Stanislav Filip

Signaling involved in hair follicle morphogenesis and development.

Hair follicle morphogenesis depends on Wnt, Shh, Notch, BMP and other signaling pathways interplay between epithelial and mesenchymal cells. The Wnt pathway plays an essential role during hair follicle induction, Shh is involved in morphogenesis and late stage differentiation, Notch signaling determines stem cell fate while BMP is involved in cellular differentiation. The Wnt pathway is considered to be the master regulator during hair follicle morphogenesis. Wnt signaling proceeds through EDA/EDAR/NF-κB signaling. NF-κB regulates the Wnt pathway and acts as a signal mediator by upregulating the expression of Shh ligand. Signal crosstalk between epithelial and mesenchymal cells takes place mainly through primary cilia. Primary cilia formation is initiated with epithelial laminin-511 interaction with dermal β-1 integrin, which also upregulates expression of downstream effectors of Shh pathway in dermal lineage. PDGF signal transduction essential for crosstalk is mediated through epithelial PDGF-A and PDGFRα expressed on the primary cilia. Dermal Shh and PDGF signaling up-regulates dermal noggin expression; noggin is a potent inhibitor of BMP signaling which helps in counteracting BMP mediated β-catenin inhibition. This interplay of signaling between the epithelial and dermal lineage helps in epithelial Shh signal amplification. The dermal Wnt pathway helps in upregulation of epithelial Notch expression. Dysregulation of these pathways leads to certain abnormalities and in some cases even tumor outgrowth.

Gamma radiation induces senescence in human adult mesenchymal stem cells from bone marrow and periodontal ligaments.

Purpose: Mesenchymal stem cells isolated from bone marrow (BM-MSC) and periodontal ligament (PLSC) are cells with high proliferative potential and ability to self-renewal. Characterization of these cells under genotoxic stress conditions contributes to the assessment of their prospective usage. The aim of our study was to evaluate changes in BM-MSC and PLSC caused by ionizing radiation. Methods: Human BM-MSC and PLSC were irradiated with the doses up to 20 Gy by Co60 and observed 13 days; viability, proliferation, apoptosis and senescence induction, and changes in expression and phosphorylation status of related proteins were studied. Results: Irradiation with the doses up to 20 Gy significantly reduces proliferation, but has no significant effect on cell viability. The activation of tumor suppressor protein 53 (p53) and its phosphorylations on serines 15 and 392 were detected from the first day after irradiation by 20 Gy and remained elevated to day 13. Expression of cyclin-dependent kinases inhibitor 1A (p21Cip1/Waf1) increased. The cell cycle was arrested in G2 phase. Instead of apoptosis we have detected hallmarks of stress-induced premature senescence: increase in cyclin-dependent kinases inhibitor 2A (p16INK4a) and increased activity of senescence-associated β-galactosidase. Conclusion: Mesenchymal stem cells isolated from bone marrow and periodontal ligament respond to ionizing radiation by induction of stress-induced premature senescence without apparent differences in their radiation response.

Issues in stem cell plasticity

Experimental biology and medicine work with stem cells more than twenty years. The method discovered for in vitro culture of human embryonal stem cells acquired at abortions or from„surplus” embryos left from in vitro fertilization, evoked immediately ideas on the posibility to aim development and differentiation of these cells at regeneration of damaged tissues. Recently, several surprising observations proved that even tissue‐specific (multipotent) stem cells are capable, under suitable conditions of producing a while spectrum of cell types, regardless, whether these tissues are derived from the same germ layer or not. This ability is frequently called stem cell plasticity but other authors also use different names ‐„non‐orthodox differentiation” or„transdifferentiation”. In this paper we wish to raise several important questions and problems related to this theme. Let us remind some of them: Is it possible to force cells of one‐type tissue to lool and act as cells of another tissue? Are these changes netural? Could these trans‐formations be used to treat diseases? What about the bioethic issue? However, the most serious task “still remains to be soloved ‐ how to detect, harvestand culture stem cells for therapy of certain diseases”.

Irradiation of Adult Human Dental Pulp Stem Cells Provokes Activation of p53, Cell Cycle Arrest, and Senescence but Not Apoptosis

Adult human dental pulp contains stem cells (DPSCs) that are capable of differentiation into osteoblasts, odontoblasts, adipocytes, and neuronal-like cells. Because these cells have potential use in tissue regeneration, herein we characterized the response of DPSC lines to ionizing radiation (IR). These DPSC lines have been developed from the extracted molars of healthy donors. DPSCs were cultivated in a unique media supplemented with epidermal growth factor (EGF) and platelet-derived growth factor (PDGF). Since tissue homeostasis depends on a precise balance among cell proliferation, senescence, and cell death, we explored the effects of IR (2-20 Gy) on the proliferative activity of DPSCs and the molecular pathways involved. Even the highest dose used (20 Gy) did not induce DPSC apoptosis. After irradiation with doses of 6 and 20 Gy, DPSCs accumulated in the G2 phase of the cell cycle. DPSCs responded to IR (20 Gy) with senescence detected as SA-β-galactosidase positivity, beginning on the third day after irradiation. Twenty-four hours after irradiation, p53 and its serine 15 and 392 phosphorylated forms were detected. At this time, p21 (WAF1) was induced. Increases in protein p16 were observed from the third day following irradiation and continued till the end of the examination (Day 13). We conclude that DPSCs respond to IR-induced damage by permanent cell cycle arrest in the G2 phase and by stress-induced premature senescence.

Expression of intermediate filament nestin in blood vessels of neural and non-neural tissues.

Our previous findings performed in rat tissues demonstrated that intermediate filament nestin is expressed in endothelial cells of newly formed blood vessels of developing organs and neural transplants. The aim of the present study was to identify other cellular markers expressed in nestin-positive (nestin+) blood vessels. To reach this goal we performed double immunofluorescent study to co-localize nestin with endothelium-specific markers (CD31, CD34 II, vimentin) or markers of perivascular cells (GFAP, SMA) in paraffin-embedded sections of normal human brain tissue, low- and high-grade gliomas, postinfarcted heart and samples of non-neural tumours. Our findings documented that all the samples examined contained blood vessels with different ratio of nestin+ endothelial cells. Double immunostaining provided unambiguous evidence that endothelial cells expressed nestin and allowed them to distinguish from other nestin+ elements (perivascular astrocytic endfeet, undifferentiated tumour cells, smooth muscle cells and pericytes). Nestin+ endothelium was not confined only to newly formed capillaries but was also observed in blood vessels of larger calibres, frequently in arterioles and venules. We conclude that nestin represents a reliable vascular marker that is expressed in endothelial cells. Elevation of nestin expression likely corresponds to reorganization of intermediate filament network in the cytoskeleton of endothelial cells in the course of their maturation or adaptation to changes in growing tissues.

Weekly Paclitaxel Combined with Local Hyperthermia in the Therapy of Breast Cancer Locally Recurrent after Mastectomy – a Pilot Experience

Background: The combination of chemotherapy and hyperthermia (HT) is a promising approach in the treatment of malignant tumors. In the present report we evaluate the efficacy and toxicity of a combination of weekly paclitaxel combined with local hyperthermia in breast cancer. Patients and Methods: 7 patients were treated for inoperable local recurrence of breast cancer after mastectomy, irradiation, and chemotherapy or hormonal therapy. They weekly received paclitaxel (60–80 mg/m²) in 3-h infusions followed by local HT 41–44 °C for 45 min for 6–18 cycles. Results: Objective local response was observed in all treated patients (complete response in 4 patients and partial response in 3 patients). There were no grade 3 or 4 toxicities, neurologic toxicity or hypersensitivity reactions. Local tolerance to this regimen was also good, with only 4 patients developing mild transient erythema. Conclusion: Our experience indicates that the combination of weekly paclitaxel and HT may be effective in the treatment of locally recurrent breast cancer after mastectomy.

Breast cancer and cancer stem cells: a mini-review.

Breast cancer is the most common type of malignant disease in women worldwide. In developing countries the past few years have sustained an increasing incidence of this type of cancer. Currently, breast cancer is the second leading cause of death due to cancer in women. In 2008 alone it was diagnosed in more than 1 million patients and each year the number of breast cancer-related deaths is estimated to be ~450,000. The mortality rate in breast cancer patients has been decreasing over the years thanks to the development of early diagnostic methods and more effective treatments. But despite the new advances in cancer diagnosis and treatment, the risk of recurrence and metastasis is ever present. It has been theorized that cancer stem cells are involved in the process of tumor growth and metastases. Due to their self-renewing and differentiation capabilities, they are now considered the underlying factor in tumor recurrence and the main reason for therapy resistance. Therefore, the characterization of cancer stem cells may contribute to the development of more effective treatment strategies that should make it possible to eliminate cancer stem cells in order to prevent tumor relapse and metastasis in diagnosed patients.

Safety and Tolerability of Long Lasting LDL-apheresis in Familial Hyperlipoproteinemia

Abstract:  The aim of this work is to arbitrate the incidence of side effects and tolerability of long lasting LDL‐apheresis in familial hyperlipoproteinemia. 1200 procedures were performed and the last 463 of them were evaluated. An immunoadsorption method of LDL‐apheresis was used (continuous blood cell separator Cobe Spectra; secondary device: automated adsorption‐desorption ADA, Medicap; absorption columns: Lipopak). As a whole, 6.26% adverse events were found and subsequently resolved by standard symptomatic therapy. Vaso‐vagal reactions (symptoms of neurovegetative lability) were the most common adverse effects, presented as malaise, weakness, slight and short‐term drop in blood pressure or other general signs. They were all well controlled by symptomatic therapy. We conclude that LDL‐apheresis in the hands of experienced personnel is a safe procedure. An acceptable procedure duration limit, balancing the possibility to achieve a targeted cholesterol level while still maintaining an acceptable patient tolerance, was confirmed to be 4 hours.

Local Environmental Factors Determine Hematopoietic Differentiation of Neural Stem Cells

Stem cells exhibit unique properties and hold high therapeutic promise, but factors influencing their differentiation after transplantation need to be recognized and defined for this promise to be fully met. Here, we demonstrate that endogenous colony-forming unit spleen (CFU-S) colonies are not generated in lethally irradiated mice transplanted with neural stem cells obtained from brain tissue of syngeneic donors. We investigated the proportion of transplanted neural stem cells that contributed to hematopoietic reconstitution and compared the distribution of transplanted cells in nonsplenectomized to that of splenectomized mice following sublethal whole-body irradiation. We also used clonogenic assays, colony assays, and histochemical analyses to explore conditions under which transplanted, beta-galactosidase-tagged neural stem cells underwent hematopoietic differentiation. Our results suggest that neural stem cells do undergo extramedullary hematopoiesis, even while no endogenous hematopoietic colonies develop in the spleen. Furthermore, we found that neural stem cells effectively colonized the bone marrow of splectomized recipients. We conclude that the hematopoietic differentiation of neural stem cells is highly dependent on the extramedullary environment. We also conclude that the bone marrow does not provide an environment supportive of hematopoietic differentiation by neural stem cells.

Phenotypic and morphological characterization of in vitro oligodendrogliogenesis.

The neurosphere assay has been used to maintain neural progenitor cells (NPCs) in the undifferentiated state. These cells are multipotent and gave rise to neurons and glial cells. Here we show that within 10 days of culture, neurospheres contained precursors and differentiated progeny of all three major central nervous system (CNS) cell lineages and these occupied distinct zones. The microenvironment of the inner zone supported cell differentiation. Cells of oligodendroglial lineage generated within the neurosphere were frequently observed. Of these cells, A2B5(+) cells were homogeneously distributed in the neurospheres, NG2(+) cells preferentially occupied the outer zone and O4(+) cells were localized at the inner zone of 10 day-old neurospheres. We prevented a massive cell death of dissociated neurosphere cells seen after differentiation triggered with adhesion and fetal calf serum by adding epidermal growth factor and basic fibroblast growth factor to the culture medium. Under these conditions, less than one third of cells did not express cell specific markers, glial fibrillary acidic protein-positive astroglia represented 43.4%, NG2(+) and/or O4(+) oligodendroglia represented 24.3%, and betaIII-tubulin(+) neurons 3.1% of cells recovered after neurosphere differentiation. We present evidence that oligodendroglial cells differentiate in a stepwise process as a result of their distribution in subsets that represent distinct developmental stages according to antigenic and morphological criteria. These include oligodendrocyte progenitors, preoligodendrocytes, and oligodendrocytes. The highly complex morphology of mature oligodendrocytes was compatible with functional cells.