Deep Sequencing of Mixed Total DNA without Barcodes Allows Efficient Assembly of Highly Plastic Ascidian Mitochondrial Genomes

Ascidians or sea squirts form a diverse group within chordates, which includes a few thousand members of marine sessile filter-feeding animals. Their mitochondrial genomes are characterized by particularly high evolutionary rates and rampant gene rearrangements. This extreme variability complicates standard polymerase chain reaction (PCR) based techniques for molecular characterization studies, and consequently only a few complete Ascidian mitochondrial genome sequences are available. Using the standard PCR and Sanger sequencing approach, we produced the mitochondrial genome of Ascidiella aspersa only after a great effort. In contrast, we produced five additional mitogenomes (Botrylloides aff. leachii, Halocynthia spinosa, Polycarpa mytiligera, Pyura gangelion, and Rhodosoma turcicum) with a novel strategy, consisting in sequencing the pooled total DNA samples of these five species using one Illumina HiSeq 2000 flow cell lane. Each mitogenome was efficiently assembled in a single contig using de novo transcriptome assembly, as de novo genome assembly generally performed poorly for this task. Each of the new six mitogenomes presents a different and novel gene order, showing that no syntenic block has been conserved at the ordinal level (in Stolidobranchia and in Phlebobranchia). Phylogenetic analyses support the paraphyly of both Ascidiacea and Phlebobranchia, with Thaliacea nested inside Phlebobranchia, although the deepest nodes of the Phlebobranchia–Thaliacea clade are not well resolved. The strategy described here thus provides a cost-effective approach to obtain complete mitogenomes characterized by a highly plastic gene order and a fast nucleotide/amino acid substitution rate

Purifying selection in corvids is less efficient on islands

Funding was provided by the European Research Council (ERCStG-336536 FuncSpecGen to J.B.W.W.), the Swedish Research Council Vetenskapsrådet (621-2013-4510 to J.B.W.W.), the Knut and Alice Wallenberg Foundation (to J.B.W.W.), the Lawski foundation (to V.E.K. and J.B.W.W.), the German Research Foundation (KU 3402/1-1 to V.E.K.), the UK’s Biotechnology and Biological Sciences Research Council (BB/G023913/2 to C.R.), and the New Zealand Marsden Fund (to G.R.H.).Theory predicts that deleterious mutations accumulate more readily in small populations. As a consequence, mutation load is expected to be elevated in species where life-history strategies and geographic or historical contingencies reduce the number of reproducing individuals. Yet, few studies have empirically tested this prediction using genome-wide data in a comparative framework. We collected whole-genome sequencing data for 147 individuals across seven crow species (Corvus spp.). For each species, we estimated the distribution of fitness effects of deleterious mutations and compared it with proxies of the effective population size Ne. Island species with comparatively smaller geographic range sizes had a significantly increased mutation load. These results support the view that small populations have an elevated risk of mutational meltdown, which may contribute to the higher extinction rates observed in island species.Publisher PDFPeer reviewe

Molecular systematics, phylogenetics and evolution of Phyllostomid bats (Mammalia, Chiroptera) : a mitogenomic approach using high-throughput sequencing technologies

L'acquisition des données moléculaires a été bouleversée par le développement des techniques de séquençage haut-débit. Celles-ci ont augmenté la quantité des données et ont fait diminuer le coût de manière considérable. Ces nouvelles approches ont également redonné accès à des sources de matériel biologique qui étaient auparavant inutilisables en raison de la faible quantité et la forte dégradation de l'ADN qu'elles fournissent, notamment des tissus anciens, des échantillons de musée voire du matériel fossile. Un avantage supplémentaire c'est la possibilité de multiplexer les échantillons, c'est-à-dire, les mélanger et les séquencer simultanément grâce à l'utilisation de « tags » ou étiquettes permettant de les séparer après avec des outils bioinformatiques. Un marqueur qui a grandement bénéficié de ces technologies est le génome mitochondrial. En effet, nous montrons que grâce au ratio élevé entre l'ADN mitochondrial et l'ADN nucléaire par cellule, il est possible l'obtention de mitogénomes entiers, avec de couvertures adéquates, sans qu'un enrichissement préalable de l'échantillon soit nécessaire. Ceci permet d'envisager la réalisation de projets de mitogénomique comparative pour de groupes riches en espèces, requérant un échantillonnage taxonomique exhaustif et dont les divergences génétiques rendrait difficile l'usage du séquençage classique. C'est dans ce contexte que cette thèse aborde la systématique, la phylogénie et l'évolution moléculaires d'une famille de chauves-souris néotropicales : les Phyllostomidae. Cette famille est riche en espèces, avec plus de 160 taxons mais aussi en traits d'histoire de vie contrastés notamment le régime alimentaire. Cette diversité résulte en des morphologies convergentes dont les caractères sont en conséquence peu appropriés pour reconstruire l'histoire évolutive de ce groupe. La mitogénomique a prouvé être un outil efficace dans ce dessein, mais à présent aucune étude de ce type a été conduite pour cette famille. Nous avons d'abord réussi à séquencer les mitogénomes de représentants de toutes les lignées majeures couvrant également la diversité de traits d'histoire de vie. Nous montrons ensuite que l'utilisation de ces mitogénomes permet de résoudre les relations de parenté au niveau intrafamilial avec une résolution similaire à celle d'une concaténation de marqueurs mitochondriaux et nucléaires avec un soutien statistique robuste pour la plupart des nœuds de la phylogénie. Ceci nous a permis de clarifier plusieurs relations qui restaient controversées dans des études précédentes et confirmer plusieurs des clades proposés par celles-ci. Ensuite, nous abordons l'évolution du mitogénome en relation avec les traits d'histoire de vie en utilisant comme exemple le clade des vampires, les seules Mammifères hématophages, dont le génome mitochondrial semble avoir été touché par une accélération du taux d'évolution comme conséquence de l'action combinée de forces neutres et sélectives pour répondre aux contraintes imposées par ce régime alimentaire. Finalement, le cadre phylogénétique robuste proportionné par les 100 mitogénomes que nous avons séquencés pourra être utilisé comme référence pour étudier la diversification des Phyllostomidae.New sequencing technologies have revolutionized the acquisition of molecular data by increasing the amount of sequences at a considerably lower cost. These new technologies have also given access to samples previously neglected because they resulted in low-quantity and degraded DNA yields, as for example, old tissues, museum specimens and even fossil rests. An additional advantage comes from the possibility of multiplexing; this is, mixing several taxa in a single sample thanks to the use of tags or labels allowing late separating the sequences using bioinformatic tools. A molecular marker that has greatly benefited from these technologies is the mitochondrial genome. Indeed, we show that, thanks to the high per-cell ratio of mitochondrial to nuclear DNA, it's possible to obtain whole well-covered mitochondrial genomes without previous sample enrichment. This allows the accomplishment of projects of comparative mitogenomics for species-rich groups needing exhaustive taxon sampling and for which strong genetic divergences would difficult the use of classical sequencing.It is in this context that this thesis tackles the molecular systematics, phylogenetics and evolution of a Neotropical family of bats: the Phyllostomidae. This species-rich family, accounting for more than 160 species, is also the family of Mammals with the highest diversity of life history traits, for example, feeding on almost every possible source of food. This diversity results in convergent morphologies that make this kind of characters inadequate for reconstructing the evolutionary history of this group. Mitogenomics has proven useful in similar cases but no study of this kind has been conducted for this family. We got to sequence whole mitogenomes for representatives of all major lineages and covering the diversity of life history traits. We then show that using these mitogenomes allows solving intrafamilial relationships with a resolution similar to that resulting from a concatenation of mitochondrial and nuclear markers and with solid statistical support for most of the nodes of the phylogeny. This allowed clarifying several controversial relationships and confirming several clades proposed in previous studies. Next, we illustrate the evolution of mitogenomes and the influence of life history traits using the clade of vampire bats, the only hematophagous Mammals, whose mitogenome seem to have undergone an acceleration of evolutionary rate as a consequence of the combined action of neutral and selective forces in order to counter the constraints imposed by this feeding habit. Finally, the robust phylogenetic frame provided by the 100 mitogenomes that we sequenced, will be used for future studies about, for exemple, the diversification process of Phyllostomids

Systématique, phylogénie et évolution moléculaires des Phyllostomidae (Mammalia, Chiroptera) : une approche mitogénomique comparative

New sequencing technologies have revolutionized the acquisition of molecular data by increasing the amount of sequences at a considerably lower cost. These new technologies have also given access to samples previously neglected because they resulted in low-quantity and degraded DNA yields, as for example, old tissues, museum specimens and even fossil rests. An additional advantage comes from the possibility of multiplexing; this is, mixing several taxa in a single sample thanks to the use of tags or labels allowing late separating the sequences using bioinformatic tools. A molecular marker that has greatly benefited from these technologies is the mitochondrial genome. Indeed, we show that, thanks to the high per-cell ratio of mitochondrial to nuclear DNA, it's possible to obtain whole well-covered mitochondrial genomes without previous sample enrichment. This allows the accomplishment of projects of comparative mitogenomics for species-rich groups needing exhaustive taxon sampling and for which strong genetic divergences would difficult the use of classical sequencing.It is in this context that this thesis tackles the molecular systematics, phylogenetics and evolution of a Neotropical family of bats: the Phyllostomidae. This species-rich family, accounting for more than 160 species, is also the family of Mammals with the highest diversity of life history traits, for example, feeding on almost every possible source of food. This diversity results in convergent morphologies that make this kind of characters inadequate for reconstructing the evolutionary history of this group. Mitogenomics has proven useful in similar cases but no study of this kind has been conducted for this family. We got to sequence whole mitogenomes for representatives of all major lineages and covering the diversity of life history traits. We then show that using these mitogenomes allows solving intrafamilial relationships with a resolution similar to that resulting from a concatenation of mitochondrial and nuclear markers and with solid statistical support for most of the nodes of the phylogeny. This allowed clarifying several controversial relationships and confirming several clades proposed in previous studies. Next, we illustrate the evolution of mitogenomes and the influence of life history traits using the clade of vampire bats, the only hematophagous Mammals, whose mitogenome seem to have undergone an acceleration of evolutionary rate as a consequence of the combined action of neutral and selective forces in order to counter the constraints imposed by this feeding habit. Finally, the robust phylogenetic frame provided by the 100 mitogenomes that we sequenced, will be used for future studies about, for exemple, the diversification process of Phyllostomids.L'acquisition des données moléculaires a été bouleversée par le développement des techniques de séquençage haut-débit. Celles-ci ont augmenté la quantité des données et ont fait diminuer le coût de manière considérable. Ces nouvelles approches ont également redonné accès à des sources de matériel biologique qui étaient auparavant inutilisables en raison de la faible quantité et la forte dégradation de l'ADN qu'elles fournissent, notamment des tissus anciens, des échantillons de musée voire du matériel fossile. Un avantage supplémentaire c'est la possibilité de multiplexer les échantillons, c'est-à-dire, les mélanger et les séquencer simultanément grâce à l'utilisation de « tags » ou étiquettes permettant de les séparer après avec des outils bioinformatiques. Un marqueur qui a grandement bénéficié de ces technologies est le génome mitochondrial. En effet, nous montrons que grâce au ratio élevé entre l'ADN mitochondrial et l'ADN nucléaire par cellule, il est possible l'obtention de mitogénomes entiers, avec de couvertures adéquates, sans qu'un enrichissement préalable de l'échantillon soit nécessaire. Ceci permet d'envisager la réalisation de projets de mitogénomique comparative pour de groupes riches en espèces, requérant un échantillonnage taxonomique exhaustif et dont les divergences génétiques rendrait difficile l'usage du séquençage classique. C'est dans ce contexte que cette thèse aborde la systématique, la phylogénie et l'évolution moléculaires d'une famille de chauves-souris néotropicales : les Phyllostomidae. Cette famille est riche en espèces, avec plus de 160 taxons mais aussi en traits d'histoire de vie contrastés notamment le régime alimentaire. Cette diversité résulte en des morphologies convergentes dont les caractères sont en conséquence peu appropriés pour reconstruire l'histoire évolutive de ce groupe. La mitogénomique a prouvé être un outil efficace dans ce dessein, mais à présent aucune étude de ce type a été conduite pour cette famille. Nous avons d'abord réussi à séquencer les mitogénomes de représentants de toutes les lignées majeures couvrant également la diversité de traits d'histoire de vie. Nous montrons ensuite que l'utilisation de ces mitogénomes permet de résoudre les relations de parenté au niveau intrafamilial avec une résolution similaire à celle d'une concaténation de marqueurs mitochondriaux et nucléaires avec un soutien statistique robuste pour la plupart des nœuds de la phylogénie. Ceci nous a permis de clarifier plusieurs relations qui restaient controversées dans des études précédentes et confirmer plusieurs des clades proposés par celles-ci. Ensuite, nous abordons l'évolution du mitogénome en relation avec les traits d'histoire de vie en utilisant comme exemple le clade des vampires, les seules Mammifères hématophages, dont le génome mitochondrial semble avoir été touché par une accélération du taux d'évolution comme conséquence de l'action combinée de forces neutres et sélectives pour répondre aux contraintes imposées par ce régime alimentaire. Finalement, le cadre phylogénétique robuste proportionné par les 100 mitogénomes que nous avons séquencés pourra être utilisé comme référence pour étudier la diversification des Phyllostomidae

Thrice better than once: quality control guidelines to validate new mitogenomes

International audienceMitogenomic data are increasingly used in evolutionary biology and ecology, stressing theimportance for double checking the authenticity of DNA sequences. For example, Szczes´niaket al. (2013) recently published the mitochondrial genome of a bat, the Leschenault’s rousette(Rousettus leschenaultii). Here we show using straightforward phylogenetic analyses of availablechiropteran sequence data that the taxonomic attribution of the reported mitogenome iserroneous. The purportedly-new complete mitochondrial genome likely belongs to theEgyptian fruit bat (R. aegyptiacus) for which a reference sequence already exists. We proposethat future articles reporting complete mitochondrial genome sequences should mandatorilyinclude maximum likelihood trees inferred from (i) the standard barcoding marker for the taxonunder focus, which would benefit from the massive data available in public databases, and(ii) the available mitogenomes of closely related species. We also strongly advise these trees bepresented as phylograms so that all pertinent phylogenetic information is displayed in the formof a topology and its associated branch lengths. Along with compulsory information on thegeographical location and origin of the specimen, these new standards should help avoidingthe publication of taxonomically misidentified mitogenomes that might end up as referencesequences in public databases and re-used in subsequent meta-analyses

Caracterización de nichos tróficos con base en la morfología de las especies de una comunidad de aves de la Vega, Cundinamarca (Colombia)

La ecomorfología describe las interrelaciones entre la morfología funcional de los organismos y el medio. Se puede observar como el ambiente modela el diseño del organismo o como la morfología funcional del organismo determina su interacción con el ambiente. Se tomaron nueve medidas (culmen expuesto y total, alto y ancho del pico, tarso, ala, cola, largo total y largo del cuerpo (restando culmen expuesto y cola del largo total), para las especies de la comunidad de aves de la finca Paye Maye en La Vega, Cundinamarca, Colombia. Las aves se capturaron empleando redes de niebla. Para incrementar los tamaños muestrales, se midieron ejemplares de las diferentes especies que pertenecieran a la misma localidad, para lo cual se recurrió a la colección del Instituto de Ciencias Naturales de la Universidad Nacional de Colombia. Empleando análisis multivariantes, se encontraron relaciones significativas entre la morfología de las especies de aves y la ecología de las mismas, siendo las variables del pico las que expresan la mayor porción de la varianza entre las especies, seguidas por variables de gran importancia ecológica y aerodinámica como el tarso, el ala y la cola. Tanto en el espacio canónico, como en un espacio generado a partir de los componentes principales, las especies se agrupan de manera concordante con los gremios tróficos establecidos para esta comunidad. Se plantea la hipótesis de la reducción en los tamaños de las especies, a partir de los resultados del análisis discriminante entre las muestras de campo y las del Instituto de Ciencias Naturales, que datan de muestreos realizados entre 1964 y 1966, el cual separa los dos grupos con un grado alto de confianza

Illumina Library Preparation for Sequencing the GC-Rich Fraction of Heterogeneous Genomic DNA

International audienceStandard Illumina libraries are biased toward sequences of intermediate GC-content. This results in an underrepresentation of GC-rich regions in sequencing projects of genomes with heterogeneous base composition, such as mammals and birds. We developed a simple, cost-effective protocol to enrich sheared genomic DNA in its GC-rich fraction by subtracting AT-rich DNA. This was achieved by heating DNA up to 90 C before applying Illumina library preparation. We tested the new approach on chicken DNA and found that heated DNA increased average coverage in the GC-richest chromosomes by a factor up to six. Using a Taq polymerase supposedly appropriate for PCR amplification of GC-rich sequences had a much weaker effect. Our protocol should greatly facilitate sequencing and resequencing of the GC-richest regions of heterogeneous genomes, in combination with standard short-read and long-read technologies

Avian Genomes Revisited: Hidden Genes Uncovered and the Rates versus Traits Paradox in Birds

International audienceAccording to current assemblies, avian genomes differ from those of the other lineages of amniotes in 1) containing a lower number of genes; 2) displaying a high stability of karyotype and recombination map; and 3) lacking any correlation between evolutionary rates (dN/dS) and life-history traits, unlike mammals and nonavian reptiles. We question the reality of the bird missing genes and investigate whether insufficient representation of bird gene content might have biased previous evolutionary analyses. Mining RNAseq data, we show that the vast majority of the genes missing from avian genome assemblies are actually present in most species of birds. These mainly correspond to the GC-rich fraction of the bird genome, which is the most difficult to sequence, assemble and annotate. With the inclusion of these genes in a phylogenomic analysis of high-quality alignments, we uncover a positive and significant correlation between the ratio of nonsynonymous to synonymous substitution rate (dN/dS) and life-history traits in Neoaves. We report a strong effect of GC-biased gene conversion on the dN/dS ratio in birds and a peculiar behavior of Palaeognathae (ostrich and allies) and Galloanserae (chickens, ducks and allies). Avian genomes do not contain fewer genes than mammals or nonavian reptiles. Previous analyses have overlooked $15% of the bird gene complement. GC-rich regions, which are the most difficult to access, are a key component of amniote genomes. They experience peculiar molecular processes and must be included for unbiased functional and comparative genomic analyses in birds

Polymorphism Data Assist Estimation of the Nonsynonymous over Synonymous Fixation Rate Ratio omega for Closely Related Species

The ratio of nonsynonymous over synonymous sequence divergence, dN/dS, is a widely used estimate of the nonsynonymous over synonymous fixation rate ratio omega, which measures the extent to which natural selection modulates protein sequence evolution. Its computation is based on a phylogenetic approach and computes sequence divergence of protein-coding DNA between species, traditionally using a single representative DNA sequence per species. This approach ignores the presence of polymorphisms and relies on the indirect assumption that new mutations fix instantaneously, an assumption which is generally violated and reasonable only for distantly related species. The violation of the underlying assumption leads to a time-dependence of sequence divergence, and biased estimates of omega in particular for closely related species, where the contribution of ancestral and lineage-specific polymorphisms to sequence divergence is substantial. We here use a time-dependent Poisson random field model to derive an analytical expression of dN/dS as a function of divergence time and sample size. We then extend our framework to the estimation of the proportion of adaptive protein evolution alpha. This mathematical treatment enables us to show that the joint usage of polymorphism and divergence data can assist the inference of selection for closely related species. Moreover, our analytical results provide the basis for a protocol for the estimation of omega and alpha for closely related species. We illustrate the performance of this protocol by studying a population data set of four corvid species, which involves the estimation of omega and alpha at different time-scales and for several choices of sample sizes