Identification of post-transcriptionally regulated Xenopus tropicalis maternal mRNAs by microarray

Cytoplasmic control of the adenylation state of mRNAs is a critical post-transcriptional process involved in the regulation of mRNAs stability and translational efficiency. The early development of Xenopus laevis has been a major model for the study of such regulations. We describe here a microarray analysis to identify mRNAs that are regulated by changes in their adenylation state during oogenesis and early development of the diploid frog Xenopus tropicalis. The microarray data were validated using qRT–PCR and direct analysis of the adenylation state of endogenous maternal mRNAs during the period studied. We identified more than 500 mRNAs regulated at the post-transcriptional level among the 3000 mRNAs potentially detected by the microarray. The mRNAs were classified into nine different adenylation behavior categories. The various adenylation profiles observed during oocyte maturation and early development and the analyses of 3′-untranslated region sequences suggest that previously uncharacterized sequence elements control the adenylation behavior of the newly identified mRNAs. These data should prove useful in identifying mRNAs with important functions during oocyte maturation and early development

Post-transcriptional regulation in Xenopus embryos: role and targets of EDEN-BP.

International audienceEDEN (embryo deadenylation element)-dependent deadenylation is a regulatory process that was initially identified in Xenopus laevis early embryos and was subsequently shown to exist in Drosophila oocytes. Recent data showed that this regulatory process is required for somitic segmentation in Xenopus. Inactivation of EDEN-BP (EDEN-binding protein) causes severe segmentation defects, and the expression of segmentation markers in the Notch signalling pathway is disrupted. We showed that the mRNA encoding XSu(H) (Xenopus suppressor of hairless), a protein central to the Notch pathway, is regulated by EDEN-BP. Our data also indicate that other segmentation RNAs are targets for EDEN-BP. To identify new EDEN-BP targets, a microarray analysis has been undertaken

Ptbp1 and Exosc9 knockdowns trigger skin stability defects through different pathways

AbstractIn humans, genetic diseases affecting skin integrity (genodermatoses) are generally caused by mutations in a small number of genes that encode structural components of the dermal–epidermal junctions. In this article, we first show that inactivation of both exosc9, which encodes a component of the RNA exosome, and ptbp1, which encodes an RNA-binding protein abundant in Xenopus embryonic skin, impairs embryonic Xenopus skin development, with the appearance of dorsal blisters along the anterior part of the fin. However, histological and electron microscopy analyses revealed that the two phenotypes are distinct. Exosc9 morphants are characterized by an increase in the apical surface of the goblet cells, loss of adhesion between the sensorial and peridermal layers, and a decrease in the number of ciliated cells within the blisters. Ptbp1 morphants are characterized by an altered goblet cell morphology. Gene expression profiling by deep RNA sequencing showed that the expression of epidermal and genodermatosis-related genes is also differentially affected in the two morphants, indicating that alterations in post-transcriptional regulations can lead to skin developmental defects through different routes. Therefore, the developing larval epidermis of Xenopus will prove to be a useful model for dissecting the post-transcriptional regulatory network involved in skin development and stability with significant implications for human diseases

Identification of CUG-BP1/EDEN-BP target mRNAs in Xenopus tropicalis

The early development of many animals relies on the posttranscriptional regulations of maternally stored mRNAs. In particular, the translation of maternal mRNAs is tightly controlled during oocyte maturation and early mitotic cycles in Xenopus. The Embryonic Deadenylation ElemeNt (EDEN) and its associated protein EDEN-BP are known to trigger deadenylation and translational silencing to several mRNAs bearing an EDEN. This Xenopus RNA-binding protein is an ortholog of the human protein CUG-BP1/CELF1. Five mRNAs, encoding cell cycle regulators and a protein involved in the notch pathway, have been identified as being deadenylated by EDEN/EDEN-BP. To identify new EDEN-BP targets, we immunoprecipitated EDEN-BP/mRNA complexes from Xenopus tropicalis egg extracts. We identified 153 mRNAs as new binding targets for EDEN-BP using microarrays. Sequence analyses of the 3′ untranslated regions of the newly identified EDEN-BP targets reveal an enrichment in putative EDEN sequences. EDEN-BP binding to a subset of the targets was confirmed both in vitro and in vivo. Among the newly identified targets, Cdk1, a key player of oocyte maturation and cell cycle progression, is specifically targeted by its 3′ UTR for an EDEN-BP-dependent deadenylation after fertilization

DHX15-independent roles for TFIP11 in U6 snRNA modification, U4/U6.U5 tri-snRNP assembly and pre-mRNA splicing fidelity

International audienceThe U6 snRNA, the core catalytic component of the spliceosome, is extensively modified post-transcriptionally, with 2’-O-methylation being most common. However, how U6 2’-O-methylation is regulated remains largely unknown. Here we report that TFIP11, the human homolog of the yeast spliceosome disassembly factor Ntr1, localizes to nucleoli and Cajal Bodies and is essential for the 2’-O-methylation of U6. Mechanistically, we demonstrate that TFIP11 knockdown reduces the association of U6 snRNA with fibrillarin and associated snoRNAs, therefore altering U6 2′-O-methylation. We show U6 snRNA hypomethylation is associated with changes in assembly of the U4/U6.U5 tri-snRNP leading to defects in spliceosome assembly and alterations in splicing fidelity. Strikingly, this function of TFIP11 is independent of the RNA helicase DHX15, its known partner in yeast. In sum, our study demonstrates an unrecognized function for TFIP11 in U6 snRNP modification and U4/U6.U5 tri-snRNP assembly, identifying TFIP11 as a critical spliceosome assembly regulator

Xenopus Resources: Transgenic, Inbred and Mutant Animals, Training Opportunities, and Web-Based Support

Two species of the clawed frog family, Xenopus laevis and X. tropicalis, are widely used as tools to investigate both normal and disease-state biochemistry, genetics, cell biology, and developmental biology. To support both frog specialist and non-specialist scientists needing access to these models for their research, a number of centralized resources exist around the world. These include centers that hold live and frozen stocks of transgenic, inbred and mutant animals and centers that hold molecular resources. This infrastructure is supported by a model organism database. Here, we describe much of this infrastructure and encourage the community to make the best use of it and to guide the resource centers in developing new lines and libraries

Post-transcriptional regulation in cancer

International audienceDeregulation of gene expression is a hallmark of the cancer cell. Acquiring a new profile of expressed proteins may enable the cell to re-enter the cell cycle, or give them a growth or motility advantage over "normal cells". An efficient and rapid way to alter gene expression is via regulation of mRNAs already transcribed. Modifications of mRNA stability and/or translational efficiency are increasingly reported in cancer. mRNA stability and translation are controlled through a complex network of RNA/protein interactions involving recognition of specific target mRNAs by RNA-BPs. We review how alterations in regulatory sequences, RNA-BPs, or in upstream signalling pathways affect the stability and/or translational efficiency of mRNAs encoding proto-oncogenes, cytokines, cell cycle regulators and other regulatory proteins to promote tumorigenesis and cancer progression. A more thorough understanding of post-transcriptional mechanisms such as these will enable the design and development of specific therapies based on modulating the translation or stability of specific mRNAs

Étude des protéines de liaison à l'ARN des familles PTB et ARE-BP au cours du développement chez le xénope

Mes travaux ont porté sur l'étude de deux familles de protéines de liaison à l'ARN, la famille des ARE-BP (AU-rich elements binding protein) et la famille des PTB (Polypyrimidine tract binding protein) au cours du développement chez le xénope. L'étude de l'expression de cinq membres de la famille ARE-BP a mis en évidence une redondance d'expression tissulaire et temporelle entre quatre de ces ARE-BP (AUF1, KSRP, HuR et TIA1). A l'inverse, l'expression atypique de TTP a permis de suggérer son implication dans l'hématopoïèse. Mes travaux sur la famille PTB (PTBP1, PTBP2, PTBP3) ont montré que chacun des paralogues présente une expression spécifique ce qui suggère qu'elles aient des fonctions différentes lors du développement. Des résultats du laboratoire montraient que l'inactivation de PTBP1 ou de EXOSC9, un composant de l'exosome ARN, entraînait des défauts de morphogenèse de l'épiderme dorsal. Afin d'identifier l'origine moléculaire de ces défauts, j'ai réalisé l'analyse transcriptomique par séquençage à haut débit (RNA-Seq) des morphants PTBP1 et EXOSC9. J'ai produit des banques d'ADNc à partir des morphants ou d'embryons témoins et celles-ci ont été séquencées au Génoscope. L'analyse d'une cible connue de PTBP1 a montré que des modifications minoritaires de l'épissage étaient détectées à partir de ces données. De plus ces défauts d'épissage ne sont pas retrouvés dans les morphants EXOSC9, validant son utilisation comme crible additionnel permettant d'exclure les évènements d'épissage qui ne sont pas impliqués dans le défaut d'épiderme. Une approche gène candidat a été initiée afin de cibler l'analyse de transcrits impliqués dans la morphogenèse de l'épiderme dorsale.My work has focused on the function of RNA binding-proteins during early development in Xenopus. I first documented the expression pattern of members of the AU-rich element binding protein (ARE-BP) and of the polypyrimidin tract binding protein (PTB) families during development. Study of the expression patterns of five members of the ARE-BP family (AUF1, KSRP, HuR, TIA1 and TTP) has underlined the broad role and the redundancy of expression of four of these proteins. Conversely, the highly specific expression pattern of TTP in macrophages suggests a potential function for this ARE-BP in hematopoietic development. My study of the PTB family (PTBP1, PTBP2 and PTBP3), has showed that each paralog presents a unique pattern of expression emphasizing their diverse functions during development. From previous work in the lab we knew that morpholino mediated knockdown of both PTBP1 and EXOSC9, a component of the RNA exosome, generated similar defects in the dorsal fin morphology. To identify the molecular origin of these defects we realized the transcriptome analysis by high throughput sequencing (RNA-Seq) of both morphants embryos. I produced cDNA libraries of control and morphant embryos and the sequencing was performed at the Genoscope. Analysis of a known PTBP1 target showed that even modest modifications of alternative splicing could be detected in our data sets. In addition, because these defects are not found in the EXOSC9 morphants it validated its use as an additional screen to exclude splicing events not involved in the epidermal defects. Identification of RNA whose deregulation may be involved in the fin phenotype is currently under study for a set of candidate genes.RENNES1-BU Sciences Philo (352382102) / SudocSudocFranceF

Expression analysis of the polypyrimidine tract binding protein (PTBP1) and its paralogs PTBP2 and PTBP3 during Xenopus tropicalis embryogenesis.

International audienceThe PTB (polypyrimidine tract binding protein) family of RNA-binding proteins plays a critical role in development through the regulation of post-transcriptional events. We have determined expression patterns of the three members of this gene family ptbp1, ptbp2 and ptbp3 during Xenopus tropicalis embryogenesis using whole-mount in situ hybridization. Our results show that each paralog presents a unique pattern of expression. ptbp1 is the prevalent maternal mRNA and is differentially expressed in the three germ layers. Later in development, it is widely expressed in the embryo including the epidermis, the dermatome, the intermediate mesoderm, the lateral plate mesoderm and the neural crest. ptbp2 expression is restricted to the nervous system including the brain, the neural retina and the spinal cord and the intermediate mesoderm. In addition to being expressed in erythroid precursors, ptbp3 is present in specific subdomains of the brain and the spinal cord, as well as in the posterior part of the notochord, suggesting it may play a role in the patterning of the nervous system. In the eye, each of the three genes is expressed in a specific structure which emphasizes their non-redundant function during development. Strickingly, our experiments also revealed that none of the three paralogs was expressed in the myotome, suggesting that the absence of PTB activity is a key determinant to display myotomal splicing patterns