Colony-forming activity of bone marrow cells in 3- and 12-month-old Wistar rats does not differ by the number of early and erythroid precursors and by the formation of granulocyte-macrophage colonies. In senescence-accelerated OXYS rats, the number of early and erythroid precursors significantly increases by the age of 12 months and surpasses the corresponding values in Wistar rats. The number of granulocyte-macrophage colonies in OXYS rats does not change with age, but the numbers of these colonies formed at the age of 3 and 12 months in these animals are higher than in Wistar rats. As a result, the total number of hemopoietic colonies in 12-month-old OXYS rats 2-fold surpassed that in 12-month-old Wistar rats. Activation of granulopoiesis and increased numbers of early and erythroid precursors indicate deep changes in the functional status of the hemopoietic stem cell in 1-year-old OXYS rats in the direction characteristic of aging animals.

We developed a technology of labeling bone marrow precursor cells with the Lin-c-kit+ phenotype in culture by green fluorescent protein gene using a lentivirus vector. The proposed system provides effective transduction of bone marrow precursor cells and high transgene expression level in vitro (27%). The integration of the transgene into the transduced cell genome in vivo was verified by the method of splenic colonies.

The presence of strongly pronounced metabolic dependence of cooling-induced action potentials (APs) in excitable cells of pumpkin stem was shown using NaN3, DCCD, and IAA. This dependence might be connected with participation of the plasma-membrane ATP-dependent pump in the excitation process. The decrease of extracellular Ca2+ concentration had as strong depressive effect on the AP as that of the inhibition of metabolism. It has been supposed that the calcium signal is important coupling factor between the AP generation and the metabolism of excitable cells.

The investigation of antigenic diversion of tumor cells resulting from the expression of heteroorganic antigens has been continued. Tumor-associated heteroorganic antigens with mol. weight 200-210 kDa (identified before as laminin), 105-130, 75-80 and 43 kDa were detected by anti-kidney serum in fractions of plasmatic membranes of cells of rat ascitic Zajdela hepatoma and cultured HTC hepatoma; the antigen 43 kDa was isolated on immunosorbent and identified by mass spectrometry as beta-actin. Anti-kidney serum revealed laminin in fractions of plasmatic membranes of cultured L8 and L6J1 myoblasts, and L6J1 myotubes; apparently, synthesis of laminin by hepatoma and myogenic cells is not connected with their proliferative activity. Besides, anti-kidney serum detected components 38, 42, 44, 48, 62, 78 and 120 kDa, expression of which on myogenic cells surface might be consequence of active cell proliferation and (or) differentiation.

Asymmetric cell division observed in many groups of organisms has similar mechanisms suggesting conservatism of the process. Asymmetric division of stem cells that reside in their niches is aimed to regulation of cell proliferation and genome stability maintenance. But stem cells may also divide symmetrically depending on situation. Alteration of mechanisms of asymmetric division might be one of the factors of neoplasm growth.

Study of dynamic morphological changes if the brain after ischemic stroke is an important phase of pre-clinical trial of mesenchymal stem cell (MSC) therapy for this widespread disease. Experoments were carried out in inbred Wistar-Kyoto rats. MSCs were isolated, expanded in culture and labeled with vital fluorescent dye PKH26. Animals were subjected to middle cerebral artery occlusion (MCAO) followed by injection of 5 x 10(6) rat MSCs into the tail vein on the day of MCAO. Control group of animals received PBS injection (negative control). Animals were sacrificed in 1, 2, 3 and 5 days and in 1, 2, 4 and 6 weeks after operation. MSCs were revealed in the brain on the third day transplantation. They distributed around brain vessels in both the ipsilateral and contralateral hemispheres. This pattern of distribution remained unchanged during 6 weeks of observation. It was demonstrated that inflammation process and scar formation in the experimental group progressed 25-30 % faster than in the control group. MSC transplantation stimulated endogenous stem cell proliferation on the subependimal zone of lateral ventricles (subventrecular zone). What is more, MSC injection showed neuroprotective effect: almost all penumbra neurons in animals treated with cell therapy retained their normal structure, whereas in animals of control group penumbra neurons died or had signs of serious damage.

The report deals with the ability of embryonic cells harvested from the nervous, hematopoietic and epithelial-muscular human tissues to form spheres during in vitro culturing. Judging from their own data and those reported elsewhere, the authors have hypothesized that formation of spherical colonies in vitro is a common feature of stem cells of various origin and varying degree of maturation. Probably, the formation of spheres provides for development of stem cells according to the locations and their inner temporal programs, which are specific and particular for every type of cells.

Morphological analysis of flowers was carried out in Paeonia cultivars. Some unusual alternations of floral organs were described: sepal-(petal-stamen) x N-carpel, where 2 < or = n < or = 4 (appearance of an additional zone of petal and stamen formation in the medial flower part). The identity of floral organs was not affected in the flowers with this unusual alternation. It was shown on the basis of mathematical simulation of the genes responsible for flower development that these alternations may be determined by increased pool of stem cells, which may lead to delayed termination of flower development.

In higher plants, homeobox genes of the KNOX and WOX subfamilies plays a key role in maintenance of the pool of stem cells, regulate proliferation, and prevent cell differentiation. It has been shown that meristem-specific genes are regulated by phytohormones and affect their metabolism, specifically that of cytokinins. Plant tumors are widely used as a model for studying the genetic control of cell division and differentiation. The tumors induced by pathogens and genetic tumors, whose development depends on the plant genotype, are distinguished. The changes in the levels of expression of genes--regulators of cell cycle, meristem-specific genes, and genes controlling metabolism and transmission of the signal of phytohormones were described on tumors of different origin. The mechanisms underlying tumor formation in plants and animals were shown to be similar, specifically as concerns the relationship between the genes--cell cycle regulators and tumorigenesis. In plants, transcriptional factors of the subfamily KNOX have similarity in structure and, supposedly, common origin with transcriptional factors MEIS in animals, which are very active in neoplastic cells. The review presents the characteristics of KNOX and WOX transcriptional factors, their functions in meristem development, and interaction with the plant hormonal system. The role of homeodomain-containing transcriptional factors in tumorigenesis in plants and animals is discussed. The role of meristem-specific genes and phytohormones in tumorigenesis is discussed on the example of genetic tumors obtained by mutagenesis in Arabidopsis thaliana and tumors in the radish inbred lines.

Plant cells are capable of reversible transition from the proliferating to the stem state. This transition is determined by a system of cell-cell interactions and interrelationships between plant parts. Stem cells defined as the cells preserving the capacity to divisions and differentiation for a long time arise repeatedly during development of the root and shoot primordial, rather than are clones of a population of stem cells laid down at a certain stage of embryogenesis. The quiescent center cells, rather than the surrounding actively dividing cells, best correspond to the characteristics of stem cells according to Loeffler and Potten. The factors that determine the quiescent center formation and maintenance in the root have been analyzed. The available data suggest that among these factors, indoleacetic acid transport and cap influence are of paramount significance. The cap formation precedes the quiescent center formation both during the root development and in the course of meristem regeneration after the root decapitation. The capacity of tem cell formation by the meristem suggests that not only meristem arises from the stem cells, but also that stem cells are formed from actively dividing cells. Repeated formation of stem cells allows long-term preservation of the capacity of plants for open morphogenesis and vegetative propagation.

Digital microfocal x-ray study was experimentally studied in animals to examine the time course of changes in their bone regeneration. Sixteen Chinchila rabbits whose bone defect in the angle of the mandibular ramus had been closed with the osteoplastic material Gapcol with the applied allogeneic, autologous stem cells isolated from rabbit adipose tissue and human plasma enriched with thrombocytic growth factors were examined. The capabilities of digital microfocal x-ray study versus x-ray computed tomography were compared in the evaluation of reparative regeneration of bone tissue. The results of radiation studies were verified with the data of scanning electron microscopy.

Motor dysfunctions in Parkinson's disease are believed to be primarily due to the degeneration of dopaminergic neurons located in the substantia nigra pars compacta. Numerous cell replacement therapy approaches have been developed and tested, including these based on donor cell transplantation (embryonic and adult tissue-derived), adult mesenchymal stem cells (hMSCs)-, neural stem cells (hNSCs)--and finally human embryonic stem cells (hESCs)-based. Despite the progress achieved, numerous difficulties prevent wider practical application of stem cell-based therapy approaches for the treatment of Parkinson's disease. Among the latter, ethical, safety and technical issues stand out. Current series of reviews (Cell therapy for Parkinson's disease: I. Embryonic and adult donor tissue-based applications; II. Adult stem cell-based applications; III. Neonatal, fetal and embryonic stem cell-based applications; IV. Risks and future trends) aims providing a balanced and updated view on various issues associated with cell types (including stem cells) in regards to their potential in the treatment of Parkinson's disease. Essential features of the individual cell subtypes, principles of available cell handling protocols, transplantation, and safety issues are discussed extensively.

The article is dedicated to analysis of centrosomal hypothesis of cellular aging in the light of new data concerning existence of centrosomal RNA, and also in the light of the role of maternal and daughter centrosomes in processes of asymmetric division of stem cells. It is supposed that these data confirm the central role of centrosomes in aging and cellular differentiation. Additional arguments concerning conceptual consistency of telomeric and centrosomal hypothesis of cellular aging are presented.

Most, if not all epithelial tissues contain stem/progenitor cells and niche, where the cells are kept on deposit. These cells are responsible for normal tissue renewal or the regeneration following damage. The age-increased incidence of epithelial cancer (above 90% among other tumors) has been associated with age-reduced stability to injury in epithelium and its decline in regeneration capacity. What makes the epithelial tissues susceptible to cancer transformation under aging? The goal of this review is to check the hypothesis that injury-induced changes in aging epithelium create opportunities for chronic (not acute) inflammatory response, which support pro-cancer microenvironment conditions similar to cancer microenvironment. Both this microenvironments is able to stimulate the homing and division of stem/progenitor cells but not their differentiation. These local changes together with age-reduced immunity, could contribute to the pathogenesis of age-specific cancer.

Paclitaxel (single intravenous injection in a maximum tolerated dose of 4.6 mg/kg) to white outbred rats causes bone marrow hypoplasia, increased granulocyte and erythroid cell mitosis (metaphase-anaphase transition), and moderate pancytopenia developments in peripheral blood (hypoplastic anemia, deep, short-term neutropenia, lymphopenia and thrombocytopenia) in the first hours after injection. A considerable increase of polyploidy (4n) cells and a moderate increase in the structural changes (chromatid deletions) of chromosomes was observed on bone marrow metaphase plates in 24 h. The drug introduction causes earlier increase in the rate of thymus cells mitosis, a growth in the number of thymocytes with apoptosis signs, and a moderate decrease in the thymus and spleen weight. All changes are reversible. Long-term (90 days after injection) observation revealed decreased lymphocyte count in the peripheral blood and bone marrow and earlier thymus involution.

GIST are stromal tumors and the gastrointestinal tract (GIT) and some other organs of spindle-cell or epithelioid-cell structure expressing CD117 (C-kit, KIT), as well as those at different rates and in different combinations, CD34, smooth muscle and/or neurogenic differentiation antigens. It should be taken into account that CD117 are also expressed by melanomas, vascular, and some other tumors. The c-kit gene mutations leading to the expression and autoactivation of the tyrosine kinase receptor KIT underlie the oncogenesis of GIST, which results in enhanced proliferative activity and inhibited apoptosis. This is supported by successful chemotherapy for GIST with a KIT receptor inhibitor. The histogenesis of GIST is associated with GIT somatic stem, the Cajal cell precursors. Many GISTs behave like sarcomas and they are characterized by an infiltrating growth, hematogenic (mainly into the liver) and implantational (along the peritoneum) cancer spread. There are opinions that all such neoplasms are potentially malignany and small-sized GISTs are benign and have the minimum mitotic activity.

The data available in the literature data on the role of neoangiogenesis and extracellular matrix factors in the pathogenesis of acute and chronic leukemias and lymphoproliferative diseases are presented. Hematopoiesis and endothelial cells have a common pluripotential progenitor. Angiogenic and fibroblast growth factors are involved chronic leukemia. The phenotype of lymphoid cells determines the type of the cellular and extracellular factors.

Ph+, bcr/abl+ cells arise due to t(9,22) chromosome translocation and Ph+ chromosome formation in hematopoietic stem cells. The cells show appreciable apoptosis suppression but retain their ability to differentiate and maturate. Ph chromosome, bcr/abl oncogene and Ph+, bcr/abl+ cells themselves are the hallmark of chronic myeloid leukemia. Under leukemia progression differentiating Ph+, bcr/abl+ cells transform into leukemic malignant cells with differentiation block. It is assumed to be a result of subsequent mutations or activation of proliferation of long silent Ph+ cells arisen previously in the stem cells because of the translocation. Real mechanism underlying the cell transformation remains unknown. This work was performed to develop a proper cell model allowing us to study functioning of differentiating Ph+, bcr/abl+ cells and their real transformation into malignant cells with block of differentiation. For this purpose we have investigated kinetics of Ph+, bcr/abl+ cells proliferation, differentiation, cell death and transcription of antiapoptotic genes in cultured 14-day of Ph+ mononuclear cells isolated from peripheral blood of a patient in chronic phase of chronic myeloid leukemia before treatment. The results obtained revealed that Ph+ cell differentiation proceeded in accord with characteristic scheme of chronic myeloid leukemia in vivo. Myeloid cells of hematopoietic cell lineage amounted to 3/4 of live Ph+ mononuclear cells undergoing accumulation and subsequent consumption in the course of differentiation. 95% myeloid cells were differentiating Ph+ granulocytes. The most deal of differentiating Ph+ cells was myelocytes. The rate ratio of myelocyte accumulation to its subsequent consumption showed that the rate of transformation into metamyelocytes was significantly decreased at this differentiation stage. Ph+ cells cultivation curves characterized cell death at different differentiation stages. There were observed the cell death of proliferating Ph+ cells and Ph+ myelocytes, and intensive death of mature cells as well. P/D index, that is ratio of immature Ph+ granulocytes differentiated by cell dividing (blasts, promyelocytes and myelocytes) to the cells differentiated without dividing (metamyelocytes and mature neutrofiles), revealed active of proliferation at the beginning of cultivation and unexpected new proliferative activity at the end of cultivation in the presence of growth factor. The peaks of antiapoptotic bcr/abl gene transcription activity coincided with the observed active proliferation at the beginning and at the end of cultivation. Cell proliferation, differentiation and apoptosis were noticeably accelerated by growth factor treatment. Thus, the study of the Ph+ cells cultivation kinetics is rather informative approach to investigation of continuous regulation of cellular and molecular processes in vitro in the case of chronic myeloid leukemia and allows more complete consideration of Ph+, bcr/abl+ cells hematopoiesis.