Subcellular mRNA localization regulates ribosome biogenesis in migrating cells

Dermit et al. reveal that ribosomal protein (RP)-mRNAs localize to the protrusive fronts of migratory cells, where their translation is locally increased, leading to upregulation of ribosome biogenesis and protein synthesis. In aggressive carcinomas, this pathway is upregulated in order to support the high anabolic demands of invasive cancer cells

Graphene-Based Nanocomposites for Energy Storage

Since the first report of using micromechanical cleavage method to produce graphene sheets in 2004, graphene/graphene-based nanocomposites have attracted wide attention both for fundamental aspects as well as applications in advanced energy storage and conversion systems. In comparison to other materials, graphene-based nanostructured materials have unique 2D structure, high electronic mobility, exceptional electronic and thermal conductivities, excellent optical transmittance, good mechanical strength, and ultrahigh surface area. Therefore, they are considered as attractive materials for hydrogen (H2) storage and high-performance electrochemical energy storage devices, such as supercapacitors, rechargeable lithium (Li)-ion batteries, Li–sulfur batteries, Li–air batteries, sodium (Na)-ion batteries, Na–air batteries, zinc (Zn)–air batteries, and vanadium redox flow batteries (VRFB), etc., as they can improve the efficiency, capacity, gravimetric energy/power densities, and cycle life of these energy storage devices. In this article, recent progress reported on the synthesis and fabrication of graphene nanocomposite materials for applications in these aforementioned various energy storage systems is reviewed. Importantly, the prospects and future challenges in both scalable manufacturing and more energy storage-related applications are discussed

Aminoacyl-ARNt synthétases mitochondriales humaines : aspects fondamentaux et contribution à la compréhension de pathologies reliées

Aminoacyl-tRNA synthetases (aaRSs) are housekeeping enzymes involved in translation. In human cells, 2 different sets of nuclear genes code for aaRSs. One codes for cytosolic (cyt) aaRSs, and the second one codes for aaRSs of mitochondrial (mt) location. Mt-aaRSs are translated in the cytosol, targeted and imported into mitochondria.Mutations in 9 mt-aaRSs have been described. Some of the mutations do not display significant influence on the housekeeping aminoacylation activity. It has been proposed that those mutations affect alternative functions.Alternate functions have been described for cyt-aaRSs. While the organization of cyt-aaRSs is explored and their involvement into alternate functions established, the properties of the human mt-aaRSs remain unknown. On one site, this thesis integrate mt-AspRS into new functional networks (sub-mitochondrial localization and partnership). On the other site, it expand the view of the sub-mitochondrial organization to the full set of mt-aaRSs and should ultimately shed light into the molecular mechanisms underlying some of the pathologies. These results open the door for additional investigations to gain a complete view about the sub-mitochondrial organization of aaRSs. Those contributions will be of help for the understanding of molecular mechanisms underlying some mitochondrial disorders.Les aminoacyl-ARNt synthetases (aaRS) sont impliquées dans le mécanismes de la traduction. Dans les cellules humaines, il existe deux jeux de gènes nucléaires codant pour les aaRS : un pour les aaRS cytosolique (cyt), le second pour les aaRS mitochondriales (mt). Les aaRS mt sont traduites dans le cytosole, adressées et importées dans la mitochondrie.Mutations dans 9 gènes d’aaRS mt ont été démontrées comme responsables de pathologies mitochondriales. Certaines des mutations n’affectent pas la propriété originelle d’aminoacylation. Il a été proposé que certaines de ces mutations puissent affecter des propriétés alternatives.Alors l’organisation des aaRS cyt est bien étudiée et que des implications dans des fonctions alternatives établies pour certaines d’entre elles, les connaissances quant aux aaRS mt restent parcimonieuses. L’objectif principal de ce manuscrit de thèse est: (i) révéler d’organisation sous-mt de l’AspRS mt; (ii) étendre l’analyse de l’organisation sous-mt à l’ensemble des aaRS mt; et (iii) contribuer à la compréhension de mécanismes moléculaires sous-jacents à certaines pathologies. Ces travaux ouvrent la porte vers d’autres investigations de l’organisation des aaRS à l’intérieur de la mitochondrie. Ces contributions seront utiles à la meilleure compréhension de mécanismes moléculaires sous-jacents à pathologies mitochondriales

New properties of mitochondrial aminoacyl-tRNA synthetases and their connection to mitochondrial diseases

Les aminoacyl-ARNt synthetases (aaRS) sont impliquées dans le mécanismes de la traduction. Dans les cellules humaines, il existe deux jeux de gènes nucléaires codant pour les aaRS : un pour les aaRS cytosolique (cyt), le second pour les aaRS mitochondriales (mt). Les aaRS mt sont traduites dans le cytosole, adressées et importées dans la mitochondrie.Mutations dans 9 gènes d’aaRS mt ont été démontrées comme responsables de pathologies mitochondriales. Certaines des mutations n’affectent pas la propriété originelle d’aminoacylation. Il a été proposé que certaines de ces mutations puissent affecter des propriétés alternatives.Alors l’organisation des aaRS cyt est bien étudiée et que des implications dans des fonctions alternatives établies pour certaines d’entre elles, les connaissances quant aux aaRS mt restent parcimonieuses. L’objectif principal de ce manuscrit de thèse est: (i) révéler d’organisation sous-mt de l’AspRS mt; (ii) étendre l’analyse de l’organisation sous-mt à l’ensemble des aaRS mt; et (iii) contribuer à la compréhension de mécanismes moléculaires sous-jacents à certaines pathologies. Ces travaux ouvrent la porte vers d’autres investigations de l’organisation des aaRS à l’intérieur de la mitochondrie. Ces contributions seront utiles à la meilleure compréhension de mécanismes moléculaires sous-jacents à pathologies mitochondriales.Aminoacyl-tRNA synthetases (aaRSs) are housekeeping enzymes involved in translation. In human cells, 2 different sets of nuclear genes code for aaRSs. One codes for cytosolic (cyt) aaRSs, and the second one codes for aaRSs of mitochondrial (mt) location. Mt-aaRSs are translated in the cytosol, targeted and imported into mitochondria.Mutations in 9 mt-aaRSs have been described. Some of the mutations do not display significant influence on the housekeeping aminoacylation activity. It has been proposed that those mutations affect alternative functions.Alternate functions have been described for cyt-aaRSs. While the organization of cyt-aaRSs is explored and their involvement into alternate functions established, the properties of the human mt-aaRSs remain unknown. On one site, this thesis integrate mt-AspRS into new functional networks (sub-mitochondrial localization and partnership). On the other site, it expand the view of the sub-mitochondrial organization to the full set of mt-aaRSs and should ultimately shed light into the molecular mechanisms underlying some of the pathologies. These results open the door for additional investigations to gain a complete view about the sub-mitochondrial organization of aaRSs. Those contributions will be of help for the understanding of molecular mechanisms underlying some mitochondrial disorders

New properties of mitochondrial aminoacyl-tRNA synthetases and their connection to mitochondrial diseases

Les aminoacyl-ARNt synthetases (aaRS) sont impliquées dans le mécanismes de la traduction. Dans les cellules humaines, il existe deux jeux de gènes nucléaires codant pour les aaRS : un pour les aaRS cytosolique (cyt), le second pour les aaRS mitochondriales (mt). Les aaRS mt sont traduites dans le cytosole, adressées et importées dans la mitochondrie.Mutations dans 9 gènes d’aaRS mt ont été démontrées comme responsables de pathologies mitochondriales. Certaines des mutations n’affectent pas la propriété originelle d’aminoacylation. Il a été proposé que certaines de ces mutations puissent affecter des propriétés alternatives.Alors l’organisation des aaRS cyt est bien étudiée et que des implications dans des fonctions alternatives établies pour certaines d’entre elles, les connaissances quant aux aaRS mt restent parcimonieuses. L’objectif principal de ce manuscrit de thèse est: (i) révéler d’organisation sous-mt de l’AspRS mt; (ii) étendre l’analyse de l’organisation sous-mt à l’ensemble des aaRS mt; et (iii) contribuer à la compréhension de mécanismes moléculaires sous-jacents à certaines pathologies. Ces travaux ouvrent la porte vers d’autres investigations de l’organisation des aaRS à l’intérieur de la mitochondrie. Ces contributions seront utiles à la meilleure compréhension de mécanismes moléculaires sous-jacents à pathologies mitochondriales.Aminoacyl-tRNA synthetases (aaRSs) are housekeeping enzymes involved in translation. In human cells, 2 different sets of nuclear genes code for aaRSs. One codes for cytosolic (cyt) aaRSs, and the second one codes for aaRSs of mitochondrial (mt) location. Mt-aaRSs are translated in the cytosol, targeted and imported into mitochondria.Mutations in 9 mt-aaRSs have been described. Some of the mutations do not display significant influence on the housekeeping aminoacylation activity. It has been proposed that those mutations affect alternative functions.Alternate functions have been described for cyt-aaRSs. While the organization of cyt-aaRSs is explored and their involvement into alternate functions established, the properties of the human mt-aaRSs remain unknown. On one site, this thesis integrate mt-AspRS into new functional networks (sub-mitochondrial localization and partnership). On the other site, it expand the view of the sub-mitochondrial organization to the full set of mt-aaRSs and should ultimately shed light into the molecular mechanisms underlying some of the pathologies. These results open the door for additional investigations to gain a complete view about the sub-mitochondrial organization of aaRSs. Those contributions will be of help for the understanding of molecular mechanisms underlying some mitochondrial disorders

Two proteomic methodologies for defining N-termini of mature human mitochondrial aminoacyl-tRNA synthetases

International audienceHuman mitochondrial aminoacyl-tRNA synthetases (mt-aaRSs) are encoded in the nucleus, synthesized in the cytosol and targeted for importation into mitochondria by a N-terminal mitochondrial targeting sequence. This targeting sequence is presumably cleaved upon entry into the mitochondria, following a process still not fully deciphered in human, despite essential roles for the mitochondrial biogenesis. Maturation processes are indeed essential both for the release of a functional enzyme and to route correctly the protein within mitochondria. The absence of consensus sequences for cleavage sites and the discovery of possible multiple proteolytic steps render predictions of N-termini difficult. Further, the knowledge of the cleavages is key for the design of protein constructions compatible with efficient production in bacterial strains. Finally, full comprehension becomes essential because a growing number of mutations are found in genes coding for mt-aaRS. In the present study, we take advantage of proteomic methodological developments and identified, in mitochondria, three N-termini for the human mitochondrial aspartyl-tRNA synthetase. This first description of the co-existence of different forms opens new perspectives in the biological understanding of this enzyme. Those methods are extended to the whole set of human mt-aaRSs and methodological advice are provided for further investigations

Three human aminoacyl-tRNA synthetases have distinct sub-mitochondrial localizations that are unaffected by disease-associated mutations

International audienc

Sci Rep

Mutations in human mitochondrial aminoacyl-tRNA synthetases are associated with a variety of neurodegenerative disorders. The effects of these mutations on the structure and function of the enzymes remain to be established. Here, we investigate six mutants of the aspartyl-tRNA synthetase correlated with leukoencephalopathies. Our integrated strategy, combining an ensemble of biochemical and biophysical approaches, reveals that mutants are diversely affected with respect to their solubility in cellular extracts and stability in solution, but not in architecture. Mutations with mild effects on solubility occur in patients as allelic combinations whereas those with strong effects on solubility or on aminoacylation are necessarily associated with a partially functional allele. The fact that all mutations show individual molecular and cellular signatures and affect amino acids only conserved in mammals, points towards an alternative function besides aminoacylation