G. T. Sukhikh

Differences in gene expression levels between early and later stages of human lung development are opposite to those between normal lung tissue and non-small lung cell carcinoma

We, for the first time, directly compared gene expression profiles in human non-small cell lung carcinomas (NSCLCs) and in human fetal lung development. Previously reported correlations of gene expression profiles between lung cancer and lung development, deduced from matching data on mouse development and human cancer, have brought important information, but suffered from different timing of mouse and human gene expression during fetal development and fundamental differences in tumorigenesis in mice and humans. We used the suppression subtractive hybridization technique to subtract cDNAs prepared from human fetal lung samples at weeks 10-12 and 22-24 and obtained a cDNA library enriched in the transcripts more abundant at the later stage. cDNAs sequencing and RT-PCR analysis of RNAs from human fetal and adult lungs revealed 12 differentially transcribed genes: ADH1B, AQP1, FOLR1, SLC34A2, CAV1, INMT, TXNIP, TPM4, ICAM-1, HLA-DRA, EFNA1 and HLA-E. Most of these genes were found up-regulated in mice and rats at later stages than in human lung development. In surgical samples of NSCLC, these genes were down-regulated as compared to surrounding normal tissues and normal lungs, thus demonstrating opposite expression profiles for the genes up-regulated during fetal lung development.

Umbilical cord blood mesenchymal stem cells

We studied umbilical cord blood mesenchymal stem cells and compared mesenchymal stem cells derived from umbilical cord blood, adipose tissue, and skin. Umbilical cord blood mesenchymal stem cells were characterized morphologically, cytofluorometrically, and by their differentiation potential. Umbilical cord blood mesenchymal stem cells did not differ from cells isolated from adipose tissue and skin by the main parameters (by morphology, expression of surface markers, and differentiation potential). A specific feature of umbilical cord blood mesenchymal stem cells is their low count per volume of the initial material and very low proliferative activity.

Identification of some human genes oppositely regulated during esophageal squamous cell carcinoma formation and human embryonic esophagus development.

Here we directly compared gene expression profiles in human esophageal squamous cell carcinomas and in human fetal esophagus development. We used the suppression subtractive hybridization technique to subtract cDNAs prepared from tumor and normal human esophageal samples. cDNA sequencing and reverse transcription polymerase chain reaction (RT-PCR) analysis of RNAs from human tumor and the normal esophagus revealed 10 differentially transcribed genes: CSTA, CRNN, CEACAM1, MAL, EMP1, ECRG2, and SPRR downregulated, and PLAUR, SFRP4, and secreted protein that is acidic and rich in cysteine upregulated in tumor tissue as compared with surrounding normal tissue. In turn, genes up- and downregulated in tumor tissue were down- and upregulated, respectively, during development from the fetal to adult esophagus. Thus, we demonstrated that, as reported for other tumors, gene transcriptional activation and/or suppression events in esophageal tumor progression were opposite to those observed during development from the fetal to adult esophagus. This tumor embryonization supports the idea that stem or progenitor cells are implicated in esophageal cancer emergence.

Mesenchymal stem cells.

Institute of Biological Medicine, Moscow The formation of the concept of a mesenchymal stem cell (MSC) is a priority of Russian biological science. A. Ya. Fridenshtein and his colleagues were the first who experimentally proved the existence of MSC. Osteogenic potential of fibroblastlike bone marrow cells of different mammalian species was demonstrated [25,26]. Fibroblast-like bone marrow cells often formed discrete adhesive colonies in vitro [27,28,47]. After heteroand orthotopic transplantation in vivo cloned cells from these colonies formed bone, cartilaginous, fibrous, and adipose tissues [48]. Intensive self-renewal and multipotency of fibroblast-like colony-forming cells from the bone marrow allowed Fridenshtein and Owen to formulate a concept of multipotent mesenchymal precursor cells (MPC) [62]. An ordered chain of finely regulated cell proliferation, migration, differentiation, and maturation processes underlies the formation of the majority of cell lineages in adult organisms. The earliest cell elements in this chain are stem cells (SC). Along with extensive self-renewal capacity, SC possess a great differentiation potential. Apart from well studied hemopoietic and intestinal SC, other SC classes were recently discovered in adult organism. Until recently it was considered that SC in adults can give rise to cell lines specific to tissues where these cells are located; however, new facts necessitated revision of this concept. Hemopoietic SC capable of differentiating into all cell elements of the blood, can also be a source of hepatic oval cells [65]; neural SC, precursors of neurons and glia [2,3], serve as the source of early and committed hemopoietic precursors [10]. MSC, a source of bone, cartilaginous, and adipose tissue cells, can differentiate into neural cells [46]. Tissue growth and reparation are associated with migration of uncommitted precursor cells from other tissues. During muscle tissue reparation mesenchymal SC migrate from the bone marrow into skeletal muscles [24]. Hence, in addition to capacity to unlimited division and reproduction of a wide spectrum of descendants of a certain differentiation line, adult SC are characterized by high plasticity. The existence of a rare type of somatic pluripotent SC, common precursors of all SC in an adult organism, is hypothesized [79]. Another important characteristic of SC is their migration from the tissue niche into circulation, which was experimentally proven for hemopoietic and MSC [69,73]. For activation of the differentiation program, circulating SC should get into an appropriate microenvironment [75,78]. A potent stimulus for investigation of SC is the possibility of their clinical use in cell and gene therapy. The bone marrow contains multipotent MSC, which can be easily isolated and cultured in vitro. It is therefore interesting to analyze some fundamental aspects of MSC biology and the possibilities of their clinical use. MSC descendants are involved in the formation of bones, cartilages, tendons, adipose and muscle tissues, and stroma maintaining the hemopoiesis [12,19,51]. The term MPC is used to denote MSC and their committed descendants capable of differentiating into at least two types of mature cells, which are present in the bone marrow and some mesenchymal tissues [16,19,57,82].

Experimental intravenous cell therapy of acute and chronic renal failure

The therapeutic effect of intravenous injection of human fetal bone marrow mesenchymal stem cells or summary culture of kidney cells were studied on models of chronic or acute renal failure in outbred albino rats. Both cell types promoted improvement and normalization of the renal function in rats with stable chronic renal insufficiency (2 weeks after kidney cell injection, 1 month after bone marrow mesenchymal stem cell injection). Renal function remained normal or subnormal during the delayed period (3–3.5 months after injection). In rats with latent stage of chronic renal insufficiency, exacerbation was induced by additional 40-min ischemia. All rats receiving intravenous injection of saline died. Improvement of the functional parameters started 2 weeks after injection of kidney cells or bone marrow mesenchymal stem cells, and normalization was observed after 1.1–5 months. During the delayed period (after 3–4 months), functional parameters retained at normal or subnormal levels. In experimental series III, all rats with acute renal failure intravenously injected with saline (control) died from uremia on days 2–4. After injection of kidney cells 50% rats survived and renal function in these animals returned to normal after 2 weeks. After injection of bone marrow mesenchymal stem cells 83% rats survived, functional parameters returned to normal after 3 weeks.

Morphofunctional Study of the Therapeutic Efficacy of Human Mesenchymal and Neural Stem Cells in Rats with Diffuse Brain Injury

We studied the effect of transplantation of human stem cells from various tissues on reparative processes in the brain of rats with closed craniocerebral injury. Combined treatment with standard drugs and systemic administration of xenogeneic stem cells had a neuroprotective effect. The morphology of neurons rapidly returned to normal after administration of fetal neural stem cells. Fetal mesenchymal stem cells produced a prolonged effect on proliferative activity of progenitor cells in the subventricular zone of neurogenesis. Adult mesenchymal stem cells had a strong effect on recovery of the vascular bed in ischemic regions.

Effect of Cell Therapy on Recovery of Cognitive Functions in Rats during the Delayed Period after Brain Injury

We studied the effect of systemic transplantation of human stem cells from various tissues on cognitive functions of the brain in rats during the delayed period after experimental brain injury. Stem cells were shown to increase the efficacy of medical treatment with metabolic and symptomatic drugs for recovery of cognitive functions. They accelerated the formation of the conditioned defense response. Fetal neural stem cells had a stronger effect on some parameters of cognitive function 2 months after brain injury. The efficacy of bone marrow mesenchymal stem cells from adult humans or fetuses was higher 3 months after brain injury.

Correlation between the content of albumin and carotenoids in human vitreous body during prenatal development

The dynamics of the content albumin and carotenoids in human fetal vitreous body during weeks 16–31 of gestation was studied. The maximum values of total albumin (1.42 mg) and carotenoids (276 ng) during the studied period were recorded on weeks 20–22. Albumin concentration peaked during week 17 (2.11×10−4 mol/liter) and carotenoids during weeks 16–17 (about 0.045×10−4 mol/liter) of prenatal development. By week 31, the concentrations and total content of albumin and carotenoids in the vitreous body decreased. The physiological role of the studied components of the vitreous body for prenatal development of human eye is discussed.

Application potential of human fetal stem/progenitor cells in cell therapy.

We analyzed the possibility of using fetal stem and progenitor cells for the treatment of various pathologies. A comparative characteristic of stem cells from fetuses and adult donors is presented and advantages of the use of fetal biometerial for biotransplantation are described. The main tissue sources of fetal stem cells are characterized and experimental and clinical data on the use of fetal cells for cytotherapy are presented.

Lutein and its oxidized forms in eye structures throughout prenatal human development

&NA; The presence of carotenoids in the vitreous body, retina, lens, retinal pigment epithelium together with choroid (hereinafter RPE), and ciliary body and iris together with choroidal stroma (hereinafter CBI) was studied throughout the second trimester of prenatal development of the human eye. It has been found that the vitreous body, retina, and RPE contain lutein and its oxidized forms. Zeaxanthin was not found in the tissues studied. The presence of lutein in the vitreous body is transient and no longer detected after 28 weeks of gestation. Lutein was not detected in the lens and CBI, but its oxidized forms were found. The presence of carotenoids in different tissues of the eye in the course of normal eye development and the antioxidant role of carotenoids are discussed. Graphical abstract HPLC of chloroform extracts from different tissues of human fetal eyes. Figure. No caption avaialble. HighlightsUV spectroscopy, HPLC, and mass spectrometry were used to find carotenoids in eyes.Lutein content was measured in different tissues of human fetal eyes.Lutein oxidized forms were shown to be also present in all fetal eye tissues studied.