissues to be constructed. However, the discussion about the existence and functioning of microenvironment for the MMSCs is just beginning to develop. The design of artificial materials that are able to reproduce biomimetically the cellular and tissue microenvironment and based on ideas and main elements borrowed from wildlife is current direction in a development of medical materials technology and tissue bioengineering. Scaffold technology is a promising experimental approach to simulate the properties of natural microenvironment of stem cells. Our aim is a short review of key elements of MMSC microterritories, its advanced investigations and the attempts of modeling in application to tissue bioengineering and regenerative medicine

Prevalence and genetic diversity of Wolbachia endosymbiont and mtDNA in Palearctic populations of Drosophila melanogaster

Abstract Background Maternally inherited Wolbachia symbionts infect D. melanogaster populations worldwide. Infection rates vary greatly. Genetic diversity of Wolbachia in D. melanogaster can be subdivided into several closely related genotypes coinherited with certain mtDNA lineages. mtDNA haplotypes have the following global distribution pattern: mtDNA clade I is mostly found in North America, II and IV in Africa, III in Europe and Africa, V in Eurasia, VI is global but very rare, and VIII is found in Asia. The wMel Wolbachia genotype is predominant in D. melanogaster populations. However, according to the hypothesis of global Wolbachia replacement, the wMelCS genotype was predominant before the XX century when it was replaced by the wMel genotype. Here we analyse over 1500 fly isolates from the Palearctic region to evaluate the prevalence, genetic diversity and distribution pattrern of the Wolbachia symbiont, occurrence of mtDNA variants, and finally to discuss the Wolbachia genotype global replacement hypothesis. Results All studied Palearctic populations of D. melanogaster were infected with Wolbachia at a rate of 33–100%. We did not observe any significant correlation between infection rate and longitude or latitude. Five previously reported Wolbachia genotypes were found in Palearctic populations with a predominance of the wMel variant. The mtDNA haplotypes of the I_II_III clade and V clade were prevalent in Palearctic populations. To test the recent Wolbachia genotype replacement hypothesis, we examined three genomic regions of CS-like genotypes. Low genetic diversity was observed, only two haplotypes of the CS genotypes with a ‘CCG’ variant predominance were found. Conclusion The results of our survey of Wolbachia infection prevalence and genotype diversity in Palearctic D. melanogaster populations confirm previous studies. Wolbachia is ubiquitous in the Palearctic region. The wMel genotype is dominant with local occurrence of rare genotypes. Together with variants of the V mtDNA clade, the variants of the ‘III+’ clade are dominant in both infected and uninfected flies of Palearctic populations. Based on our data on Wolbachia and mtDNA in different years in some Palearctic localities, we can conclude that flies that survive the winter make the predominant symbiont contribution to the subsequent generation. A comprehensive overview of mtDNA and Wolbachia infection of D. melanogaster populations worldwide does not support the recent global Wolbachia genotype replacement hypothesis. However, we cannot exclude wMelCS genotype rate fluctuations in the past