1 |
Cellular and molecular effects of fibroblast growth factors 2 and 4 on human umbilical veinal endothelial cellsKabbara, Khaled Wally 22 January 2016 (has links)
Fibroblast growth factors (FGFs), encompasses a family of 22 related polypeptide. There are 18 different biologically active FGF proteins. They influence a wide array of biological and physiological responses such as migration, proliferation, tissue homeostasis, and wound healing. Most FGF are secreted and bind to heparin sulphate binding proteins (HPSG) in the extra cellular matrix (ECM). FGF-binding protein (FGF-BP) is a chaperon protein that binds to FGF releasing from the ECM and chaperoning it to bind to FGF receptors (FGFRs). FGFR dimerize when bound to FGF and starts series of a signal cascade that ultimately leads to the activation of MAPK. FGF2 and FGF4 are selected from the pool of 18 different FGF to be studied in this investigation. Both FGF2 and FGF4 have been reported to be critical for development during embryogenesis. De-regulation of these proteins could lead to various pathologies including different types of cancers. Hence we attempt to investigate the cellular and molecular role of these proteins and their implication on cells in an attempt to set up a foundational understanding for further studies that will include FGF-BPs and FGFRs. To do so, we used HUVECs to examine FGF2 and FGF4 activity through Western Blot
analysis. We also investigated their effect on migration using the ECIS Migration Assays, on wound healing by the ECIS Wound Healing Assays and captured wound healing images through Incucyte. Data from these experiments indicated that both, FGF2 and FGF4, have a role in cellular migration and wound healing. They also show they have a dose response on these cells. As a result, we can use these models to further investigate FGF2 and FGF4 modulation by FGF-BP1 and FGF-BP3 and the affects cellular response.
|
2 |
Cardioprotection: effects of increased levels of fibroblast growth factor-2 in the heartJimenez, Sarah K. 31 August 2011 (has links)
High mortality rates from cardiovascular disease underscore the need for improved therapies. Thus, it is important to further our understanding of factors and mechanisms promoting cardiac protection and repair.
Fibroblast growth factor-2 (FGF-2), administered to the heart before or during injury exerts beneficial effects such as cytoprotection and angiogenesis. However, the effects of a chronic elevation in endogenous FGF-2 on recovery/remodeling after ischemic injury are not known. My hypothesis was that chronic elevation in endogenous FGF-2 expression (in FGF-2 overexpressing transgenic mice) exerts beneficial effects such as improved function after isoproterenol-induced injury in vivo.
The first study showed that treatment with the β-adrenergic agonist isoproterenol resulted in exaggerated levels of cellular infiltration and myocardial disarray in transgenic FGF-2 versus non-transgenic mouse myocardium. This was suggestive of increased cardiac injury in transgenic FGF-2 mice. Inhibition of T cells using the immunosuppressants cyclosporine A or antibodies against CD3ε attenuated cellular infiltration in transgenic FGF-2 mice, to levels comparable to those of non-transgenic mice, suggesting a T lymphocyte-mediated effect. Overall morphological data suggested that chronic FGF-2 elevation might have created an adverse outcome after cardiac injury.
In a follow-up study the effect of chronic FGF-2 elevation on cardiac function was examined, as measured by tissue Doppler imaging (TDI), after isoproterenol administration. FGF-2 overexpressing mice displayed improved cardiac function compared to controls, after isoproterenol, both acutely (24 h) and in a sustained fashion (2-4 weeks). The FGF-2 associated functional improvement at 2-4 weeks was attenuated following immunosuppression with cyclosporine A, but not treatment with anti-CD3ε antibodies. The FGF-2–associated functional improvement may be partially attributed to a cyclosporine A-sensitive (but anti-CD3-insensitive) infiltrating cell population. Thus cellular infiltration, in response to elevated FGF-2, may have a net beneficial effect.
In a third study, non-transgenic mice were put through a brief swimming protocol (exercise) prior to isoproterenol. This acute bout of exercise resulted in significant improvement in TDI function, compared to control groups, measured at 24 hours up to 4 weeks post-isoproterenol.
In conclusion, increased endogenous cardiac FGF-2 expression, or an acute bout of exercise, exert sustained beneficial effects against isoproterenol-induced cardiac injury.
|
3 |
Cardioprotection: effects of increased levels of fibroblast growth factor-2 in the heartJimenez, Sarah K. 31 August 2011 (has links)
High mortality rates from cardiovascular disease underscore the need for improved therapies. Thus, it is important to further our understanding of factors and mechanisms promoting cardiac protection and repair.
Fibroblast growth factor-2 (FGF-2), administered to the heart before or during injury exerts beneficial effects such as cytoprotection and angiogenesis. However, the effects of a chronic elevation in endogenous FGF-2 on recovery/remodeling after ischemic injury are not known. My hypothesis was that chronic elevation in endogenous FGF-2 expression (in FGF-2 overexpressing transgenic mice) exerts beneficial effects such as improved function after isoproterenol-induced injury in vivo.
The first study showed that treatment with the β-adrenergic agonist isoproterenol resulted in exaggerated levels of cellular infiltration and myocardial disarray in transgenic FGF-2 versus non-transgenic mouse myocardium. This was suggestive of increased cardiac injury in transgenic FGF-2 mice. Inhibition of T cells using the immunosuppressants cyclosporine A or antibodies against CD3ε attenuated cellular infiltration in transgenic FGF-2 mice, to levels comparable to those of non-transgenic mice, suggesting a T lymphocyte-mediated effect. Overall morphological data suggested that chronic FGF-2 elevation might have created an adverse outcome after cardiac injury.
In a follow-up study the effect of chronic FGF-2 elevation on cardiac function was examined, as measured by tissue Doppler imaging (TDI), after isoproterenol administration. FGF-2 overexpressing mice displayed improved cardiac function compared to controls, after isoproterenol, both acutely (24 h) and in a sustained fashion (2-4 weeks). The FGF-2 associated functional improvement at 2-4 weeks was attenuated following immunosuppression with cyclosporine A, but not treatment with anti-CD3ε antibodies. The FGF-2–associated functional improvement may be partially attributed to a cyclosporine A-sensitive (but anti-CD3-insensitive) infiltrating cell population. Thus cellular infiltration, in response to elevated FGF-2, may have a net beneficial effect.
In a third study, non-transgenic mice were put through a brief swimming protocol (exercise) prior to isoproterenol. This acute bout of exercise resulted in significant improvement in TDI function, compared to control groups, measured at 24 hours up to 4 weeks post-isoproterenol.
In conclusion, increased endogenous cardiac FGF-2 expression, or an acute bout of exercise, exert sustained beneficial effects against isoproterenol-induced cardiac injury.
|
4 |
The Effects of Basis FGF and Endothelin-1 on the Mitotic Activity and Survival of Cultured Carotid Body Chemoreceptor CellsPaciga, Mark January 1998 (has links)
Thesis / Master of Science (MS)
|
5 |
Régulation de la voie MEK/ERK par la signalisation éphrine lors du développement neural chez l'ascidie Ciona intestinalis / MEK/ERK regulation by the ephrin pathway during neural development in ascidian Ciona intestinalisHaupaix, Nicolas 10 February 2014 (has links)
Durant ma thèse, j’ai participé à une étude fonctionnelle qui a démontré que p120-RasGAP, une protéine appartenant à la famille GAP (GTPase-activating protein), est le médiateur cytoplasmique de l’éphrine lors de l’atténuation d’ERK1/2. Pour confirmer cela, j’ai réalisé une expérience de co-immunoprécipitation et j’ai démontré que p120-RasGAP s’associe au récepteur de l’éphrine, Eph3, quand celui-ci est activé par un ligand éphrine. Ce résultat indique fortement que les signaux FGF et éphrine convergent au niveau de Ras et qu’ils contrôlent de manière antagoniste son activité. Dès lors, j’ai analysé les autres événements de spécification cellulaire impliquant l’antagonisme FGF/éphrine. Chez l’embryon d’ascidie, le signal FGF est décrit comme inducteur du destin neural dans les cellules ectodermiques qui, en absence du signal FGF, adoptent le destin épidermique. L’induction neurale des ascidies a lieu au stade 32 cellules et se traduit par la spécification de quatre précurseurs neuraux (ERK+) parmi les 16 cellules ectodermiques. J’ai démontré que le signal éphrine/Eph/RasGAP antagonise le signal FGF pour générer une activation d’ERK1/2 de type tout ou rien parmi les cellules ectodermiques. Enfin, en collaboration avec Philip Abitua, doctorant dans le laboratoire du Dr. Mike Levine (UC Berkeley), nous démontrons que l’antagonisme entre les signaux éphrine et FGF est impliqué dans la régionalisation antéro-postérieure de la plaque neurale / During my thesis study, I was involved in functional studies to demonstrate that p120-RasGAP, a GTPase-activating-protein (GAP), is a cytoplasmic mediator of the ephrin-mediated ERK attenuation. To confirm this notion, I conducted a co-immunoprecipitation experiment and demonstrated that p120-RasGAP associates with an ephrin receptor, Eph3, when the latter is activated by an ephrin ligand in ascidian embryos. These results strongly indicate that FGF and ephrin signals converge at the level of Ras and control its activity antagonistically. Following this finding, I looked for other cell fate specification events controlled by the antagonism between ephrin and FGF signals. In ascidian embryos, FGF signals are known to induce neural fates in ectodermal cells which otherwise adopt epidermal fates. Ascidian neural induction takes place at the 32-cell stage, resulting in specification of specific four cells as ERK1/2-active neural precursors among 16 ectodermal cells. I was able to demonstrate that ephrin/Eph/RasGAP signals counterbalance FGF neural inducing signals to generate the ON-OFF response of ERK activation among the ectodermal cells. Finally, in collaboration with a PhD student in Dr. Mike Levine’s lab (UC Berkeley), the antagonism between ephrin and FGF signals plays a role in regionalisation of the neural plate along the anterior-posterior axis.
|
6 |
FGF2 Maintains the Proliferation of Neural Progenitors by Actively Suppressing the CKI p27Kip1 through Regulation of Cks1b TranscriptionDarr, Andrew 23 December 2009 (has links)
Identifying the mechanisms that regulate neural precursor cell (NPC) proliferation and differentiation is important for understanding CNS development among different vertebrates. My work has focused specifically on understanding how mitogenic factors, like basic fibroblast growth factor (FGF2), regulate the NPC cell cycle. Mitogenic factors and serum are thought to drive cell cycle and therefore proliferation mainly by activating G1-type cyclin-dependent kinases (CDKs). The general hypothesis being addressed here is that FGF2 also promotes cell cycle progression of NPCs through the degradation of the cell cycle inhibitor p27Kip1. I show that, in the presence of FGF2 in vitro, embryonic rat cortical NPCs express high protein levels of the CDC28 protein kinase regulatory subunit 1b (Cks1b), a component of the SCFSkp2 E3 ubiquitin ligase complex that targets p27Kip1 for proteasomal degradation. I also show that NPCs maintained in FGF2 express undetectable levels of p27KIP1, while removal of FGF2 results in increased p27Kip1 protein expression and decreased protein expression of Cks1b. RNA expression data shows that Cks1b mRNA is reduced in non-dividing NPCs but is present in dividing NPCs, suggesting that Cks1b is being regulated at the transcriptional level. Analysis of the putative promoter of Cks1b reveals numerous conserved transcription factor consensus sites that could potentially play a role in regulation of Cks1b transcription, including consensus sites for E2F and the cell cycle-dependent element (CDE) cell cycle genes homology region (CHR) tandem repressor element. I use chromatin immunoprecipitation and luciferase assays to identify which E2Fs occupy and regulate the transcription of Cks1b under different conditions of mitogen stimulation. The data show that E2F4 occupies the promoter of Cks1b in non-dividing NPCs while E2F1 binds exclusively in proliferating NPCs. Mutation of either the E2F or CDE/CHR consensus sites independently de-represses the activity of a Cks1b promoter reporter in NPCs in G0/G1, while mutation of both sites delays induction of promoter activity. Finally, I use in ovo electroporation to determine if p27Kip1 has an additional role in neuronal differentiation during early spinal cord development. I show that ectopic expression of p27Kip1 is insufficient to induce neuronal differentiation in spinal cord progenitors.
|
7 |
Srovnávací studie myších a lidských podpůrných buněk pomocí metody ELISAKošková, Stanislava January 2008 (has links)
No description available.
|
8 |
FGF8a is Required for Proper Vascularization of the Zebrafish RetinaWysolmerski, Erin 01 January 2015 (has links)
Fibroblast growth factors (FGFs) are critical in many aspects of embryonic development and other cellular functions including apoptosis, cell adhesion, and proliferation. FGF8a, specifically, is known to initiate retinal ganglion cell (RGC) differentiation along with FGF3 early in retinal development (Martinez-Morales et al., 2005b). There has been little research into later roles for FGF8a in eye development. Here we show mRNA expression of fgf8a in the presumptive RGCs of 2 day-old zebrafish, past the time of RGC differentiation (28-48 hours)(Schmitt and Dowling, 1996). In addition, mRNA expression of putative receptor, FGFR1b, was localized outside the retina on the presumptive vasculature. Acerebellar (ace) mutants lacking FGF8a show mispatterned retinal vasculature and a lack of blood flow through the eye at 48 hpf. Further, we looked to see if this lack of blood flow had any effect on the developing neural retina. We found a significant reduction in the size of ace mutant eyes and also a reduction in total cell numbers in the retina starting at 48 hours post fertilization (hpf) suggesting a role for fgf8a in neurovascular signaling. The cause of the small eye phenotype was found to be due to a lack of proliferating cells and not an increase in cell death. We hypothesized if this phenotype was a result of a lack of blood flow to the retina. It has previously been reported that zebrafish survive and develop normally for 7 days without blood flow as the embryo receives nutrients by simple diffusion with its surroundings (Sehnert et al., 2002). To investigate the role that blood flow plays on the developing retina we utilized a silent heart mutant (sih) fish line, which lacks cardiac troponin t resulting in embryos without blood flow, as heart contractility does not initiate. To explore lack of blood flow to the retina as a cause for the observed ace mutant phenotype, sih mutant eye phenotypes were assessed. Retina cell counts from these embryos show a decreased eye diameter and a loss in total retina cell numbers due to lack of proliferation, phenocopying ace mutants. sih mutants also show a mis-patterning of their retinal vasculature with ectopic vessel branches similar to ace mutants. Our data support the small eye phenotype seen in both mutants is a result due to lack of proliferation. After morpholino knock down of the receptor, fgfr1b, we see mispatterend vasculature that phenocopies what we see in ace mutants. These finding led us to hypothesize that FGF8a, secreted by the RGCs, signals through its receptor, FGFR1b, on the retinal vasculature to promote cell growth and development. Further these data suggest that the retinal vasculature subsequently responds by secreting an unknown factor to support the proliferation and maintenance of the RGCs.
|
9 |
FGF2 de 18kDa e de 22,5kDa: sinalização molecular parácrina e funções biológias / FGF2 species of 18 and 22.5 kDa: paracrine molecular signaling and biological functionsMurata, Gilson Masahiro 05 May 2010 (has links)
FGF2 (Fibroblast Growth Factor 2), o fundador da família FGF, tem funções regulatórias na mitogênese, diferenciação, morfogênese e reparo tecidual. Diversas espécies moleculares de FGF2 compartilham uma seqüência C-terminal comum de 155 aminoácidos, pois se originam de diferentes sítios de iniciação de leitura de um único mRNA. O menor, o FGF2-18kDa, é liberado extracelularmente para se ligar a receptores específicos (FGFRs) para disparar as funções parácrinas e autócrinas pelas quais este fator é conhecido. Por outro lado, as espécies maiores (FGF2-21, 22, 22,5 e 34kDa) são intracelulares se ligam a parceiros moleculares desconhecidos para exercer funções intrácrinas ainda indefinidas. O objetivo desta tese foi produzir espécies recombinantes do FGF2-18 e FGF2-22,5, na forma de proteínas de fusão, para analisar funções biológicas e mecanismos de sinalização. Nas células malignas Y1 de camundongo, os recombinantes de FGF2-18kDa (FGF2-18, His-FGF2-18 e His-FGF2-18-ProA) dispararam uma resposta antagônica estimulando as vias de sinalização mitogênica, mas bloqueando o ciclo celular. Nos fibroblastos não tumorigênicos Balb3T3, estes mesmos recombinantes de FGF2-18kDa dispararam apenas a resposta mitogênica clássica. Todos os efeitos biológicos destes recombinantes de FGF2-18kDa foram bloqueados pelo inibidor específico da proteína quinase de tirosina dos FGFRs, PD173074, demonstrando que são respostas intermediadas pelos FGFRs. Portanto, os domínios estruturais adicionados aos recombinantes de FGF2-18kDa não impediram que estas proteínas se ligassem e ativassem os FGFRs. Por outro lado, o recombinante His-FGF2-22,5 dispara apenas as vias de sinalização mitogênica em ambas as células Y1 e 3T3, mas este efeito biológico não é inibido por PD173074. Estes resultados sugerem que a seqüência N-terminal de 55 resíduos, rica em aminoácidos básicos, impede que o FGF2-22,5kDa se ligue e/ou ative os FGFRs. Entretanto, o recombinante His-FGF2-22,5ProA dispara a resposta antagônica característica do FGF2-18kDa. As implicações destes últimos resultados é que o domínio de ProA adicionado ao C-terminal torna o FGF2-22,5kDa um bom ligante dos FGFRs. A interação física entre ligante e receptor das formas recombinantes His-FGF2-18kDa (ou His-FGF2-18ProA) e FGF2-22,5kDa com os putativos FGFRs foi analisada através da técnica de SPR e os resultados mostram KDs aproximados (Kd18=21, 488.10-9 e Kd22,5=20,70393.10-9), enquanto que o número de sítios ligantes em vesículas microssomais das células é significantemente inferior para o FGF2-22,5kDa. Estes resultados são compatíveis com a existência de receptores diferentes para FGF2-18kDa e FGF2-22,5kDa, uma hipótese ainda a ser definitivamente corroborada. Em conclusão, o FGF2-18kDa, mesmo em formas recombinantes como proteína de fusão, dispara todos os efeitos biológicos descritos para FGF2, através dos FGFRs. Diferentemente, o FGF2-22,5kDa, como fator parácrino, só desencadeou a resposta mitogênica clássica de FGF2, provavelmente através de receptores diferentes dos FGFRs. Os resultados e conclusões desta tese têm um potencial indiscutivelmente relevante para a biologia molecular do câncer, com implicações possíveis em terapia oncológica / FGF2 (Fibroblast Growth Factor 2), the founder of the FGF family, has regulatory functions in mitogenesis, differentiation, morphogenesis and tissue repair. Multiple FGF2 molecular species, sharing a C-terminal sequence of 155 amino acids, are translated from different iniciation sites of the same mRNA. The smaller, the FGF2-18kD, is extracellularly released to bind to specific membrane receptors (FGFRs), performing paracrine and autocrine functions. On the other hand, the larger FGF2s (21, 22, 22.5 and 34kDa) are intracellular species that bind to unknown partners to play still undefined intracrine roles. The aim of this thesis was to produce recombinant species of FGF2-18kDa and FGF2-22,5kDa, in the form of fusion proteins, to analyze functions and signaling mechanisms. In mouse Y1 malignant cells, FGF2-18kD recombinants (FGF2-18kDa and His-FGF2-18kDaProA) triggered an antagonistic response activating mitogenic signaling pathways, but blocking the cell cycle. However, in non tumorigenic Balb3T3 fibroblasts, these same FGF2-18kD recombinants only elicited the classical mitogenic response. All biological effects of these FGF2-18kD recombinants were blocked by the specific inhibitor of FGFR-protein-tyrosine-kinases, PD173074, demonstrating that these responses are mediated by FGFRs. Therefore, the new peptide domains added to FGF2-18kD did not prevent these recombinant fusion proteins to bind and activate FGFRs. Conversely, the recombinant His-FGF2-22,5kDa triggered only mitogenic signaling pathways in both Y1 and Balb3T3 cells, a biological effect not inhibited by PD173074. These results suggested that the additional basic-rich N-terminal sequence of 55 amino acid residues, found in FGF2-22,5kDa, prevents this FGF2 species from binding and / or activate FGFRs. However, surprisingly, the recombinant His-FGF2-22kDaProA triggered the antagonistic response characteristic of FGF2-18kDa. These results imply that the ProA-domain added to the C-terminal end rendered the FGF2-22,5kDaProA a good ligand of FGFRs. The physical interaction between recombinants of both His-FGF2-18kD and His-FGF2-22kDa with putative FGFRs, analyzed by SPR, yielded close KD values (KD18=21, 5.10-9 e K D22,5=20,7.10-9), while the number of binding sites in cell microsomal vesicles were significantly lower for the His-FGF2-22,5kDa. These results are consistent with the existence of different receptors for FGF2 and FGF2-18kD-22,5kDa, a hypothesis that has yet to be definitively confirmed. In conclusion, FGF2-18kD, even as recombinant fusion proteins, triggered all biological effects of FGF2, through FGFRs. Conversely, the FGF2-22, 5kDa only triggered the classical mitogenic response, probably via receptors other than FGFRs. The results and conclusions of this thesis are potentially of great interest in cancer molecular biology, with implications in oncologic therapy.
|
10 |
FGF-2: estudo de estrutura e função / FGF-2: Study of structure and functionOliveira, Alexandre Dermargos 01 October 2007 (has links)
FGFs compreendem um grande família de 24 proteínas, participando de processos chaves nos mais variados tecidos, tendo funções parácrina, autócrina e intrácrina, regulando mitogênese, diferenciação celular, morfogênese e cicatrização. Mas, a relação estrutura-função dos FGFs é pobremente entendida. O membro protótipo desta família é o FGF-2, que apresenta quatro isoformas moleculares incluindo a forma de 18 kDa que é secretada e se liga aos receptores específicos (FGFRs) e dispara uma complexa sinalização. As outras isoformas, de alto peso molecular (21, 22 e 22,5 kDa) são expressas por códons alternativos (CUG) e permanecem no interior da célula interagindo com parceiros moleculares desconhecidos. Para antecipar mecanismos e parceiros do FGF-2 HMW foi realizada modelagem molecular desta isoforma que mostrou: uma estrutura do N-terminal da proteína com motivo β→α→β e manutenção do barril β. A busca por parceiros intracelulares, foi realizada através da técnica do duplo hibrido de levedura, usando um biblioteca de cDNA de cérebro de rato. Foram encontrados 4 possíveis parceiros: BRD2, UBE2I, BRPF1, PC4. Todas essas interações foram confirmadas através do crescimento da levedura em meio sem histidina, produção de β-galactosidase e ensaios de \"pull-down\" com GST. Analises por FACS confirmam que FGF2 não causa apoptose em células adrenais tumorais Y1 de camundongo, mas promovem um acumulo de células na fase S com bloqueio do ciclo celular e da proliferação, configurando uma forma de senescência. Resultados com as células humanas HEK-ER:Ras permitem fazer a seguinte generalização: FGF2 induz senescência em células malignas transformadas pelos oncogenes raso A superexpressão da proteína de fusão FGF-2(18kDa):protA, mas não a da FGF-2(22,5 kDa):protA, protege a célula Y1 da senescência induzida por FGF-2. Por outro lado, a superexpressão destas mesmas isoformas de FGF-2 fusionadas à proteína A em células imortalizadas Balb3T3 não causou transformação celular e nem alterou a resposta mitogênica destas células ao FGF-2 recombinante adicionado ao meio de cultura. Células Y1 quando tratadas com FGF-2 recombinante produz ROS intracelular e libera anions superóxido no meio extracelular. Além disso, o anti-oxidante NAC protege estas células da indução de senescência induzida por FGF-2, sugerindo que ROS pode ser intermediário no disparo de senescência por FGF-2. / FGFs comprise a large fami1y of 24 proteins that play key roles in a number of tissues as local paracrine, autocrine and intracrine regulators of mitogenesis, cellular differentiation, organ morphogenesis and tissue repair. Structure-function relationship among FGFs is still poorly understood. FGF-2, the fami1y prototype member, exists as four molecular species. The 18 kDa form is released to the extracellular milieu and binds to specific receptors (FGFR), initiating a complex array of signals. Other isoforms of higher molecular weights (21, 22 and 22,5 kDa) are translated from alternative codons (CUG) and remain inside of the cell interacting with unknown partners. Aiming to anticipate mechanisms and partners, we modeled the FGF2-HMW molecule, showing that the protein displays β→α→β motif in the N-terminal region and maintains the β-barrel structure common to ali FGFs. By the yeast two-hybrid method, using a cDNA rat brain library, we found four possible partners for FGF2-HMW: BRD2, UBE2I, BRP1 and PC4. Ali partners were confirmed by yeast growth without histidine, production of β-galactosidase and \"pull-down\" assays with GST. FACS analyses confirmed that FGF2 does not cause apoptosis in mouse Y1 adrenal tumor cells. But, FGF2 inhibited S phase progression blocking cell cycle and proliferation, characterizing a form of senescence. In addition, results obtained with the human HEK-ER:Ras cells support the following general statement: FGF2 triggers senescence in malignant cells transformed by ras oncogenes. Ectopic expression of the fusion protein FGF-2(18 kDa):protA, but not of FGF-2(22,s kDa):protA, protected Y1 cells senescence induced by FGF-2. On the other hand, ectopic expression of FGF-2 isoforms fusioned to protA in Balb3T3 immortalized cells did not cause transformation and neither modified the mitogenic response of this cell to recombinant FGF2. Recombinant FGF-2 stimules Y1 cells to produce intracellular ROS and to release superoxide anions into intracellular medium. Moreover, the ROS scavenger NAC protect Y1 cells from senescence induced by FGF-2, suggesting that ROS may be mediate senescence triggering induced by FGF-2.
|
Page generated in 0.0516 seconds