Daniel M. Tiago

Alternatively spliced transcripts of Sparus aurata insulin-like growth factor 1 are differentially expressed in adult tissues and during early development

Spliced variants of insulin-like growth factor 1 (IGF-1), a small peptide with a critical role in metabolism and growth, have been identified in various vertebrate species. However, despite recent functional data in mammalian systems suggesting specific roles (e.g. in muscle formation) for their pro-peptides and/or E domains, their function remains unclear. In this study, three alternatively spliced variants of Sparus aurata proIGF-1 (1a, 1b, and 1c) were identified and their expression analyzed. In adult fish, IGF-1 gene expression was observed in various soft tissues (highest levels in liver) and calcified tissues, with IGF-1c being always the most expressed isoform. In developing larvae, each isoform presented a specific pattern of expression, characterized by different onset and extent and consistent with a possible role of IGF-1a and 1b during early post-hatching events (e.g. bone or muscle formation), while IGF-1c would be rather involved in early larvae formation but probably acts in concerted action with other isoforms at later stages. We also propose that, in adults, IGF-1a and 1b isoforms may have a local action, while isoform 1c would assume a systemic action, as its mammalian counterpart. This hypothesis was further supported by in silico analysis of isoform distribution, revealing that only IGF-1c/Ea isoform has been conserved throughout evolution and that other fish isoforms (i.e. 1a and 1b) may be associated with mechanisms of osmoregulation. We finally propose that IGF-1 variants may exhibit different modes of action (systemic or local) and may be involved in different developmental and adaptive mechanisms.

Vanadate proliferative and anti-mineralogenic effects are mediated by MAPK and PI-3K/Ras/Erk pathways in a fish chondrocyte cell line.

We 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.

MiR-29a is an enhancer of mineral deposition in bone-derived systems.

MicroRNAs (miRNAs) provide a mechanism for fine-tuning of intricate cellular processes through post-transcriptional regulation. Emerging evidences indicate that miRNAs play key roles in regulation of osteogenesis. The miR-29 family was previously implicated in mammalian osteoblast differentiation by targeting extracellular matrix molecules and modulating Wnt signaling. Nevertheless, the function of miR-29 in bone formation and homeostasis is not completely understood. Here, we provide novel insights into the biological effect of miR-29a overexpression in a mineralogenic cell system (ABSa15). MiR-29a gain-of-function resulted in significant increase of extracellular matrix mineralization, probably due to accelerated differentiation. We also demonstrated for the first time that miR-29a induced β-catenin protein levels, implying a stimulation of canonical Wnt signaling. Our data also suggests that SPARC is a conserved target of miR-29a, and may contribute to the phenotype observed in ABSa15 cells. Finally, we provide evidences for miR-29a conservation throughout evolution based on sequence homology, synteny analysis and expression patterns. Concluding, miR-29a is a key player in osteogenic differentiation, leading to increased mineralization in vitro, and this function seems to be conserved throughout vertebrate evolution by interaction with canonical Wnt signaling and conservation of targets.

New insights into mineralogenic effects of vanadate.

Vanadium 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.

Proliferative and mineralogenic effects of insulin, IGF-1, and vanadate in fish osteoblast-like cells.

Fish have recently been recognized as a suitable model and a promising alternative to mammalian systems to study skeletogenesis. In this regard, several fish bone-derived cell lines have been developed and are being used to investigate mechanisms associated with insulin-like action of vanadium on extracellular matrix (ECM) mineralization. Although proliferative and mineralogenic effects of vanadate, insulin-like growth factor 1 (IGF-1), and insulin have recently been evaluated in a fish prechondrocyte cell line, no data are available in fish bone-forming cells, the osteoblasts. Using fish preosteoblast cells, we showed that IGF-1, but not insulin or vanadate, stimulated cell proliferation through the mitogen-activated protein kinase (MAPK) pathway, while both IGF-1 and vanadate inhibited cell differentiation/ECM mineralization through the same mechanism. Our data also indicated that the phosphatidyl inositol-3 kinase (PI-3K) pathway stimulates differentiation/ECM mineralization in osteoblasts and could represent a way to balance MAPK pathway action. The comparison of these new data obtained in fish with those available in mammals clearly evidenced a conservation of regulatory mechanisms among vertebrate bone-derived systems, although different players are involved.

Enhanced DNA transfer into fish bone cells using polyethylenimine.

The use of in vitro cell culture systems to assess gene function largely depends on the successful transfer of DNA into target cells. Well developed in mammals, transfection methods are still to be optimized for non-mammalian cell culture systems, like fish. Here we describe a rapid, cost-efficient, and successful method to transfer DNA into a fish bone-derived cell line using polyethylenimine (PEI) as the DNA carrier. Using this method, DNA transfer was remarkably enhanced in comparison with commercially available reagents, as demonstrated by the increased activity of both luciferase and green fluorescent protein observed in the transfected cells. Its efficiency in transferring DNA intoa wide range of cell types, including non-mammalian and hard-to-transfect cells, in addition to a low cost, show that PEI is a reagent of choice for nonviral vector transfection.

Global analysis of gene expression in mineralizing fish vertebra-derived cell lines: new insights into anti-mineralogenic effect of vanadate

BackgroundFish has been deemed suitable to study the complex mechanisms of vertebrate skeletogenesis and gilthead seabream (Sparus aurata), a marine teleost with acellular bone, has been successfully used in recent years to study the function and regulation of bone and cartilage related genes during development and in adult animals. Tools recently developed for gilthead seabream, e.g. mineralogenic cell lines and a 4 × 44K Agilent oligo-array, were used to identify molecular determinants of in vitro mineralization and genes involved in anti-mineralogenic action of vanadate.ResultsGlobal analysis of gene expression identified 4,223 and 4,147 genes differentially expressed (fold change - FC > 1.5) during in vitro mineralization of VSa13 (pre-chondrocyte) and VSa16 (pre-osteoblast) cells, respectively. Comparative analysis indicated that nearly 45% of these genes are common to both cell lines and gene ontology (GO) classification is also similar for both cell types. Up-regulated genes (FC > 10) were mainly associated with transport, matrix/membrane, metabolism and signaling, while down-regulated genes were mainly associated with metabolism, calcium binding, transport and signaling. Analysis of gene expression in proliferative and mineralizing cells exposed to vanadate revealed 1,779 and 1,136 differentially expressed genes, respectively. Of these genes, 67 exhibited reverse patterns of expression upon vanadate treatment during proliferation or mineralization.ConclusionsComparative analysis of expression data from fish and data available in the literature for mammalian cell systems (bone-derived cells undergoing differentiation) indicate that the same type of genes, and in some cases the same orthologs, are involved in mechanisms of in vitro mineralization, suggesting their conservation throughout vertebrate evolution and across cell types. Array technology also allowed identification of genes differentially expressed upon exposure of fish cell lines to vanadate and likely involved in its anti-mineralogenic activity. Many were found to be unknown or they were never associated to bone homeostasis previously, thus providing a set of potential candidates whose study will likely bring insights into the complex mechanisms of tissue mineralization and bone formation.

Matrix Gla protein repression by miR-155 promotes oncogenic signals in breast cancer MCF-7 cells.

MGP is a protein that was initially associated with the inhibition of calcification in skeleton, soft tissues, and arteries, but more recently also implicated in cancer. In breast cancer, higher levels of MGP mRNA were associated with poor prognosis, but since this deregulation was never demonstrated at the protein level, we postulated the involvement of a post‐transcriptional regulatory mechanism. In this work we show that MGP is significantly repressed by miR‐155 in breast cancer MCF‐7 cells, and concomitantly there is a stimulation of cell proliferation and cell invasiveness. This study brings new insights into the putative involvement of MGP and oncomiR‐155 in breast cancer, and may contribute to develop new therapeutic strategies.

Evidences for a New Role of miR-214 in Chondrogenesis

AbstractmiR-214 is known to play a role in mammalian skeletal development through inhibition of osteogenesis and stimulation of osteoclastogenesis, but data regarding other vertebrates, as well as a possible role in chondrogenesis, remain unknown. Here, we show that miR-214 expression is detected in bone and cartilage of zebrafish skeleton, and is downregulated during murine ATDC5 chondrocyte differentiation. Additionally, we observed a conservation of the transcriptional regulation of miR-214 primary transcript Dnm3os in vertebrates, being regulated by Ets1 in ATDC5 chondrogenic cells. Moreover, overexpression of miR-214 in vitro and in vivo mitigated chondrocyte differentiation probably by targeting activating transcription factor 4 (Atf4). Indeed, miR-214 overexpression in vivo hampered cranial cartilage formation of zebrafish and coincided with downregulation of atf4 and of the key chondrogenic players sox9 and col2a1. We show that miR-214 overexpression exerts a negative role in chondrogenesis by impacting on chondrocyte differentiation possibly through conserved mechanisms.

Central role of betaine–homocysteine S-methyltransferase 3 in chondral ossification and evidence for sub-functionalization in neoteleost fish

BACKGROUND To better understand the complex mechanisms of bone formation it is fundamental that genes central to signaling/regulatory pathways and matrix formation are identified. Cell systems were used to analyze genes differentially expressed during extracellular matrix mineralization and bhmt3, coding for a betaine-homocysteine S-methyltransferase, was shown to be down-regulated in mineralizing gilthead seabream cells. METHODS Levels and sites of bhmt3 expression were determined by qPCR and in situ hybridization throughout seabream development and in adult tissues. Transcriptional regulation of bhmt3 was assessed from the activity of promoter constructs controlling luciferase gene expression. Molecular phylogeny of vertebrate BHMT was determined from maximum likelihood analysis of available sequences. RESULTS bhmt3 transcript is abundant in calcified tissues and localized in cartilaginous structures undergoing endo/perichondral ossification. Promoter activity is regulated by transcription factors involved in bone and cartilage development, further demonstrating the central role of Bhmt3 in chondrogenesis and/or osteogenesis. Molecular phylogeny revealed the explosive diversity of bhmt genes in neoteleost fish, while tissue distribution of bhmt genes in seabream suggested that neoteleostean Bhmt may have undergone several steps of sub-functionalization. CONCLUSIONS Data on bhmt3 gene expression and promoter activity evidences a novel function for betaine-homocysteine S-methyltransferase in bone and cartilage development, while phylogenetic analysis provides new insights into the evolution of vertebrate BHMTs and suggests that multiple gene duplication events occurred in neoteleost fish lineage. GENERAL SIGNIFICANCE High and specific expression of Bhmt3 in gilthead seabream calcified tissues suggests that bone-specific betaine-homocysteine S-methyltransferases could represent a suitable marker of chondral ossification.