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The RAF family of protein kinases consists of three members, A-RAF, B-RAF and C-RAF. Unlike the other isotypes, B-RAF has been found to have an important function for normal development of the central nervous system (CNS), because newly generated embryonic neurons lacking B-RAF cannot respond to survival factors and undergo cell death in vitro. A second cell lineage affected by the absence of B-RAF are endothelial cells and their death leads to internal bleedings and lethality of B-RAF-/- mice between embryonic day 10.5 (E10.5) and E12.5 precluding an opportunity to further analyze neural B-RAF function at a later stage. In contrast to B-RAF-/- mice, B-RAFKIN/KIN mice, which are B-RAF deficient but express a chimeric protein consisting of the unique N terminus of B-RAF and all the domains of A-RAF in the B-RAF gene locus, survive after midgestation because their endothelial cells are protected from apoptosis. More importantly, overall prevention of abnormal neural apoptosis in the forebrain allows us to study proliferation- or differentiation-oriented function of B-RAF other than its survival effects in CNS development. The detailed investigation of B-RAFKIN/KIN animals was concentrated on cortical development. There were apparent cortical defects in B-RAFKIN/KIN forebrain: Loss of B-RAF led to severe reduction of Brn-2 expressing pyramidal projection neurons accompanied by a disruption of dendrite formation in the upper layers. In further analysis, BrdU labelling experiments showed that from E14.5 to E16.5 cell proliferation in the ventricular zone of the mutant mice was reduced and that the late-born cortical neurons failed to migrate properly. While the proliferation defect of cortical progenitors was associated with reduced ERK activation, the mechanism causing impaired neuronal migration remains to be determined. Our hypothesis is that the subcellular localization of phospho-ERK may be altered in migrating cortical neurons in B-RAFKIN/KIN mice. To confirm in vivo function of B-RAF and further study unknown roles in embryonic neurogenesis as well as other morphogenesis, conditional B-RAF knockouts would be the ideal models, which can efficiently avoid embryonic lethality, prevent unwanted pleiotropic side effects and exclude accumulative compensatory developmental changes from the earliest developmental stage on, through the deletion of genetic material/gene function in selected cells at a specific time. The use of site-specific recombinases such as Cre and the successful development of the reversible tetracycline-based switch have provided powerful venues for creating conditional loss-of-function mouse models. Generation of tetracycline-regulated B-RAF and floxed B-RAF mouse embryonic stem (ES) cell lines was performed. Up to now, high-grade chimeric mice were obtained after blastocyst injection of the modified ES cell clones. The germline transmission from these chimeric mice is currently under investigation. When either of conditional mouse lines is ready, detailed examination in their CNS development would be done to reveal how B-RAF plays a real role for normal development of the nervous system.
Cellular proliferation, differentiation and survival in response to extracellular signals are controlled by the signal transduction pathway of Ras, Raf and MAP kinase. The Raf proteins are serine/threonine kinases with essential function in growth/differentiation/survival - related signal transduction events. In mammals, three functional (A-, B-, and C-Raf) genes were described. Biochemical studies suggest overlapping and differential utilization of Raf isozymes. However, the frequent co-expression of Raf isozymes and their multiple activators and effectors impedes the full understanding of their specific roles. The elucidation of these roles is important due to the involvement of the Ras/Raf/MEK/MAP kinase cascade in human disorders especially in tumor development and progression. B-Raf was shown to posses the strongest kinase activity among Raf kinases and display antiapoptotic properties. Mice deficient in B-Raf show overall growth retardation and die between E10.5 and E12.5 of vascular defects caused by excessive death of differentiated endothelial cells. To elucidate the redundancy of Raf isozymes during embryonic development and to rescue B-Raf-/- (KO) phenotype, B-Raf alleles were disrupted by introducing A-Raf cDNA under the control of endogenous B-Raf promoter. The resulting BRaf A-Raf/A-Raf (KIN) phenotype depends on genetic background. The living embryos displaying normal development but size reduction were found with low incidence at E12.5d-16.5d. All of them displayed the rescue of vascular system. One adult p20 mouse without any visible defects in development and behavior was obtained. On the other hand, the processes of neurogenesis and neural precursors migration in survived embryos were disturbed which led in some cases to underdevelopment of different brain compartments. TUNEL and cell proliferation (PCNA staining) assays revealed more apoptotic (E13.5d) and less proliferating(E12.5d cells within ventricular and sub-ventricular zones of brain ventricles and in striatum of KIN embryos. In addition, more apoptotic cells were detected in many other tissues of E13.5d and in lung of E16.5d KIN embryos but not in adult KIN mouse. p20 KIN mouse demonstrated reduced fraction of neural precursor cells in sub-granular zone of hippocampus and mature neurons in olfactory bulb. The other processes of neurogenesis were not disturbed in adult KIN animal. Fibroblasts obtained from KIN embryos demonstrated less proliferative ability and were more susceptible to apoptotic stimuli compared to WT. This was accompanied by the reduction of active ERK and Akt required for survival, and with decrease of inactive phosphorylated BAD. The kinetic of both ERK and Akt phosphorylation upon serum stimulation was delayed. All these data indicate that moderate A-Raf kinase activity can prevent the endothelial apoptosis but is not enough to completely rescue the other developmental consequences.
Growth factor induced signaling cascades are key regulatory elements in tissue development, maintenance and regeneration. Deregulation of the cascades has severe consequences, leading to developmental disorders and neoplastic diseases. As a major function in signal transduction, activating mutations in RAF family kinases are the cause of many human cancers. In the first project described in this thesis we focused on B-RAF V600E that has been identified as the most prevalent B-RAF mutant in human cancer. In order to address the oncogenic function of B-RAF V600E, we have generated transgenic mice expressing the activated oncogene specifically in lung alveolar epithelial type II cells. Constitutive expression of B-RAF V600E caused abnormalities in alveolar epithelium formation that led to airspace enlargements. These lung lesions showed signs of tissue remodeling and were often associated with chronic inflammation and low incidence of lung tumors. Inflammatory cell infiltration did not precede the formation of emphysema-like lesions but was rather accompanied with late tumor development. These data support a model where the continuous regenerative process initiated by oncogenic B-RAF-driven alveolar disruption provides a tumor-promoting environment associated with chronic inflammation. In the second project we focused on wild type B-RAF and its role in an oncogenic-C-RAF driven mouse lung tumor model. Toward this aim we have generated compound mice in which we could conditionally deplete B-RAF in oncogenic-C-RAF driven lung tumors. Conditional elimination of B-RAF did not block lung tumor formation however led to reduced tumor growth. The diminished tumor growth was not caused by increased cell death instead was a consequence of reduced cell proliferation. Moreover, B-RAF ablation caused a reduction in the amplitude of the mitogenic signalling cascade. These data indicate that in vivo B-RAF is dispensable for the oncogenic potential of active C-RAF; however it cooperates with oncogenic C-RAF in the activation of the mitogenic cascade.
The experimental work of this thesis addresses the questions of whether established cell lines injected into murine blastocysts find their way back home and seed preferentially at the site of their origin. Furthermore, can they change their fate and differentiate to unrelated cell types when exposed to the embryonic environment. This survey was based on the fact that different cell lines have different potentials in developing embryos, dependent on their cellular identity. The cell lines used in this survey were AGM region-deriving DAS 104-4, DAS 104-8 cells, yolk sac-deriving YSE cells and bone marrow-deriving FDCP mix cells. These cells were injected into mouse blastocysts. Donor cells were traced in developing embryos via specific markers. Analysis of the embryos revealed that DAS cells are promiscuous in their seeding pattern, since they were found in all analysed tissues with similar frequencies. YSE cells showed preferences in seeding yolk sac and liver. YSE donor cells in chimaeric tissues were not able to change their immuno-phenotype, indicating that they did not change their destiny. Analysis of adult mice did not reveal any of YSE-derived cells donor contribution. In contrast, FDCP mix cells mostly engrafted haematopoietic tissues, although the embryos analysed by in situ hybridization had donor signals frequently in cartilage primordia, heads, and livers. Analysis of whether FDCPmix-derived cells found in foetal livers were of haematopoietic or hepatocytes nature showed that progeny of injected FDCP mix cells do not differentiate into cells that express a hepatocyte-specific marker. Further analysis showed that FDCPmix-derived donor cells found in brain express neural or haematopoietic markers. In order to reveal if they transdifferentiate to neurons or fuse with neurons/glial cells, nuclear diameters of donor and recipient cells were determined. Comparison of the nuclear diameters of recipient and donor cells revealed no differences. Therefore this suggests that progeny of FDCP mix in brain are not fusion products. Analysis of adult mice tissues revealed that presence of FDCP mix-derived cells was the highest in brains. These results confirmed the assumption that the developmental potential of the analysed cells cannot be easily modified, even when exposed to early embryonic environment. Therefore one can conclude that the analysed cell types had different homing patterns depending on their origins.