Claire Pujol

Bio: Claire Pujol is an academic researcher from Centre national de la recherche scientifique. The author has contributed to research in topics: Transfer RNA & Gene. The author has an hindex of 5, co-authored 5 publications receiving 339 citations. Previous affiliations of Claire Pujol include Louis Pasteur University.

Import of tRNAs and aminoacyl-tRNA synthetases into mitochondria.

Abstract: During evolution, most of the bacterial genes from the ancestral endosymbiotic α-proteobacteria at the origin of mitochondria have been either lost or transferred to the nuclear genome. A crucial evolutionary step was the establishment of macromolecule import systems to allow the come back of proteins and RNAs into the organelle. Paradoxically, the few mitochondria-encoded protein genes remain essential and must be translated by a mitochondrial translation machinery mainly constituted by nucleus-encoded components. Two crucial partners of the mitochondrial translation machinery are the aminoacyl-tRNA synthetases and the tRNAs. All mitochondrial aminoacyl-tRNA synthetases and many tRNAs are imported from the cytosol into the mitochondria in eukaryotic cells. During the last few years, their origin and their import into the organelle have been studied in evolutionary distinct organisms and we review here what is known in this field.

Dual-targeted tRNA-dependent amidotransferase ensures both mitochondrial and chloroplastic Gln-tRNAGln synthesis in plants

Abstract: Aminoacyl-tRNAs are generally formed by direct attachment of an amino acid to tRNAs by aminoacyl-tRNA synthetases, but Gln-tRNA is an exception to this rule. Gln-tRNAGln is formed by this direct pathway in the eukaryotic cytosol and in protists or fungi mitochondria but is formed by an indirect transamidation pathway in most of bacteria, archaea, and chloroplasts. We show here that the formation of Gln-tRNAGln is also achieved by the indirect pathway in plant mitochondria. The mitochondrial-encoded tRNAGln, which is the only tRNAGln present in mitochondria, is first charged with glutamate by a nondiscriminating GluRS, then is converted into Gln-tRNAGln by a tRNA-dependent amidotransferase (AdT). The three subunits GatA, GatB, and GatC are imported into mitochondria and assemble into a functional GatCAB AdT. Moreover, the mitochondrial pathway of Gln-tRNAGln formation is shared with chloroplasts as both the GluRS, and the three AdT subunits are dual-imported into mitochondria and chloroplasts.

Characterization of Arabidopsis thaliana genes encoding functional homologues of the yeast metal chaperone Cox19p, involved in cytochrome c oxidase biogenesis

Abstract: The Arabidopsis thaliana genome contains two nearly identical genes which encode proteins showing similarity with the yeast metal chaperone Cox19p, involved in cytochrome c oxidase biogenesis. One of these genes (AtCOX19-1) produces two transcript forms that arise from an alternative splicing event and encode proteins with different N-terminal portions. Both AtCOX19 isoforms are imported into mitochondria in vitro and are found attached to the inner membrane facing the intermembrane space. The smaller AtCOX19-1 isoform, but not the larger one, is able to restore growth on non-fermentable carbon sources when expressed in a yeast cox19 null mutant. AtCOX19 transcript levels increase by treatment with copper or compounds that produce reactive oxygen species. Young roots and anthers are highly stained in AtCOX19-1::GUS plants. Expression in leaves is only observed when cuts are produced, suggesting an induction by wounding. Infection of plants with the pathogenic bacterium Pseudomonas syringae pv. tomato also induces AtCOX19 gene expression. The results suggest that AtCOX19 genes encode functional homologues of the yeast metal chaperone. Induction by biotic and abiotic stress factors may indicate a relevant role of this protein in the biogenesis of cytochrome c oxidase to replace damaged forms of the enzyme or a more general role in the response of plants to stress.

Organization and regulation of mitochondrial respiration in plants.

Abstract: Mitochondrial respiration in plants provides energy for biosynthesis, and its balance with photosynthesis determines the rate of plant biomass accumulation. We describe recent advances in our understanding of the mitochondrial respiratory machinery of cells, including the presence of a classical oxidative phosphorylation system linked to the cytosol by transporters, discussed alongside nonphosphorylating (and, therefore, non-energy conserving) bypasses that alter the efficiency of ATP synthesis and play a role in oxidative stress responses in plants. We consider respiratory regulation in the context of the contrasting roles mitochondria play in different tissues, from photosynthetic leaves to nutrient-acquiring roots. We focus on the molecular nature of this regulation at transcriptional and post-transcriptional levels that allow the respiratory apparatus of plants to help shape organ development and the response of plants to environmental stress. We highlight the challenges for future research considerin...

Facing the challenges of Cu, Fe and Zn homeostasis in plants

Abstract: Plants have recently moved into the spotlight owing to the growing realization that the world needs solutions to energy and food production that are sustainable and environmentally sound. Iron, copper and zinc are essential for plant growth and development, yet the same properties that make these transition metals indispensable can also make them deadly in excess. Iron and copper are most often used for their redox properties, whereas zinc is primarily used for its ability to act as a Lewis acid. Here we review recent advances in the field of metal homeostasis and integrate the findings on uptake and transport of these three metals.

Detecting sequence signals in targeting peptides using deep learning.

Abstract: In bioinformatics, machine learning methods have been used to predict features embedded in the sequences. In contrast to what is generally assumed, machine learning approaches can also provide new insights into the underlying biology. Here, we demonstrate this by presenting TargetP 2.0, a novel state-of-the-art method to identify N-terminal sorting signals, which direct proteins to the secretory pathway, mitochondria, and chloroplasts or other plastids. By examining the strongest signals from the attention layer in the network, we find that the second residue in the protein, that is, the one following the initial methionine, has a strong influence on the classification. We observe that two-thirds of chloroplast and thylakoid transit peptides have an alanine in position 2, compared with 20% in other plant proteins. We also note that in fungi and single-celled eukaryotes, less than 30% of the targeting peptides have an amino acid that allows the removal of the N-terminal methionine compared with 60% for the proteins without targeting peptide. The importance of this feature for predictions has not been highlighted before.

Genomic and biochemical insights into the specificity of ETS transcription factors.

Abstract: ETS proteins are a group of evolutionarily related, DNA-binding transcriptional factors. These proteins direct gene expression in diverse normal and disease states by binding to specific promoters and enhancers and facilitating assembly of other components of the transcriptional machinery. The highly conserved DNA-binding ETS domain defines the family and is responsible for specific recognition of a common sequence motif, 5 � -GGA(A/T)-3 � . Attaining specificity for biological regulation in such a family is thus a conundrum. We present the current knowledge of routes to functional diversity and DNA binding specificity, including divergent properties of the conserved ETS and PNT domains, the involvement of flanking structured and unstructured regions appended to these dynamic domains, posttranslational modifications, and protein partnerships with other DNA-binding proteins and coregulators. The review emphasizes recent advances from biochemical and biophysical approaches, as well as insights from genomic studies that detect ETSfactor occupancy in living cells.