Arturo C. Verrotti scite author profile

In Drosophila, the product of the fs (2)cup gene (Cup) is known to be crucial for diverse aspects of female germ-line development. Its functions at the molecular level, however, have remained mainly unexplored. Cup was found to directly associate with eukaryotic translation initiation factor 4E (eIF4E). In this report, we show that Cup is a nucleocytoplasmic shuttling protein and that the interaction with eIF4E promotes retention of the Cup protein in the cytoplasm. Cup is required for the correct accumulation and localization of eIF4E within the posterior cytoplasm of developing oocytes. We furthermore show that cup and eIF4E interact genetically, because a reduction in the level of eIF4E activity deteriorates the development and growth of ovaries bearing homozygous cup mutant alleles. Our results reveal a crucial role for the Cup-eIF4E complex in ovary-specific developmental programs.ovary development ͉ translational regulation ͉ oogenesis

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RAS residues that are distant from the GDP binding site play a critical role in dissociation factor-stimulated release of GDP.

Verrotti

Créchet

Blasi

et al. 1992

The EMBO Journal

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We have previously shown that a conserved glycine at position 82 of the yeast RAS2 protein is involved in the conversion of RAS proteins from the GDP‐ to the GTP‐bound form. We have now investigated the role of glycine 82 and neighbouring amino acids of the distal switch II region in the physiological mechanism of activation of RAS. We have introduced single and double amino acid substitutions at positions 80–83 of the RAS2 gene, and we have investigated the interaction of the corresponding proteins with a yeast GDP dissociation stimulator (SDC25 C‐domain). Using purified RAS proteins, we have found that the SDC25‐stimulated conversion of RAS from the GDP‐bound inactive state to the GTP‐bound active state was severely impaired by amino acid substitutions at positions 80–81. However, the rate and the extent of conversion from the GDP‐ to the GTP‐bound form in the absence of dissociation factor was unaffected. The insensitivity of the mutated proteins to the dissociation factor in vitro was paralleled by an inhibitory effect on growth in vivo. The mutations did not significantly affect the interaction of RAS with adenylyl cyclase. These findings point to residues 80–82 as important determinants of the response of RAS to GDP dissociation factors. This suggests a molecular model for the enhancement of nucleotide release from RAS by such factors.

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Translational regulation during oogenesis and early development: The cap-poly(A) tail relationship

Piccioni

Zappavigna

Verrotti

2005

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Metazoans rely on the regulated translation of select maternal mRNAs to control oocyte maturation and the initial stages of embryogenesis. These transcripts usually remain silent until their translation is temporally and spatially required during early development. Different translational regulatory mechanisms, varying from cytoplasmic polyadenylation to localization of maternal mRNAs, have evolved to assure coordinated initiation of development. A common feature of these mechanisms is that they share a few key trans-acting factors. Increasing evidence suggest that ubiquitous conserved mRNA-binding factors, including the eukaryotic translation initiation factor 4E (eIF4E) and the cytoplasmic polyadenylation element binding protein (CPEB), interact with cell-specific molecules to accomplish the correct level of translational activity necessary for normal development. Here we review how capping and polyadenylation of mRNAs modulate interaction with multiple regulatory factors, thus controlling translation during oogenesis and early development. To cite this article: F.

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Evolutionary conservation of sequence elements controlling cytoplasmic polyadenylylation.

Verrotti

Thompson²,

Wreden³

et al. 1996

Proc. Natl. Acad. Sci. U.S.A.

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Cytoplasmic polyadenylylation is an evolutionarily conserved mechanism involved in the translational activation of a set of maternal messenger RNAs (mRNAs) during early development. In this report, we show by interspecies injections that Xenopus and mouse use the same regulatory sequences to control cytoplasmic poly(A) addition during meiotic maturation. Similarly, Xenopus and Drosophila embryos exploit functionally conserved signals to regulate polyadenylylation during early post-fertilization development.These experiments demonstrate that the sequence elements that govern cytoplasmic polyadenylylation, and hence one form of translational activation, function across species. We infer that the requisite regulatory sequence elements, and likely the trans-acting components with which they interact, have been conserved since the divergence of vertebrates and arthropods.

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