Your search keyword '"Tiso, N"' showing total 6 results

1. Distinct delta and jagged genes control sequential segregation of pancreatic cell types from precursor pools in zebrafish

Author

Zecchin, E., primary, Filippi, A., additional, Biemar, F., additional, Tiso, N., additional, Pauls, S., additional, Ellertsdottir, E., additional, Gnügge, L., additional, Bortolussi, M., additional, Driever, W., additional, and Argenton, F., additional

Published

2007

2. A Smad3 transgenic reporter reveals TGF-beta control of zebrafish spinal cord development.

Author

Casari A, Schiavone M, Facchinello N, Vettori A, Meyer D, Tiso N, Moro E, and Argenton F

Subjects

Activin Receptors, Type I metabolism, Animals, Animals, Genetically Modified, Cell Cycle, Cell Proliferation, Genes, Reporter, Immunohistochemistry, Neurons metabolism, Phenotype, Promoter Regions, Genetic, Protein Serine-Threonine Kinases metabolism, Receptor, Transforming Growth Factor-beta Type I, Receptors, Transforming Growth Factor beta metabolism, Signal Transduction, Spinal Cord physiology, Zebrafish, Zebrafish Proteins metabolism, Gene Expression Regulation, Developmental, Smad3 Protein genetics, Spinal Cord embryology, Transforming Growth Factor beta metabolism, Transgenes, Zebrafish Proteins genetics

Abstract

TGF-beta (TGFβ) family mediated Smad signaling is involved in mesoderm and endoderm specifications, left-right asymmetry formation and neural tube development. The TGFβ1/2/3 and Activin/Nodal signal transduction cascades culminate with activation of SMAD2 and/or SMAD3 transcription factors and their overactivation are involved in different pathologies with an inflammatory and/or uncontrolled cell proliferation basis, such as cancer and fibrosis. We have developed a transgenic zebrafish reporter line responsive to Smad3 activity. Through chemical, genetic and molecular approaches we have seen that this transgenic line consistently reproduces in vivo Smad3-mediated TGFβ signaling. Reporter fluorescence is activated in phospho-Smad3 positive cells and is responsive to both Smad3 isoforms, Smad3a and 3b. Moreover, Alk4 and Alk5 inhibitors strongly repress the reporter activity. In the CNS, Smad3 reporter activity is particularly high in the subpallium, tegumentum, cerebellar plate, medulla oblongata and the retina proliferative zone. In the spinal cord, the reporter is activated at the ventricular zone, where neuronal progenitor cells are located. Colocalization methods show in vivo that TGFβ signaling is particularly active in neuroD+ precursors. Using neuronal transgenic lines, we observed that TGFβ chemical inhibition leads to a decrease of differentiating cells and an increase of proliferation. Similarly, smad3a and 3b knock-down alter neural differentiation showing that both paralogues play a positive role in neural differentiation. EdU proliferation assay and pH3 staining confirmed that Smad3 is mainly active in post-mitotic, non-proliferating cells. In summary, we demonstrate that the Smad3 reporter line allows us to follow in vivo Smad3 transcriptional activity and that Smad3, by controlling neural differentiation, promotes the progenitor to precursor switch allowing neural progenitors to exit cell cycle and differentiate., (Copyright © 2014 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2014

3. In vivo Wnt signaling tracing through a transgenic biosensor fish reveals novel activity domains.

Author

Moro E, Ozhan-Kizil G, Mongera A, Beis D, Wierzbicki C, Young RM, Bournele D, Domenichini A, Valdivia LE, Lum L, Chen C, Amatruda JF, Tiso N, Weidinger G, and Argenton F

Subjects

Animals, Animals, Genetically Modified, Biosensing Techniques, Cell Differentiation, Cell Movement, Neurons cytology, Neurons physiology, Zebrafish embryology, Wnt Signaling Pathway, Zebrafish physiology

Abstract

The creation of molecular tools able to unravel in vivo spatiotemporal activation of specific cell signaling events during cell migration, differentiation and morphogenesis is of great relevance to developmental cell biology. Here, we describe the generation, validation and applications of two transgenic reporter lines for Wnt/β-catenin signaling, named TCFsiam, and show that they are reliable and sensitive Wnt biosensors for in vivo studies. We demonstrate that these lines sensitively detect Wnt/β-catenin pathway activity in several cellular contexts, from sensory organs to cardiac valve patterning. We provide evidence that Wnt/β-catenin activity is involved in the formation and maintenance of the zebrafish CNS blood vessel network, on which sox10 neural crest-derived cells migrate and proliferate. We finally show that these transgenic lines allow for screening of Wnt signaling modifying compounds, tissue regeneration assessment as well as evaluation of potential Wnt/β-catenin genetic modulators., (Copyright © 2012 Elsevier Inc. All rights reserved.)

Published

2012

4. prep1.2 and aldh1a2 participate to a positive loop required for branchial arches development in zebrafish.

Author

Vaccari E, Deflorian G, Bernardi E, Pauls S, Tiso N, Bortolussi M, and Argenton F

Subjects

Animals, Body Patterning, Embryo, Nonmammalian metabolism, Gene Expression Regulation, Developmental, Retinal Dehydrogenase metabolism, Transcription Factors metabolism, Zebrafish metabolism, Zebrafish Proteins metabolism, Branchial Region embryology, Retinal Dehydrogenase genetics, Transcription Factors genetics, Zebrafish embryology, Zebrafish Proteins genetics

Abstract

Segmentation is a key step in embryonic development. Acting in all germ layers, it is responsible for the generation of antero-posterior asymmetries. Hox genes, with their diverse expression in individual segments, are fundamental players in the determination of different segmental fates. In vertebrates, Hox gene products gain specificity for DNA sequences by interacting with Pbx, Prep and Meis homeodomain transcription factors. In this work we cloned and analysed prep1.2 in zebrafish. In-situ hybridization experiments show that prep1.2 is maternally and ubiquitously expressed up to early somitogenesis when its expression pattern becomes more restricted to the head and trunk mesenchyme. Experiments of loss of function with prep1.2 morpholinos change the shape of the hyoid and third pharyngeal cartilages while arches 4-7 and pectoral fins are absent, a phenotype strikingly similar to that caused by loss of retinoic acid (RA). In fact, we show that prep1.2 is positively regulated by RA and required for the normal expression of aldh1a2 at later stages, particularly in tissues involved in the development of the branchial arches and pectoral fins. Thus, prep1.2 and aldh1a2 are members of an indirect positive feedback loop required for pharyngeal endoderm and posterior branchial arches development. As the paralogue gene prep1.1 is more important in hindbrain patterning and neural crest chondrogenesis, we provide evidence of a functional specialization of prep genes in zebrafish head segmentation and morphogenesis., (Copyright 2010 Elsevier Inc. All rights reserved.)

Published

2010

5. Function and regulation of zebrafish nkx2.2a during development of pancreatic islet and ducts.

Author

Pauls S, Zecchin E, Tiso N, Bortolussi M, and Argenton F

Subjects

Animals, Base Sequence, Gene Expression Regulation, Developmental, Homeobox Protein Nkx-2.2, Islets of Langerhans cytology, Islets of Langerhans embryology, Molecular Sequence Data, Pancreatic Ducts cytology, Pancreatic Ducts embryology, Promoter Regions, Genetic, Zebrafish metabolism, Zebrafish Proteins, Homeodomain Proteins metabolism, Islets of Langerhans metabolism, Pancreatic Ducts metabolism, Transcription Factors metabolism, Zebrafish embryology

Abstract

In the mouse Nkx2.2 is expressed in the entire pancreatic anlage. Nevertheless, absence of Nkx2.2 only perturbs the development of endocrine cell types, notably beta-cells which are completely absent. In order to test the possibility that Nkx2.2 might fulfil additional functions during pancreas development we analysed its zebrafish homologue nkx2.2a using gene targeting and GFP-transgenic fish lines. Our results suggest similar roles for nkx2.2a and Nkx2.2 during the development of the endocrine pancreas. Morpholino-based knock-down of nkx2.2a leads to a reduction of alpha- and beta-cell number and an increase of ghrelin-producing cells but, as in mice, does not affect delta-cells. Moreover, like in the mouse, two spatially distinct promoters regulate expression of nkx2.2a in precursors and differentiated islet cells. In addition we found that in zebrafish nkx2.2a is also expressed in the anterior pancreatic bud and, later, in the differentiated pancreatic ducts. A nkx2.2a-transgenic line in which pancreatic GFP expression is restricted to the pancreatic ducts revealed that single GFP-positive cells leave the anterior pancreatic bud and move towards the islet where they form intercellular connections between each other. Subsequently, these cells generate the branched network of the larval pancreatic ducts. Morpholinos that block nkx2.2a function also lead to the absence of the pancreatic ducts. We observed the same phenotype in ptf1a-morphants that are additionally characterized by a reduced number of nkx2.2a-positive duct precursors. Whereas important details of the molecular program leading to the differentiation of endocrine cell types are conserved between mammals and zebrafish, our results reveal a new function for nkx2.2a in the development of the pancreatic ducts.

Published

2007

6. Evolutionary conserved role of ptf1a in the specification of exocrine pancreatic fates.

Author

Zecchin E, Mavropoulos A, Devos N, Filippi A, Tiso N, Meyer D, Peers B, Bortolussi M, and Argenton F

Subjects

Animals, Base Sequence, Cell Differentiation genetics, Central Nervous System metabolism, DNA Primers, Humans, Immunohistochemistry, Mice, Pancreas cytology, Pancreas metabolism, Signal Transduction, Zebrafish, Evolution, Molecular, Pancreas embryology, Transcription Factors physiology

Abstract

We have characterized and mapped the zebrafish ptf1a gene, analyzed its embryonic expression, and studied its role in pancreas development. In situ hybridization experiments show that from the 12-somite stage to 48 hpf, ptf1a is dynamically expressed in the spinal cord, hindbrain, cerebellum, retina, and pancreas of zebrafish embryos. Within the endoderm, ptf1a is initially expressed at 32 hpf in the ventral portion of the pdx1 expression domain; ptf1a is expressed in a subset of cells located on the left side of the embryo posteriorly to the liver primordium and anteriorly to the endocrine islet that arises from the posterodorsal pancreatic anlage. Then the ptf1a expression domain buds giving rise to the anteroventral pancreatic anlage that grows posteriorly to eventually engulf the endocrine islet. By 72 hpf, ptf1a continues to be expressed in the exocrine compartment derived from the anteroventral anlage. Morpholino-induced ptf1a loss of function suppresses the expression of the exocrine markers, while the endocrine markers in the islet are unaffected. In mind bomb (mib) mutants, in which delta-mediated notch signalling is defective [Dev. Cell 4 (2003) 67], ptf1a is normally expressed. In addition, the slow-muscle-omitted (smu) mutants that lack expression of endocrine markers because of a defective hedgehog signalling [Curr. Biol. 11(2001) 1358] exhibit normal levels of ptf1a. This indicates that hedgehog signaling plays a different genetic role in the specification of the anteroventral (mostly exocrine) and posterodorsal (endocrine) pancreatic anlagen.

Published

2004