The impact of mitochondrial tRNA mutations on the amount of ATP synthase differs in the brain compared to other tissues

AbstractThe impact of point mutations in mitochondrial tRNA genes on the amount and stability of respiratory chain complexes and ATP synthase (OXPHOS) has been broadly characterized in cultured skin fibroblasts, skeletal muscle samples, and mitochondrial cybrids. However, less is known about how these mutations affect other tissues, especially the brain. We have compared OXPHOS protein deficiency patterns in skeletal muscle mitochondria of patients with Leigh (8363G>A), MERRF (8344A>G), and MELAS (3243A>G) syndromes. Both mutations that affect mt-tRNALys (8363G>A, 8344A>G) resulted in severe combined deficiency of complexes I and IV, compared to an isolated severe defect of complex I in the 3243A>G sample (mt-tRNALeu(UUR)). Furthermore, we compared obtained patterns with those found in the heart, frontal cortex, and liver of 8363G>A and 3243A>G patients. In the frontal cortex mitochondria of both patients, the patterns of OXPHOS deficiencies differed substantially from those observed in other tissues, and this difference was particularly striking for ATP synthase. Surprisingly, in the frontal cortex of the 3243A>G patient, whose ATP synthase level was below the detection limit, the assembly of complex IV, as inferred from 2D-PAGE immunoblotting, appeared to be hindered by some factor other than the availability of mtDNA-encoded subunits

Correction of the consequences of mitochondrial 3243A>G mutation in the MT-TL1 gene causing the MELAS syndrome by tRNA import into mitochondria

Mutations in human mitochondrial DNA are often associated with incurable human neuromuscular diseases. Among these mutations, an important number have been identified in tRNA genes, including 29 in the gene MT-TL1 coding for the tRNALeu(UUR). The m.3243A>G mutation was described as the major cause of the MELAS syndrome (mitochondrial encephalomyopathy with lactic acidosis and stroke-like episodes). This mutation was reported to reduce tRNALeu(UUR) aminoacylation and modification of its anti-codon wobble position, which results in a defective mitochondrial protein synthesis and reduced activities of respiratory chain complexes. In the present study, we have tested whether the mitochondrial targeting of recombinant tRNAs bearing the identity elements for human mitochondrial leucyl-tRNA synthetase can rescue the phenotype caused by MELAS mutation in human transmitochondrial cybrid cells. We demonstrate that nuclear expression and mitochondrial targeting of specifically designed transgenic tRNAs results in an improvement of mitochondrial translation, increased levels of mitochondrial DNA-encoded respiratory complexes subunits, and significant rescue of respiration. These findings prove the possibility to direct tRNAs with changed aminoacylation specificities into mitochondria, thus extending the potential therapeutic strategy of allotopic expression to address mitochondrial disorders

Gènes de l’immunité innée et leur importance dans l'écologie évolutive des rongeurs sauvages

Appropriate recognition of parasites is crucial for effective immune response, ensuring activation of adequate defence mechanisms. In vertebrates, it has frequently been demonstrated that genes encoding proteins involved in pathogen recognition by an adaptive immune system are often subject to intense selection pressures. On the contrary, much less information has been provided on the evolution of recognition mechanisms of innate immunity. The aim of this thesis is to describe the pattern of natural variation of innate immunity genes involved in pathogen recognition in rodents and to analyze the mechanisms of their evolution. We used murine rodents (subfamily Murinae) as a principal model group because they are potential reservoirs of various pathogens dangerous to humans. First, we studied the intraspecific variability of five bacterial sensing Toll-like receptors (TLR1, TLR2, TLR4, TLR5, and TLR6) in inbred strains derived from two subspecies of the house mouse (M. m. musculus, hereafter abbreviated as Mmm and Mus musculus domesticus, Mmd). Wild-derived inbred strains are suitable tools for studying variation of immunity genes because they provide information about alleles that occur in natural populations, and at the same time they occur at homozygous state. The most significant results include the findings of a stop codon in exon 2 of the Tlr5 gene in one Mmm strain and no variability in Tlr4 of Mmd. Following these results we decided to check whether the absence of Tlr4 polymorphism in Mmd reflects the pattern found in natural populations, or whether it is a consequence of insufficient sampling or subsequent breeding. We therefore sequenced Tlr4 in both subspecies across a large part of the Western Palearctic region (in total 39 Mmm and 62 Mmd individuals), then we compared these results with variability on mitochondrial DNA (cytochrome b). The result confirmed our prediction that observed variability in Mmd is strongly reduced also in free-living populations (compared to Mmm), probably due to strong purifying selection by pathogens with which they met during the westward colonization. However, the influence of random evolutionary processes (e.g. drift during bottlenecks) cannot be excluded based on our data. At the intraspecific level, we could not find any sign of positive selection. The last part of my dissertation is devoted to interspecific comparison of two receptors, TLR4 and TLR7. These two TLRs differ in the exposure and the ligands detection. TLR4 is an extracellular receptor detecting mainly bacterial ligands (especially lipopolysaccharides), while TLR7 is located inside the cell and detects ssRNA viruses. The aim of this part of the thesis was to describe variability of both receptors at the interspecific level and to reveal selection forces acting on TLRs in longer evolutionary time scale. In total we analyzed 23 rodent species of the subfamily Murinae in Europe, Asia and Africa. Our results suggest that purifying selection has been a dominant force in evolution of the Tlr4 and Tlr7 genes, but we also demonstrated that episodic diversifying selection has shaped the present species-specific variation in rodent Tlrs. Sites under positive selection were concentrated mainly in the extracellular domain of both receptors, which is responsible for ligand binding. The comparison between two TLRs lead us to the conclusion that the intracellular TLR7 is under much stronger negative selection pressure, presumably due to its interaction with viral nucleic acids.Une reconnaissance appropriée des parasites est essentielle pour une réponse immunitaire efficace, assurant l'activation adéquate des mécanismes de défense immunitaire. Chez les vertébrés, il a été démontré que les gènes codant pour les récepteurs de l'immunité adaptative impliqués dans la reconnaissance des agents pathogènes sont soumis à une intense pression sélective. En revanche, beaucoup moins d’études se sont intéressées à la sélection agissant sur les récepteurs de l'immunité innée. Le but de cette thèse est de décrire la variabilité naturelle des gènes de l'immunité innée impliqués dans la détection des agents pathogènes chez les rongeurs et d’analyser les mécanismes responsables de leur évolution. Ce travail s’est focalisé principalement sur les rongeurs de la sous-famille des Murinae et de leur rôle potentiel en tant que réservoirs d’agents pathogènes dangereux pour l’Homme. Tout d´abord nous avons étudié la variabilité intraspécifique de cinq Toll-like récepteurs ciblant les bactéries (TLR1, TLR2, TLR4, TLR5 et TLR6) pour des lignées consanguines de souris domestiques issues d’une population sauvage de deux sous-espèces : Mus musculus domesticus (Mmd) et Mus musculus musculus (Mmm). Les souches consanguines constituent un outil adapté à l'étude de la variabilité des gènes immunitaires car elles confèrent une information sur les allèles présents dans les populations naturelles tout en bénéficiant de génotypes homozygotes. Les résultats les plus significatifs concernent la découverte d'un codon stop dans l'exon 2 du Tlr5 chez une lignée de Mmm et l’absence de variabilité du Tlr4 chez Mmd. A la suite de ces résultats, nous avons décidé de vérifier si l‘absence de polymorphisme du Tlr4 chez Mmd reflète une absence de variabilité dans les populations naturelles, ou si il s’agit plutôt d’un effet de l'échantillonnage ou des croisements ultérieurs. Nous avons donc séquencé le gène Tlr4 pour les deux sous-espèces provenant de la région du Paléarctique Occidentale (au total 39 Mmm et 62 Mmd) puis nous avons comparé ces résultats avec la variabilité génétique d’un gène mitochondrial (cytochrome b). Nous avons confirmé notre prédiction : la variabilité de Tlr4 chez Mmd est fortement réduite par rapport à Mmm, probablement à cause d’agents pathogènes ayant exercé une sélection purifiante chez Mmd durant la colonisation vers l’ouest. Cependant, l'influence de mécanismes évolutifs neutres, tel que la dérive consécutive à un goulot d’étranglement démographique, ne peut être exclue sur la base de nos données. La dernière partie a été consacrée à la comparaison interspécifique de deux récepteurs : TLR4 et TLR7. Ces deux TLRs se différencient à la fois par leur localisation et leur capacité de détection. TLR4 est un TLR extracellulaire reconnaissant principalement les ligands bactériens, essentiellement les lipopolysaccharides, tandis que TLR7 est localisé dans la cellule et détecte les virus à ARN simple brin. L‘objectif était de décrire la variabilité inter-spécifique de chaque récepteur et de révéler les mécanismes de sélection s’exerçant sur ces gènes au cours de leur évolution sur une échelle de temps plus importante. Nous avons analysé 23 espèces de Murinae provenant surtout d’Asie. Nos résultats suggèrent que la sélection purifiante est la force principale ayant agit sur l’évolution des deux TLRs. Cependant, nous avons également mis en évidence des épisodes de sélection diversifiante qui ont pu être à l’origine des variations intra-spécifiques de TLRs observée aujourd’hui chez les rongeurs. Des sites sous sélection positive sont principalement concentrés dans les domaines extracellulaires des deux récepteurs, domaines responsables de la reconnaissance des agents pathogènes. Enfin, la comparaison entre ces deux TLRs montre que le TLR7 est soumis à une sélection négative plus forte. Cette sélection peut s’expliquer en raison des interactions du TLR7 avec les acides nucléiques viraux

Contrasting patterns of polymorphism and selection in bacterial-sensing toll-like receptor 4 in two house mouse subspecies: Contrasting patterns of polymorphism and selection in bacterial-sensing toll-like receptor 4 in two house mouse subspecies

Times Cited: 0 Vinkler, Michal/G-2072-2011; Pialek, Jaroslav/B-1237-2008; Bryja, Josef/C-3013-2008 Vinkler, Michal/0000-0003-3572-9494; 0International audienceDetailed investigation of variation in genes involved in pathogen recognition is crucial for understanding co-evolutionary processes between parasites and their hosts. Triggering immediate innate response to invading microbes, Toll-like receptors (TLRs) belong presently among the best-studied receptors of vertebrate immunity. TLRs exhibit remarkable interspecific variation and also intra-specific polymorphism is well documented. In humans and laboratory mice, several studies have recently shown that single amino acid substitution may significantly alter receptor function. Unfortunately, data concerning polymorphism in free-living species are still surprisingly scarce. In this study, we analyzed the polymorphism of Toll-like receptor 4 (Tlr4) over the Palearctic range of house mouse (Mus musculus). Our results reveal contrasting evolutionary patterns between the two recently (0.5 million years ago) diverged house mouse subspecies: M. m. domesticus (Mmd) and M. m. musculus (Mmm). Comparison with cytochrome b indicates strong directional selection in Mmd Tlr4. Throughout the whole Mmd western Palaearctic region, a single variant of the ligand-binding region is spread, encoded mainly by one dominant haplotype (71% of Mmd). In contrast, Tlr4 in Mmm is much more polymorphic with several haplotypes at intermediate frequencies. Moreover, we also found clear signals of recombination between two principal haplogroups in Mmm, and we identified eight sites under positive selection in our dataset. Our results suggest that observed differences in Tlr4 diversity may be attributed to contrasting parasite-mediated selection acting in the two subspecies

Strong matrilineal structure in common pipistrelle bats (Pipistrellus pipistrellus) is associated with variability in echolocation calls

International audienceThe ontogeny and heritability of echolocation, an important sense in echolocating bats, is still not completely understood. Intraspecific variation in echolocation calls can be high, although the importance of possible explanatory variables (e.g. age, sex, social groups) remains largely unknown. Echolocation pulse features may vary among maternity roosts and this can theoretically be caused either by intercolony genetic differences or by vocal dialects learned during ontogeny within a roost (or a combination of both). In the present study, we analyzed intraspecific variation in echolocation parameters in relation to genetic structure at bi-parentally inherited microsatellites and maternally inherited mitochondrial (mt)DNA in maternal colonies of Pipistrelluspipistrellus in Central Europe. We found that individual colonies differ significantly in mtDNA, whereas the structure on nuclear markers is almost absent. This suggests a typical temperate bat social structure pattern, with strong sex-biased dispersal (i.e. philopatric females and dispersing males) (up to 92% of males leave their birth place according to our results). However, we show for the first time that genetic differentiation among mtDNA matrilines is associated with significant intercolony echolocation parameter differences. Because the genetic component of echolocation is not likely to be encoded by mtDNA, the results support the hypothesis of maternal echolocation dialect transmission to offspring, and the role of learning in this process is discussed

Contrasted evolutionary histories of two Toll-like receptors (Tlr4 and Tlr7) in wild rodents (MURINAE)

Background: In vertebrates, it has been repeatedly demonstrated that genes encoding proteins involved in pathogen-recognition by adaptive immunity (e. g. MHC) are subject to intensive diversifying selection. On the other hand, the role and the type of selection processes shaping the evolution of innate-immunity genes are currently far less clear. In this study we analysed the natural variation and the evolutionary processes acting on two genes involved in the innate-immunity recognition of Microbe-Associated Molecular Patterns (MAMPs). Results: We sequenced genes encoding Toll-like receptor 4 (Tlr4) and 7 (Tlr7), two of the key bacterial-and viral-sensing receptors of innate immunity, across 23 species within the subfamily Murinae. Although we have shown that the phylogeny of both Tlr genes is largely congruent with the phylogeny of rodents based on a comparably sized non-immune sequence dataset, we also identified several potentially important discrepancies. The sequence analyses revealed that major parts of both Tlrs are evolving under strong purifying selection, likely due to functional constraints. Yet, also several signatures of positive selection have been found in both genes, with more intense signal in the bacterial-sensing Tlr4 than in the viral-sensing Tlr7. 92% and 100% of sites evolving under positive selection in Tlr4 and Tlr7, respectively, were located in the extracellular domain. Directly in the Ligand-Binding Region (LBR) of TLR4 we identified two rapidly evolving amino acid residues and one site under positive selection, all three likely involved in species-specific recognition of lipopolysaccharide of gram-negative bacteria. In contrast, all putative sites of LBRTLR7 involved in the detection of viral nucleic acids were highly conserved across rodents. Interspecific differences in the predicted 3D-structure of the LBR of both Tlrs were not related to phylogenetic history, while analyses of protein charges clearly discriminated Rattini and Murini clades. Conclusions: In consequence of the constraints given by the receptor protein function purifying selection has been a dominant force in evolution of Tlrs. Nevertheless, our results show that episodic diversifying parasite-mediated selection has shaped the present species-specific variability in rodent Tlrs. The intensity of diversifying selection was higher in Tlr4 than in Tlr7, presumably due to structural properties of their ligands