Academic literature on the topic 'Vertebrates Wnt genes'

All vertebrates possess anatomical features not seen in their closest living relatives, the protochordates (tunicates and amphioxus). Some of these features depend on developmental processes or cellular behaviours that are again unique to vertebrates. We are interested in the genetic changes that may have permitted the origin of these innovations. Gene duplication, followed by functional divergence of new genes, may be one class of mutation that permits major evolutionary change. Here we examine the hypothesis that gene duplication events occurred close to the origin and early radiation of the vertebrates. Genome size comparisons are compatible with the occurrence of duplications close to vertebrate origins; more precise insight comes from cloning and phylogenetic analysis of gene families from amphioxus, tunicates and vertebrates. Comparisons of Hox gene clusters, other homeobox gene families, Wnt genes and insulin-related genes all indicate that there was a major phase of gene duplication close to vertebrate origins, after divergence from the amphioxus lineage; we suggest there was probably a second phase of duplication close to jawed vertebrate origins. From amphioxus and vertebrate homeobox gene expression patterns, we suggest that there are multiple routes by which new genes arising from gene duplication acquire new functions and permit the evolution of developmental innovations.

Mutation and expression studies have implicated the Wnt gene family in early developmental decision making in vertebrates and flies. In a detailed comparative analysis, we have used in situ hybridization of 8.0- to 9.5-day mouse embryos to characterize expression of all ten published Wnt genes in the central nervous system (CNS) and limb buds. Seven of the family members show restricted expression patterns in the brain. At least three genes (Wnt-3, Wnt-3a, and Wnt-7b) exhibit sharp boundaries of expression in the forebrain that may predict subdivisions of the region later in development. In the spinal cord, Wnt-1, Wnt-3, and Wnt-3a are expressed dorsally, Wnt-5a, Wnt-7a, and Wnt-7b more ventrally, and Wnt-4 both dorsally and in the floor plate. In the forelimb primordia, Wnt-3, Wnt-4, Wnt-6 and Wnt-7b are expressed fairly uniformly throughout the limb ectoderm. Wnt-5a RNA is distributed in a proximal to distal gradient through the limb mesenchyme and ectoderm. Along the limb's dorsal-ventral axis, Wnt-5a is expressed in the ventral ectoderm and Wnt-7a in the dorsal ectoderm. We discuss the significance of these patterns of restricted and partially overlapping domains of expression with respect to the putative function of Wnt signalling in early CNS and limb development.

The distinction of anterior versus posterior is a crucial first step in animal embryogenesis. In the fly Drosophila, this axis is established by morphogenetic gradients contributed by the mother that regulate zygotic target genes. This principle has been considered to hold true for insects in general but is fundamentally different from vertebrates, where zygotic genes and Wnt signaling are required. We investigated symmetry breaking in the beetle Tribolium castaneum, which among insects represents the more ancestral short-germ embryogenesis. We found that maternal Tc-germ cell-less is required for anterior localization of maternal Tc-axin, which represses Wnt signaling and promotes expression of anterior zygotic genes. Both RNAi targeting Tc-germ cell-less or double RNAi knocking down the zygotic genes Tc-homeobrain and Tc-zen1 led to the formation of a second growth zone at the anterior, which resulted in double-abdomen phenotypes. Conversely, interfering with two posterior factors, Tc-caudal and Wnt, caused double-anterior phenotypes. These findings reveal that maternal and zygotic mechanisms, including Wnt signaling, are required for establishing embryo polarity and induce the segmentation clock in a short-germ insect.

Early neural patterning in vertebrates involves signals that inhibit anterior (A) and promote posterior (P) positional values within the nascent neural plate. In this study, we have investigated the contributions of, and interactions between, retinoic acid (RA), Fgf and Wnt signals in the promotion of posterior fates in the ectoderm. We analyze expression and function of cyp26/P450RAI, a gene that encodes retinoic acid 4-hydroxylase, as a tool for investigating these events. Cyp26 is first expressed in the presumptive anterior neural ectoderm and the blastoderm margin at the late blastula. When the posterior neural gene hoxb1b is expressed during gastrulation, it shows a strikingly complementary pattern to cyp26. Using these two genes, as well as otx2 and meis3 as anterior and posterior markers, we show that Fgf and Wnt signals suppress expression of anterior genes, including cyp26. Overexpression of cyp26 suppresses posterior genes, suggesting that the anterior expression of cyp26 is important for restricting the expression of posterior genes. Consistent with this, knock-down of cyp26 by morpholino oligonucleotides leads to the anterior expansion of posterior genes. We further show that Fgf- and Wnt-dependent activation of posterior genes is mediated by RA, whereas suppression of anterior genes does not depend on RA signaling. Fgf and Wnt signals suppress cyp26 expression, while Cyp26 suppresses the RA signal. Thus, cyp26 has an important role in linking the Fgf, Wnt and RA signals to regulate AP patterning of the neural ectoderm in the late blastula to gastrula embryo in zebrafish.

ABSTRACT The Wnt/Wg signaling pathway functions during development to regulate cell fate determination and patterning in various organisms. Two pathways are reported to lie downstream of Wnt signaling in vertebrates. The canonical pathway relies on the activation of target genes through the β-catenin–Lef/TCF complex, while the noncanonical pathway employs the activation of protein kinase C (PKC) and increases in intracellular calcium to induce target gene expression. cDNA subtractive hybridization between a cell line that overexpresses Wnt-1 (C57MG/Wnt-1) and the parental cell line (C57MG) was performed to identify downstream target genes of Wnt-1 signaling. Among the putative Wnt-1 target genes, we have identified a mouse homolog of the gene encoding human transcription factor basic transcription element binding protein 2 (mBTEB2). ThemBTEB2 transcript is found at high levels in mammary tissue taken from a transgenic mouse overexpressing Wnt-1 (both tissue prior to active proliferation and tumor tissue) but is barely detectable in wild-type mouse mammary glands. The regulation of mBTEB2 by Wnt-1 signaling in tissue culture occurs through a β-catenin–Lef/TCF-independent mechanism, as it is instead partially regulated by PKC. The Wnt-1-induced, PKC-dependent activation of mouse BTEB2 in C57MG cells, as well as the ability of Wnt-1 to stabilize β-catenin in these cells, is consistent with the hypothesis that both the noncanonical and canonical Wnt pathways are activated concomitantly in the same cell. These results suggest that mBTEB2 is a biologically relevant target of Wnt-1 signaling that is activated through a β-catenin-independent, PKC-sensitive pathway in response to Wnt-1.

The Wnt signaling pathway is important in the formation of neural crest cells in many vertebrates, but the downstream targets of neural crest induction by Wnt are largely unknown. Here, we examined quantitative changes in gene expression regulated by Wnt-mediated neural crest induction using quantitative PCR (QPCR). Induction was recapitulated in vitro by adding soluble Wnt to intermediate neural plate tissue cultured in collagen, and induced versus control tissue were assayed using gene-specific primers at times corresponding to premigratory (18 and 24 h) or early (36 h) stages of crest migration. The results show that Wnt signaling up-regulates in a distinct temporal pattern the expression of several genes normally expressed in the dorsal neural tube (slug, Pax3, Msx1, FoxD3, cadherin 6B) at “premigratory” stages. While slug is maintained in early migrating crest cells, Pax3, FoxD3, Msx1 and cadherin 6B all are down-regulated by the start of migration. These results differ from the temporal profile of these genes in response to the addition of recombinant BMP4, where gene expression seems to be maintained. Interestingly, expression of rhoB is unchanged or even decreased in response to Wnt-mediated induction at all times examined, though it is up-regulated by BMP signals. The temporal QPCR profiles in our culture paradigm approximate in vivo expression patterns of these genes before neural crest migration, and are consistent with Wnt being an initial neural crest inducer with additional signals like BMP and other factors maintaining expression of these genes in vivo. Our results are the first to quantitatively describe changes in gene expression in response to a Wnt or BMP signal during transformation of a neural tube cell into a migratory neural crest cell.

Wnt-1 homologs have been identified in invertebrates and vertebrates and play important roles in cellular differentiation and organization. In Drosophila, the products of the segment polarity genes wingless (the Wnt-1 homolog) and armadillo participate in a signal transduction pathway important for cellular boundary formation in embryonic development, but functional interactions between the proteins are unknown. We have examined Wnt-1 function in mammalian cells in which armadillo (beta-catenin and plakoglobin) is known to bind to and regulate cadherin cell adhesion proteins. We show that Wnt-1 expression results in the accumulation of beta-catenin and plakoglobin. In addition, binding of beta-catenin to the cell adhesion protein, cadherin, is stabilized, resulting in a concomitant increase in the strength of calcium-dependent cell-cell adhesion. Thus, a consequence of the functional interaction between Wnt-1 and armadillo family members is the strengthening of cell-cell adhesion, which may lead to the specification of cellular boundaries.

During embryonic development in vertebrates, morphogens play an important role in cell fate determination and morphogenesis. Bone morphogenetic proteins (BMPs) belonging to the transforming growth factor-β (TGF-β) family control the dorsal–ventral (DV) patterning of embryos, whereas other morphogens such as fibroblast growth factor (FGF), Wnt family members, and retinoic acid (RA) regulate the formation of the anterior–posterior (AP) axis. Activation of morphogen signaling results in changes in the expression of target genes including transcription factors that direct cell fate along the body axes. To ensure the correct establishment of the body plan, the processes of DV and AP axis formation must be linked and coordinately regulated by a fine-tuning of morphogen signaling. In this review, we focus on the interplay of various intracellular regulatory mechanisms and discuss how communication among morphogen signaling pathways modulates body axis formation in vertebrate embryos.

The Hox genes play a central role in patterning the embryonic anterior-to-posterior axis. An important function of Hox activity in vertebrates is the specification of different vertebral morphologies, with an additional role in axis elongation emerging. The miR-196 family of microRNAs (miRNAs) are predicted to extensively target Hox 3′ UTRs, although the full extent to which miR-196 regulates Hox expression dynamics and influences mammalian development remains to be elucidated. Here we used an extensive allelic series of mouse knockouts to show that the miR-196 family of miRNAs is essential both for properly patterning vertebral identity at different axial levels and for modulating the total number of vertebrae. All three miR-196 paralogs, 196a1, 196a2, and 196b, act redundantly to pattern the midthoracic region, whereas 196a2 and 196b have an additive role in controlling the number of rib-bearing vertebra and positioning of the sacrum. Independent of this, 196a1, 196a2, and 196b act redundantly to constrain total vertebral number. Loss of miR-196 leads to a collective up-regulation of numerous trunk Hox target genes with a concomitant delay in activation of caudal Hox genes, which are proposed to signal the end of axis extension. Additionally, we identified altered molecular signatures associated with the Wnt, Fgf, and Notch/segmentation pathways and demonstrate that miR-196 has the potential to regulate Wnt activity by multiple mechanisms. By feeding into, and thereby integrating, multiple genetic networks controlling vertebral number and identity, miR-196 is a critical player defining axial formulae.

Deuterostomes are a monophyletic group of animals that include the vertebrates, invertebrate chordates, ambulacrarians and xenoturbellids. Fossil representatives from most major deuterostome groups, including some phylum-level crown groups, are found in the Lower Cambrian, suggesting that evolutionary divergence occurred in the Late Precambrian, in agreement with some molecular clock estimates. Molecular phylogenies, larval morphology and the adult heart/kidney complex all support echinoderms and hemichordates as a sister grouping (Ambulacraria). Xenoturbellids are a relatively newly discovered phylum of worm-like deuterostomes that lacks a fossil record, but molecular evidence suggests that these animals are a sister group to the Ambulacraria. Within the chordates, cephalochordates share large stretches of chromosomal synteny with the vertebrates, have a complete Hox complex and are sister group to the vertebrates based on ribosomal and mitochondrial gene evidence. In contrast, tunicates have a highly derived adult body plan and are sister group to the vertebrates based on the analyses of concatenated genomic sequences. Cephalochordates and hemichordates share gill slits and an acellular cartilage, suggesting that the ancestral deuterostome also shared these features. Gene network data suggest that the deuterostome ancestor had an anterior–posterior body axis specified by Hox and Wnt genes, a dorsoventral axis specified by a BMP/chordin gradient, and was bilaterally symmetrical with left–right asymmetry determined by expression of nodal .

Orientadores: Lucia Elvira Alvares, Jose Xavier Neto
Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Biologia
Made available in DSpace on 2018-08-13T10:17:43Z (GMT). No. of bitstreams: 1 Sobreira_DeboraRodrigues_M.pdf: 2481929 bytes, checksum: 2cb1105ccc78322b5f11f4528108d2fc (MD5) Previous issue date: 2009
Resumo: Splicing Alternativo é um mecanismo importante para expandir a diversidade protéica em eucariotos. Este processo permite a produção de diferentes mRNAs a partir de uma mesma molécula de pré-RNA e é freqüentemente utilizado pelos genes envolvidos no desenvolvimento embrionário. O gene Oapper1 (Opr1) é um importante modulador da via de sinalização Wnt, atuando em diversos processos como especificação do tecido neural, morfogênese cefálica e desenvolvimento do coração e olho. Entre seus parceiros estão as '1lOléculas Dishevelled, o fator de transcrição TCF-3 (ambas as moléculas envolvidas na sinalização Wnt) e Dbf-4 (regulador do ciclo celular). Considerando que Dpr1 possui uma estrutura modular e interage com diferentes parceiros moleculares através de diferentes domínios estruturais, esta molécula poderia utilizar a maquinaria de Splicing Alternativo para combinar diferentes domínios e conseqüentemente ampliar suas funções biológicas. Neste estudo, descrevemos uma nova Variante do gene Opr1, identificada inicialmente no transcriptoma de camundongo utilizando ferramentas de Bioinformática. Esta nova Variante é maior em 111 pb em relação à codificada pela seqüência referência de RNAm para Dpr1 RefSeq, as quais são denominadas, respectivamente, como Variante A e Variante B. Estes transcritos variantes são gerados por dois sítios aceptores de Splicing distintos presentes no início do exon 4. O segmento exclusivo da Variante A codifica 37 aminoácidos localizados na região onde Opr1 se associa ao fator transcricional TCF-3. Uma análise comparativa do lócus de Opr1 entre diversos vertebrados (peixe, anfíbio, galinha, camundongo e humano) revelou que ambos os sítios aceptores de Splicing são conservados nos tetrápodas, enquanto que em peixe apenas um sítio é encontrado. Ensaios de RT-PCR confirmaram nossos resultados obtidos em Bioinformática. Além disso, demonstramos que ambas as Variantes são co-expressas ao longo do desenvolvimento de galinha, sugerindo que a concentração relativa dessas moléculas pode ser importante para a sua função. Finalmente, análises de pressão seletiva foram realizadas para a molécula de Dpr1. Apesar de não se confirmar a presença de seleção positiva ao longo da proteína Dpr1, o exon 4 parece estar sob pressão seletiva mais relaxada quando comparado aos outros exons. Nossos resultados são consistentes com a hipótese de que o mecanismo de Splicing Alternativo atua acelerando a evolução, reduzindo a seleção negativa.
Abstract: Alternative splicing is an important mechanism to expand protein diversity in eukaryotes. This process allows the production of different mRNAs from a single coding sequence and is frequentfy used by genes involved in development. Oapper 1 (Opr1) is an important rnodulator of Wnt signalling, working in several developmental processes, such as neural tissue specification, head morphogenesis, heart and eye development. While its interaction with Oishevelled is known to modulate Wnt signalling both in vivo and in vitre, the interaction wrth other molecules is required to mediate its multiple biological functions. Considering that Dpr1 has a modular structure that mediates its interaction with different partners through different structural domains, this molecule could greatly benefit from alternative splicing in order to combine different domains and consequently amplify its biological functions. In the present study we describe a new Opr1 isoform that was initially identified in the mouse transcriptome using bioinformatic tools. This isoform is 111 pb longer than the one encoded by the RefSeq mRNA for Opr1, here named O and E isoforms, respectively. The variant transcripts are generated through two distinct acceptor splice sites in exon 4. The segment exclusive of the O isoform is in frame and encodes 37 residues located in a variable region of Oprl exon 4, known to be necessary for the interaction with the transcriptional factor Tcf3. comparative analysis of the Opr1 locus among fish, frog, chicken, mouse and human revealed that in tetrapods two acceptor splice sites are conserved in the beginning of the exon 4, while in fish a single acceptor splice site is found. RT-PCR using species-specific primers confirmed the expression of the O and E isoforms in tetrapods while in fish only the O isoform was detected. In addition, we showed that the Opr1 isoforms are coexpressed throughout chicken development, suggesting that the relative concentration of these molecules may be important for their functionality. Finally, even though no evidence of positive selection was detected for the entire Dpr1 protein, exon 4 seems to be under more relaxed selective pressure than the other exons. These results are consistent with the notion that alternative splicing can act as a mechanism for opening accelerated paths of evolution by reducing negative selection pressure.
Mestrado
Histologia
Mestre em Biologia Celular e Estrutural

Orientador: Lúcia Elvira Alvares
Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Biologia
Made available in DSpace on 2018-08-24T17:37:00Z (GMT). No. of bitstreams: 1 Pedrosa_AngelicaVasconcelos_M.pdf: 1992620 bytes, checksum: ed7d02568860e3ccf1e489cf2928818e (MD5) Previous issue date: 2013
Resumo: A correta padronização do corpo do embrião requer a atividade de diferentes vias de sinalização. Dentre elas, uma que se destaca é via de sinalização Wnt de polaridade celular planar (Wnt/PCP), que é responsável pelo controle da polaridade celular e pela organização celular de diversos tecidos nos animais. Uma vez interrompida, a via Wnt/PCP pode causar falhas no fechamento do tubo neural, provocando defeitos congênitos. Em seres humanos, mutações em componentes-chave da via Wnt/PCP como as proteínas codificadas pelos genes Vangl1 e Vangl2 têm sido associadas à graves malformações geradas por falhas no fechamento do tubo neural. Estruturalmente, ambos os genes Vangl1 e Vangl2 codificam proteínas de superfície transmembranares, essenciais para o desenvolvimento apropriado do embrião. O presente trabalho teve como objetivo a caracterização do padrão de expressão dos genes Vangl1 e Vangl2 durante a embriogênese de Gallus gallus. Ensaios de hibridação in situ em embrião inteiro (whole mount) e cortes em vibratómo foram realizados com a finalidade de estabelecer temporal e espacialmente o padrão de expressão dos genes Vangl1 e Vangl2. Como resultado, observou-se que estes genes são expressos durante as etapas de gastrulação, neurulação e no início da organogênese do desenvolvimento embrionário de Gallus gallus. No início da gastrulação, os genes Vangl1 e Vangl2 possuem domínios de expressão comuns nos embriões de galinha, uma vez que ambos são expressos na linha primitiva, nódulo de Hensen e crescente cardiogênico. Contudo, nossos dados revelaram particularidades na expressão destes genes, uma vez que há uma predominância dos transcritos de Vangl1 na região posterior da linha primitiva, enquanto Vangl2 apresenta uma expressão uniforme ao longo desta estrutura. Em adição, enquanto Vangl1 é expresso na notocorda e em toda a extensão do nódulo de Hensen, Vangl2 é expresso no entorno desta estrutura. Ao longo da neurulação e na organogênese inicial, ambos os genes Vangl são expressos de maneira similar, em domínios que abrangem a placa, as pregas e o tubo neural. Outros importantes domínios de expressão dos Vangl correspondem às vesículas ópticas e óticas, às vesículas encefálicas particularmente na região das flexuras encefálicas, aos diferentes tipos de mesoderma (paraxial, intermediário e lateral) e ao assoalho da faringe. Ao comparar os resultados obtidos por hibridação in situ em galinha ao um levantamento bibliográfico sobre outros vertebrados, observou-se uma sobreposição dos domínios-chave de expressão nos diferentes organismos, demonstrando a conservação filogenética da atividade destes genes e sugerindo uma possível conservação funcional. Desta forma, nossos dados sugerem que os genes Vangl desempenham um importante papel no desenvolvimento embrionário de aves, possivelmente coordenando os movimentos morfogenéticos durante a gastrulação, bem como a formação da placa neural e posterior dobramento e fechamento do tubo neural, além de outros processos da embriogênese de aves
Abstract: The correct patterning of the embryo's body requires the activity of different signaling pathways. Among them, one that stands out is the Wnt Planar Cell Polarity Signaling Pathway (Wnt/PCP), which is responsible for controlling the cell polarity and cellular organization of many tissues in animals. Failures in the Wnt/PCP signaling can cause neural tube birth defects. In humans, mutations in key components of the Wnt/PCP as the Vangl1 and Vangl2 molecules were identified in patients with neural tube defects. Structurally, both Vangl1 and Vangl2 genes encode transmembrane surface proteins similar, which are essential to proper development. The present study aimed to characterize the expression pattern of Vangl1 and Vangl2 genes during embryogenesis in Gallus gallus. Whole-mount in situ hybridization assays and vibratome sectioning of embryos were conducted in order to establish the spatial and temporal expression pattern of Vangl1 and Vangl2 genes. Our results showed that these genes are expressed during gastrulation, neurulation and early organogenesis in Gallus gallus. At the onset of Gastrulation, Vangl1 and Vangl2 genes have common areas of expression in chicken embryos, since both are expressed in the primitive streak, Hensen's node and cardiogenic crescent. However, our data showed particularities in the expression of these genes, since there is a predominance of Vangl1 transcripts in the posterior region of the primitive streak while Vangl2 has a uniform expression throughout that structure. In addition, while Vangl1 is expressed in the notochord and in the full length of the Hensen's node, Vangl2 is expressed only around this structure. Throughout neurulation and early organogenesis, both Vangl genes are expressed in a similar manner on the neural plate, neural groove, neural folds and in the neural tube. Other important areas of Vangl expression correspond to optical and otic vesicles, the brain vesicles, the different types of mesoderm (paraxial, intermediate and lateral) and the floor of the pharynx. By comparing the chicken expression of Vangl genes with other vertebrates, we notice that there are overlapping expression patterns among key areas among different organisms, showing a phylogenetic conservation of expression domains and suggesting a possible functional conservation. Overall, our data suggests that Vangl genes play an important role in embryonic development of bird, possibly by coordinating the morphogenetic movements during gastrulation, as well as the formation of neural tube, among other processes during the birds embriogenesis
Mestrado
Biologia Celular
Mestra em Biologia Celular e Estrutural