RcnB Is a Periplasmic Protein Essential for Maintaining Intracellular Ni and Co Concentrations in Escherichia coli

International audienceNickel and cobalt are both essential trace elements that are toxic when present in excess. The main resistance mechanism that bacteria use to overcome this toxicity is the efflux of these cations out of the cytoplasm. RND (resistance-nodulation-cell division)- and MFS (major facilitator superfamily)-type efflux systems are known to export either nickel or cobalt. The RcnA efflux pump, which belongs to a unique family, is responsible for the detoxification of Ni and Co in Escherichia coli. In this work, the role of the gene yohN, which is located downstream of rcnA, is investigated. yohN is cotranscribed with rcnA, and its expression is induced by Ni and Co. Surprisingly, in contrast to the effect of deleting rcnA, deletion of yohN conferred enhanced resistance to Ni and Co in E. coli, accompanied by decreased metal accumulation. We show that YohN is localized to the periplasm and does not bind Ni or Co ions directly. Physiological and genetic experiments demonstrate that YohN is not involved in Ni import. YohN is conserved among proteobacteria and belongs to a new family of proteins; consequently, yohN has been renamed rcnB. We show that the enhanced resistance of rcnB mutants to Ni and Co and their decreased Ni and Co intracellular accumulation are linked to the greater efflux of these ions in the absence of rcnB. Taken together, these results suggest that RcnB is required to maintain metal ion homeostasis, in conjunction with the efflux pump RcnA, presumably by modulating RcnA-mediated export of Ni and Co to avoid excess efflux of Ni and Co ions via an unknown novel mechanism

Complexity and conservation of regulatory landscapes underlie evolutionary resilience of mammalian gene expression.

To gain insight into how mammalian gene expression is controlled by rapidly evolving regulatory elements, we jointly analysed promoter and enhancer activity with downstream transcription levels in liver samples from 15 species. Genes associated with complex regulatory landscapes generally exhibit high expression levels that remain evolutionarily stable. While the number of regulatory elements is the key driver of transcriptional output and resilience, regulatory conservation matters: elements active across mammals most effectively stabilize gene expression. In contrast, recently evolved enhancers typically contribute weakly, consistent with their high evolutionary plasticity. These effects are observed across the entire mammalian clade and are robust to potential confounders, such as the gene expression level. Using liver as a representative somatic tissue, our results illuminate how the evolutionary stability of gene expression is profoundly entwined with both the number and conservation of surrounding promoters and enhancers

Adaptation of Proteins to the Cold in Antarctic Fish: A Role for Methionine?

The evolution of antifreeze glycoproteins has enabled notothenioid fish to flourish in the freezing waters of the Southern Ocean. Whereas successful at the biodiversity level to life in the cold, paradoxically at the cellular level these stenothermal animals have problems producing, folding, and degrading proteins at their ambient temperatures of -1.86 °C. In this first multi-species transcriptome comparison of the amino acid composition of notothenioid proteins with temperate teleost proteins, we show that, unlike psychrophilic bacteria, Antarctic fish provide little evidence for the mass alteration of protein amino acid composition to enhance protein folding and reduce protein denaturation in the cold. The exception was the significant overrepresentation of positions where leucine in temperate fish proteins was replaced by methionine in the notothenioid orthologues. We hypothesize that these extra methionines have been preferentially assimilated into the genome to act as redox sensors in the highly oxygenated waters of the Southern Ocean. This redox hypothesis is supported by analyses of notothenioids showing enrichment of genes associated with responses to environmental stress, particularly reactive oxygen species. So overall, although notothenioid fish show cold-associated problems with protein homeostasis, they may have modified only a selected number of biochemical pathways to work efficiently below 0 °C. Even a slight warming of the Southern Ocean might disrupt the critical functions of this handful of key pathways with considerable impacts for the functioning of this ecosystem in the future

Impact of Zika Virus Emergence in French Guiana: A Large General Population Seroprevalence Survey.

BACKGROUND: Since the identification of Zika virus (ZIKV) in Brazil in May 2015, the virus has spread throughout the Americas. However, ZIKV burden in the general population in affected countries remains unknown. METHODS: We conducted a general population survey in the different communities of French Guiana through individual interviews and serologic survey during June-October 2017. All serum samples were tested for anti-ZIKV immunoglobulin G antibodies using a recombinant antigen-based SGERPAxMap microsphere immunoassay, and some of them were further evaluated through anti-ZIKV microneutralization tests. RESULTS: The overall seroprevalence was estimated at 23.3% (95% confidence interval [CI], 20.9%-25.9%) among 2697 participants, varying from 0% to 45.6% according to municipalities. ZIKV circulated in a large majority of French Guiana but not in the most isolated forest areas. The proportion of reported symptomatic Zika infection was estimated at 25.5% (95% CI, 20.3%-31.4%) in individuals who tested positive for ZIKV. CONCLUSIONS: This study described a large-scale representative ZIKV seroprevalence study in South America from the recent 2015-2016 Zika epidemic. Our findings reveal that the majority of the population remains susceptible to ZIKV, which could potentially allow future reintroductions of the virus

Spatial Distribution and Burden of Emerging Arboviruses in French Guiana.

Despite the health, social and economic impact of arboviruses in French Guiana, very little is known about the extent to which infection burden is shared between individuals. We conducted a large multiplexed serological survey among 2697 individuals from June to October 2017. All serum samples were tested for IgG antibodies against DENV, CHIKV, ZIKV and MAYV using a recombinant antigen-based microsphere immunoassay with a subset further evaluated through anti-ZIKV microneutralization tests. The overall DENV seroprevalence was estimated at 73.1% (70.6-75.4) in the whole territory with estimations by serotype at 68.9% for DENV-1, 38.8% for DENV-2, 42.3% for DENV-3, and 56.1% for DENV-4. The overall seroprevalence of CHIKV, ZIKV and MAYV antibodies was 20.3% (17.7-23.1), 23.3% (20.9-25.9) and 3.3% (2.7-4.1), respectively. We provide a consistent overview of the burden of emerging arboviruses in French Guiana, with useful findings for risk mapping, future prevention and control programs. The majority of the population remains susceptible to CHIKV and ZIKV, which could potentially facilitate the risk of further re-emergences. Our results underscore the need to strengthen MAYV surveillance in order to rapidly detect any substantial changes in MAYV circulation patterns

Enhancer evolution across 20 mammalian species.

The mammalian radiation has corresponded with rapid changes in noncoding regions of the genome, but we lack a comprehensive understanding of regulatory evolution in mammals. Here, we track the evolution of promoters and enhancers active in liver across 20 mammalian species from six diverse orders by profiling genomic enrichment of H3K27 acetylation and H3K4 trimethylation. We report that rapid evolution of enhancers is a universal feature of mammalian genomes. Most of the recently evolved enhancers arise from ancestral DNA exaptation, rather than lineage-specific expansions of repeat elements. In contrast, almost all liver promoters are partially or fully conserved across these species. Our data further reveal that recently evolved enhancers can be associated with genes under positive selection, demonstrating the power of this approach for annotating regulatory adaptations in genomic sequences. These results provide important insight into the functional genetics underpinning mammalian regulatory evolution.We thank Stephen Watt, Frances Connor, the CRUK-CI Genomics and Bioinformatics cores, Biological Resources Unit (Matthew Clayton), Margaret Brown (West Yorkshire bat hospital), Julie E. Horvath (North Carolina Central University), and Chris Dillingham (University of Cardiff) for technical assistance; Matthieu Muffato for assistance with whole-genome alignments; Claudia Kutter, Gordon Brown, Christine Feig, and Christina Ernst for useful comments and discussions, and the EBI systems team for management of computational resources. This research was supported by Cancer Research UK (D.V., D.T.O.), the European Molecular Biology Laboratory (C.B., P.F.), the Wellcome Trust (WT095908) (P.F.) and (WT098051) (P.F., D.T.O.), the European Research Council, EMBO Young Investigator Programme (D.T.O.), the National Science Foundation (0744979) (T.J.P.), NIH (P40 OD010965, R01 OD010980, R37 MH060233) (A.J.J.) and MRC (U117588498) (J.M.A.T.). Cetacean samples were collected by the UK Cetacean Strandings Investigation Programme, funded by Defra and the Governments of Scotland and Wales.This is the final version. It originally appeared at http://www.sciencedirect.com/science/article/pii/S0092867415000070

Etude des mécanismes évolutifs perturbant l’organisation des gènes dans les génomes de vertébrés

Evolutionary processes disrupting the gene organisation in eukaryotic genomes belong to two categories: changes in the order of the genes, known as rearrangements, and changes in the content of the genome by gene duplications, deletions and gains. The mechanisms through which these events arise, and their functional and selective impact on genomes, are poorly understood. This thesis covers two different projects. Firstly, we investigated the distribution of rearrangement breakpoints between an ancestral genome and its modern descendants. This distribution was modelled according to local genomic characteristics to highlight factors influencing the breakage process. Our results show that the distribution of breakpoints can be simply explained as a function of intergenic spacers length, although in a non-linear fashion differing from classical random expectations. The repartition of breakpoints in genomes seems to be linked to structural properties, and is only marginally affected by selective constraints. It might in fact reflect local chromatin structure in the genome. The second project is part of the joint sequencing effort for the zebrafish genome, and provides an overview of the organisation of this genome. Teleost fish genomes are anciently duplicated: the analysis focuses on the consequences of this duplication. Results show that the zebrafish genome displays a typical teleost fish genome organisation. Genes retained in two copies after the whole genome duplication belong to specific functional categories, and are biased towards genes already conserved as duplicates after the 1R and 2R duplication events that have taken place early in vertebrate history.Les phénomènes évolutifs qui perturbent l’organisation des gènes dans les génomes eucaryotes sont de deux types : les changements dans l’ordre des gènes, ou réarrangements, et les modifications du contenu en gènes du génome, par duplications, délétions ou gains de gènes. Ces processus sont mal connus, tant au niveau de leurs mécanismes d’apparition que de leur impact fonctionnel et sélectif. Ce travail de thèse s’articule autour de deux projets. Le premier s’intéresse à la distribution des points de cassure de réarrangements évolutifs entre un génome ancestral et ses descendants modernes. Cette distribution a été modélisée en fonction des caractéristiques locales du génome pour mettre en évidence quels facteurs influencent la probabilité de cassure. Nos résultats montrent que la distribution des cassures peut s’expliquer simplement comme une fonction de la longueur des espaces intergéniques, fonction qui est cependant non-linéaire contrairement aux attentes sous un régime aléatoire classique. La répartition des points de cassure dans les génomes semble principalement liée à des propriétés de structure, et n’est que peu soumise à des contraintes de sélection. Elle pourrait être liée à la structure chromatinienne du génome. Le second projet s’inscrit dans le cadre du séquençage du génome du poisson zèbre, et fournit un aperçu global de l’organisation de ce génome. Les génomes de poissons téléostéens sont anciennement dupliqués : l’analyse est axée sur les conséquences de cette duplication. Les résultats montrent que le génome du poisson zèbre présente une organisation assez typique d’un génome téléostéen. Les gènes retenus en deux copies après la duplication du génome appartiennent à des catégories fonctionnelles particulières, et sont biaisés vers des gènes déjà conservés après les duplications 1R et 2R ayant eu lieu au début de l’histoire des vertébrés

Comparative genomics and the emergence of evolutionary innovations in Vertebrates

Genome evolution is the source of much of the transmissible phenotypic variability we observe within and between species. Over the past ten years, the advancements of sequencing technologies have made it possible to explore and compare the genomes of multiple species to understand how evolution acts on vertebrate genomes, but also how the genomes of these diverse species relate to our own. Evidence shows that vertebrate genomes evolve at multiple scales, from base pair substitutions to large- scale rearrangements of chromosomal structure, and these modifications can all result in functional changes in gene products and expression programs. During my scientific career, I have studied vertebrate genome evolution across multiple clades, timescales and levels of resolution in order to better understand how genomic changes can result in evolutionary novelty. This habilitation thesis summarizes my work on the evolution of genome organisation in paleopolyploid fishes and vertebrates, and on the evolution of gene expression in mammals and fishes. Since September 2021, I lead the Comparative Functional Genomics group at Institut Pasteur. In the final section of the manuscript, I discuss how my lab is heading forward to uncover the functional mechanisms of evolutionary innovations in primates and other mammalian groups.L’évolution du génome est la source de la majorité de la variabilité phénotypique transmissible observéeentre individus et entre espèces. Au cours des dernières années, l’avancée des technologies deséquençage a rendu possible l’exploration et la comparaison des génomes de nombreuses espècespour éclairer les mécanismes par lesquels l’évolution façonne les génomes de vertébrés, mais aussi àquel degré ces génomes sont similaires au nôtre. L’observation montre que les génomes de vertébrésévoluent à de multiples échelles, de la substitution de base aux réarrangements à large échelle de lastructure des chromosomes, et toutes ces changements sont susceptibles de modifierfonctionnellement les gènes ou leurs programmes d’expression. Au cours de ma carrière scientifique,j’ai étudié l’évolution des génomes de vertébrés à travers différents clades, échelles de temps et niveauxde résolution pour mieux comprendre comment ces changements génomiques permettent l’apparitiond’innovations évolutives. Cette these d’habilitation résume mes travaux sur l’évolution de l’organisationdu génome chez les poisons paleopolyploïdes et chez les vertébrés, ainsi que sur l’évolution del’expression des gènes chez les mammifères et les poissons. Depuis septembre 2021, je dirige legroupe Génomique Fonctionnelle Comparative à l’Institut Pasteur. Dans la dernière section dumanuscrit, je discute des directions futures de mon laboratoire pour illuminer les mécanismesfonctionnels d’innovations évolutives chez les primates et d’autres groupes de mammifères

Analysis of evolutionary mecanisms altering gene organisation in vertebrate genomes

Les phénomènes évolutifs qui perturbent l’organisation des gènes dans les génomes eucaryotes sont de deux types : les changements dans l’ordre des gènes, ou réarrangements, et les modifications du contenu en gènes du génome, par duplications, délétions ou gains de gènes. Ces processus sont mal connus, tant au niveau de leurs mécanismes d’apparition que de leur impact fonctionnel et sélectif. Ce travail de thèse s’articule autour de deux projets. Le premier s’intéresse à la distribution des points de cassure de réarrangements évolutifs entre un génome ancestral et ses descendants modernes. Cette distribution a été modélisée en fonction des caractéristiques locales du génome pour mettre en évidence quels facteurs influencent la probabilité de cassure. Nos résultats montrent que la distribution des cassures peut s’expliquer simplement comme une fonction de la longueur des espaces intergéniques, fonction qui est cependant non-linéaire contrairement aux attentes sous un régime aléatoire classique. La répartition des points de cassure dans les génomes semble principalement liée à des propriétés de structure, et n’est que peu soumise à des contraintes de sélection. Elle pourrait être liée à la structure chromatinienne du génome. Le second projet s’inscrit dans le cadre du séquençage du génome du poisson zèbre, et fournit un aperçu global de l’organisation de ce génome. Les génomes de poissons téléostéens sont anciennement dupliqués : l’analyse est axée sur les conséquences de cette duplication. Les résultats montrent que le génome du poisson zèbre présente une organisation assez typique d’un génome téléostéen. Les gènes retenus en deux copies après la duplication du génome appartiennent à des catégories fonctionnelles particulières, et sont biaisés vers des gènes déjà conservés après les duplications 1R et 2R ayant eu lieu au début de l’histoire des vertébrés.Evolutionary processes disrupting the gene organisation in eukaryotic genomes belong to two categories: changes in the order of the genes, known as rearrangements, and changes in the content of the genome by gene duplications, deletions and gains. The mechanisms through which these events arise, and their functional and selective impact on genomes, are poorly understood. This thesis covers two different projects. Firstly, we investigated the distribution of rearrangement breakpoints between an ancestral genome and its modern descendants. This distribution was modelled according to local genomic characteristics to highlight factors influencing the breakage process. Our results show that the distribution of breakpoints can be simply explained as a function of intergenic spacers length, although in a non-linear fashion differing from classical random expectations. The repartition of breakpoints in genomes seems to be linked to structural properties, and is only marginally affected by selective constraints. It might in fact reflect local chromatin structure in the genome. The second project is part of the joint sequencing effort for the zebrafish genome, and provides an overview of the organisation of this genome. Teleost fish genomes are anciently duplicated: the analysis focuses on the consequences of this duplication. Results show that the zebrafish genome displays a typical teleost fish genome organisation. Genes retained in two copies after the whole genome duplication belong to specific functional categories, and are biased towards genes already conserved as duplicates after the 1R and 2R duplication events that have taken place early in vertebrate history