Mesoderm induction in Xenopus is a zygotic event regulated by maternal VegT via TGFbeta growth factors.
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The maternal transcription factor VegT is important for establishing the primary germ layers in Xenopus. In previous work, we showed that the vegetal masses of embryos lacking maternal VegT do not produce mesoderm-inducing signals and that mesoderm formation in these embryos occurred ectopically, from the vegetal area rather than the equatorial zone of the blastula. Here we have increased the efficiency of the depletion of maternal VegT mRNA and have studied the effects on mesoderm formation. We find that maternal VegT is required for the formation of 90% of mesodermal tissue, as measured by the expression of mesodermal markers MyoD, cardiac actin, Xbra, Xwnt8 and alphaT4 globin. Furthermore, the transcription of FGFs and TGFbetas, Xnr1, Xnr2, Xnr4 and derriere does not occur in VegT-depleted embryos. We test whether these growth factors may be endogenous factors in mesoderm induction, by studying their ability to rescue the phenotype of VegT-depleted embryos, when their expression is restricted to the vegetal mass. We find that Xnr1, Xnr2, Xnr4 and derriere mRNA all rescue mesoderm formation, as well as the formation of blastopores and the wild-type body axis. Derriere rescues trunk and tail while nr1, nr2 and nr4 rescue head, trunk and tail. We conclude that mesoderm induction in Xenopus depends on a maternal transcription factor regulating these zygotic growth factors. (+info)
Neuregulin induces the expression of mesodermal genes in the ectoderm of Xenopus laevis.
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The primary patterning event in early vertebrate development is the formation of mesoderm and subsequent induction of the neural tube by the mesoderm. Some of the transforming growth factor (TGF)-beta family (Activin, Vg1) and the fibroblast growth factor (FGF) family molecules have been implicated for their roles in mesoderm induction. Here we show first the evidence that neuregulin, an epidermal growth factor (EGF)-like growth factor known for its role in neural and muscle differentiation, participates in mesoderm induction. Neuregulin could induce the ectopic expression of mesoderm specific gene Xbra in animal cap explants reared to the midgastrula stage, when animal caps dissected from late blastula were cultured with Neuregulin at a low concentration (10 ng/ml). In situ hybridization study showed that alpha-cardiac actin was expressed in animal caps that were treated with Neuregulin overnight. Skeletal and cardiac muscle specific genes such as MyoD family genes (myoD, MRF4, myf5) and SL1 as well as NCAM, a pan neural marker, were also ectopically expressed by treatment with Neuregulin. However, the expression of NCAM is presumed to be a secondary result of the initial mesoderm induction by Neuregulin. The temporal expression pattern of neuregulin during the early developmental stages was analyzed by RT-PCR in order to determine if neuregulin is expressed at the time of mesoderm induction. It has been found that the neuregulin transcript was already detected from the 16-cell stage (stage 5) and continued to be expressed till the tailbud stage (stage 25), the latest embryonic stage analyzed in this study. Considering that the mesoderm is induced at early blastula before the start of zygotic transcription, maternal neuregulin is expressed at the right time to participate in mesoderm induction. These data strongly suggest that neuregulin plays an important role in mesoderm induction. (+info)
Mga, a dual-specificity transcription factor that interacts with Max and contains a T-domain DNA-binding motif.
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The basic-helix-loop-helix-leucine zipper (bHLHZip) proteins Myc, Mad and Mnt are part of a transcription activation/repression system involved in the regulation of cell proliferation. The function of these proteins as transcription factors is mediated by heterodimerization with the small bHLHZip protein Max, which is required for their specific DNA binding to E-box sequences. We have identified a novel Max-interacting protein, Mga, which contains a Myc-like bHLHZip motif, but otherwise shows no relationship with Myc or other Max-interacting proteins. Like Myc, Mad and Mnt proteins, Mga requires heterodimerization with Max for binding to the preferred Myc-Max-binding site CACGTG. In addition to the bHLHZip domain, Mga contains a second DNA-binding domain: the T-box or T-domain. The T-domain is a highly conserved DNA-binding motif originally defined in Brachyury and characteristic of the Tbx family of transcription factors. Mga binds the preferred Brachyury-binding sequence and represses transcription of reporter genes containing promoter-proximal Brachyury-binding sites. Surprisingly, Mga is converted to a transcription activator of both Myc-Max and Brachyury site-containing reporters in a Max-dependent manner. Our results suggest that Mga functions as a dual-specificity transcription factor that regulates the expression of both Max-network and T-box family target genes. (+info)
Artefactual gene induction during preparation of Xenopus laevis animal cap explants.
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The animal cap assay in Xenopus laevis was used to study the induction and regulation of the mesoderm-specific gene Xegr-1, a homolog of the mammalian egr-1 genes. Egr-1 is an immediate-early gene whose growth factor-stimulated transcriptional induction displays a transient activity profile and occurs independent of protein synthesis. The Xegr-1 promoter contains multiple serum response elements (SREs). In this paper we show that Xegr-1 is induced unspecifically during the process of animal cap preparation. Transcripts of Xegr-1 appear already 30 min after cutting of animal caps. Xfos, another SRE-regulated immediate-early gene, is induced with the same kinetics as Xegr-1. In contrast, the Xbra gene is not induced under the experimental conditions used. Xfos and Xegr-1 transcripts are not rapidly down-regulated after mechanical stimulation, but can be detected for up to 4 h later. Wounding-dependent Xegr-1 induction is reduced by injection of either mRNA coding for the dominant inhibitory forms of both the FGF receptor and the transcription factor Elk-1. Xegr-1 expression can be reinduced by mesoderm-inducing factors. These results led us to develop a new protocol for animal cap preparation, which circumvents the observed undesired artefactual gene activation events. (+info)
Tbx5 and the retinotectum projection.
(45/1708)
Dorsal and ventral aspects of the eye are distinct from the early stages of development. The developing eye cup grows dorsally, and the choroidal fissure is formed on its ventral side. Retinal axons from the dorsal and ventral retina project to the ventral and dorsal tectum, respectively. Misexpression of the Tbx5 gene induced dorsalization of the ventral side of the eye and altered projections of retinal ganglion cell axons. Thus, Tbx5 is involved in eye morphogenesis and is a topographic determinant of the visual projections between retina and tectum. (+info)
T (Brachyury) is a direct target of Wnt3a during paraxial mesoderm specification.
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Wnt3a encodes a signal that is expressed in the primitive streak of the gastrulating mouse embryo and is required for paraxial mesoderm development. In its absence cells adopt ectopic neural fates. Embryos lacking the T-box-containing transcription factors, Brachyury or Tbx6, also lack paraxial mesoderm. Here we show that Brachyury is specifically down-regulated in Wnt3a mutants in cells fated to form paraxial mesoderm. Transgenic analysis of the T promoter identifies T (Brachyury) as a direct transcriptional target of the Wnt signaling pathway. Our results suggest that Wnt3a, signaling via Brachyury, modulates a balance between mesodermal and neural cell fates during gastrulation. (+info)
Gradual refinement of activin-induced thresholds requires protein synthesis.
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Activin induces the expression of different genes in a concentration-dependent manner. In this paper, we show that the initial response of cells to activin, whether assayed in dispersed cells or in a bead-implantation regime in intact animal caps, is to activate expression of both Xbra and goosecoid. However, differential expression of the two genes, with down-regulation of Xbra, occurs very rapidly and certainly within 3 h of the initial phase of expression. This rapid refinement of gene expression can occur in dispersed cells and thus does not require cell-cell interactions. Refinement of gene expression does, however, require protein synthesis but not goosecoid function. Together, our results place the burden of threshold formation not on the initial induction of different genes but on regulatory interactions between the genes once they have been activated. (+info)
Double-stranded RNA injection produces null phenotypes in zebrafish.
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Zebrafish is a simple vertebrate that has many attributes that make it ideal for the study of developmental genetics. One feature that has been lacking in this model system is the ability to disable specifically targeted genes. Recently, double-stranded RNA has been used to silence gene expression in the nematode Caenorhabditis elegans. We have found that expression of the green fluorescent protein (GFP) from a microinjected plasmid vector can be suppressed in zebrafish embryos by the coinjection of a double-stranded RNA that is specifically targeted to GFP. To determine that double-stranded RNA can attenuate endogenous gene expression, single-cell zebrafish embryos were injected with double-stranded RNA specifically targeted to Zf-T and Pax6.1. We found that microinjection of double-stranded Zf-T RNA resulted in a high incidence of a phenotype similar to that of ntl. Furthermore, Zf-T gene expression could not be detected by in situ hybridization and the message was decreased by 75% by semiquantitative RT-PCR in 12-h embryos that had been injected with the double-stranded RNA. Expression of the zebrafish genes sonic hedgehog and floating head was altered in the embryos microinjected with the Zf-T double-stranded RNA in a manner that is remarkably similar to the zebrafish no-tail mutant. Microinjection of double-stranded RNA targeted to Pax6.1 was associated with depressed expression of Pax6. 1 and resulted in absent or greatly reduced eye and forebrain development, similar to the phenotype seen in mouse mutants. Simultaneous injection of Pax6.1 and Zf-T resulted in embryos lacking notochords, eyes, and brain structures. (+info)