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- Vanadate effects on bone metabolism: fish cell lines as an alternative to mammalian in vitro systemsPublication . Tiago, Daniel; Laizé, Vincent; Aureliano, M.; Cancela, LeonorVanadate, one of the most relevant forms of vanadium in solution, has been associated with the regulation of various enzyme activities (e.g. phosphatases, ribonucleases, ATPases, etc.) and shown to exhibit important biological effects. Several in vivo and in vitro studies have clearly demonstrated that any deficiency or excess of vanadium can seriously affect bone formation and its metabolism. Bone-related effects result largely from vanadium insulino-mimetic capabilities mediated by specific inhibition of protein tyrosine phosphatases (PTPases) and consequent activation of tyrosine kinase receptors (e.g. insulin receptor). Although mammals have been repetitively shown to be appropriate models to study vanadate mechanisms of action, fish have recently emerged as alternative models. Fish has been recognized as suitable model to study vertebrate bone formation and the natural presence of high quantities of vanadium in water makes it even more suitable to investigate vanadium effect on bone formation. Recent data obtained using fish bone-derived cells revealed that micromolar concentrations (5 mM) of monomeric and decameric vanadate slightly stimulate growth performances while strongly inhibiting extracellular matrix mineralization through mechanisms involving both alkaline phosphatase and MAPK pathways. Recent data obtained in fish cells will be discussed here and further compared to results obtained in mammalian systems.
- Impairment of mineralization by metavanadate and decavanadate solutions in a fish bone-derived cell linePublication . Tiago, Daniel; Laizé, Vincent; Cancela, Leonor; Aureliano, M.Vanadium, a trace metal known to accumulate in bone and to mimic insulin, has been shown to regulate mammalian bone formation using in vitro and in vivo systems. In the present work, short- and long-term effects of metavanadate (containing monomeric, dimeric, tetrameric and pentameric vanadate species) and decavanadate (containing decameric vanadate species) solutions on the mineralization of a fish bone-derived cell line (VSa13) were studied and compared to that of insulin. After 2 h of incubation with vanadate (10 μM in monomeric vanadate), metavanadate exhibited higher accumulation rates than decavanadate (6.85±0.40 versus 3.95±0.10 μg V/g of protein, respectively) in fish VSa13 cells and was also shown to be less toxic when applied for short periods. In longer treatments with both metavanadate and decavanadate solutions, similar effects were promoted: stimulation of cell proliferation and strong impairment (75%) of extracellular matrix (ECM) mineralization. The effect of both vanadate solutions (5 μM in monomeric vanadate), on ECM mineralization was increased in the presence of insulin (10 nM). It is concluded that chronic treatment with both vanadate solutions stimulated fish VSa13 cells proliferation and prevented ECM mineralization. Newly developed VSa13 fish cells appeared to be appropriate in the characterization of vanadate effects on vertebrate bone formation, representing a good alternative to mammalian systems.
- New insights into mineralogenic effects of vanadatePublication . Laizé, Vincent; Tiago, Daniel; Aureliano, M.; Cancela, LeonorVanadium is a transition metal that occurs naturally in a variety of minerals and exhibits an exceptional complex chemistry in solution, e.g., several oxidation states ranging from ?2 to ?5, and formation of vanadium oligomers such as decameric vanadate (?5) species [1–4]. Besides its metallurgical role in steel alloys, vanadium is also an ultra trace element known to participate in many biological processes and considered to be essential for living organisms [5, 6]. It accumulates in a variety of organisms ranging from microbes to vertebrates, where it modulates the activity of an array of key enzymes or participates as a cofactor in the active centre of others [1, 2, 5–9]. In mammals, vanadium compounds can mimic insulin action and may prevent chemical carcinogenesis, most probably through the inhibition of cellular tyrosine phosphatases and subsequent activation of signalling pathways, suggesting their use as pharmacological tools to treat human diabetes mellitus and cancer, respectively [10–14]. Anti-tumoral action of vanadium is, however, controversial as several studies have proposed that vanadium could act as a mitogen, tumor promoter and co-carcinogen (see [15] and references therein). Other studies have reported an osteogenic role for vanadium compounds and suggest that vanadium could also have a therapeutic application in bone-related diseases, such as osteoporosis [16–18]. Decades of research have thus provided evidence for vanadium’s physiological and pharmacological properties, supporting the claim that it may represent a promising therapeutic agent for diseases targeting billions of human beings and affecting a wide range of pathological conditions. However, the development of vanadium-based pharmaceuticals will probably take some time since various issues related to vanadium toxicity, speciation and multiple targeting will need to be solved before advancing to clinical trials. Despite being used for decades by researchers as an inhibitor of protein tyrosine phosphatases, it is still not totally clear which vanadium species induce or which signalling pathways transduce physiological and pharmacological effects. Vanadium chemistry is complex, and different species or complexes may induce different pathways [5], affecting different biological processes. This work intends to review what is presently known about the bone-related role of vanadium in mammals and present recent in vitro data on the mineralogenic effect of vanadate in fish, which have become promising model organisms for vertebrate bone-related studies.
- Impairment of mineralization by metavanadate and decavanadate solutions in a fish bone-derived cell linePublication . Tiago, Daniel; Laizé, Vincent; Cancela, Leonor; Aureliano, M.Vanadium, a trace metal known to accumulate in bone and to mimic insulin, has been shown to regulate mammalian bone formation using in vitro and in vivo systems. In the present work, short- and long-term effects of metavanadate (containing monomeric, dimeric, tetrameric and pentameric vanadate species) and decavanadate (containing decameric vanadate species) solutions on the mineralization of a fish bone-derived cell line (VSa13) were studied and compared to that of insulin. After 2 h of incubation with vanadate (10 μM in monomeric vanadate), metavanadate exhibited higher accumulation rates than decavanadate (6.85±0.40 versus 3.95± 0.10 μg V/g of protein, respectively) in fish VSa13 cells and was also shown to be less toxic when applied for short periods. In longer treatments with both metavanadate and decavanadate solutions, similar effects were promoted: stimulation of cell proliferation and strong impairment (75%) of extracellular matrix (ECM) mineralization. The effect of both vanadate solutions (5 μM in monomeric vanadate), on ECM mineralization was increased in the presence of insulin (10 nM). It is concluded that chronic treatment with both vanadate solutions stimulated fish VSa13 cells proliferation and prevented ECM mineralization. Newly developed VSa13 fish cells appeared to be appropriate in the characterization of vanadate effects on vertebrate bone formation, representing a good alternative to mammalian systems.
- Vanadate proliferative and anti-mineralogic effects are mediated by MAPK and PI-3K/Ras/Erk pathways in a fish chondrocyte cell linePublication . Tiago, Daniel; Cancela, Leonor; Aureliano, M.; Laizé, VincentWe recently reported proliferative and anti-mineralogenic effects of vanadate on fish chondrocytes and here we investigate the signalling pathways associated with these effects. Our data show that vanadate stimulates chondrocyte proliferation through the MAPK pathway, using signalling mechanisms similar to those used by IGF-1, while it inhibits chondrocyte differentiation/mineralization through a putative PI-3K/Ras/ Erk signalling, a pathway shared with insulin. Our data also suggest that vanadate impairs ECM mineralization not only by interfering with regulatory pathways but also by inhibiting enzymatic activity of ALP. Finally, this work provides additional evidence for the conservation, throughout evolution, of mechanisms regulating chondrocyte proliferation and differentiation.
- Vanadate and bone metabolism: effect on proliferation and mineralization of fish bone-derived cellsPublication . Tiago, Daniel; Laizé, Vincent; Cancela, Leonor; Aureliano, M.Vanadate is known for mimicking insulin action through activation of insulin and/or insulin like growth factor 1 (IGF 1) receptors. Vanadate insulin- like effect on bone-related metabolism has been previously investigated using mammalian in vitro cell systems but other vertebrate systems have rarely been used. We have recently demonstrated the suitability of a fish bone derived cell line (VSa13) to study anti-mineralogenic effects of vanadate. Here, we propose that vanadate stimulation of cell proliferation involves MAPK signalling pathway and IGF 1 receptor activation, while impairment of extracellular matrix (ECM) mineralization is likely to involve both MAPK and PI 3K pathways and insulin receptor activation.