Project description:Dendropsophus ebraccatus (hourglass treefrog) genome aDenEbr1

Project description:Dendropsophus ebraccatus (hourglass treefrog) genome aDenEbr1, paternal haplotype

Project description:Dendropsophus ebraccatus (hourglass treefrog) genome aDenEbr1, maternal haplotype

Project description:Dendropsophus ebraccatus overview

Project description:The "developmental hourglass" concept suggests that intermediate developmental stages are most resistant to evolutionary changes and that differences between species arise through divergence later in development. This high conservation during middevelopment is illustrated by the "waist" of the hourglass and it represents a low probability of evolutionary change. Earlier molecular surveys both on animals and on plants have shown that the genes expressed at the waist stage are more ancient and more conserved in their expression. The existence of such a developmental hourglass has not been explored in fungi, another eukaryotic kingdom. In this study, we generated a series of transcriptomic data covering the entire lifecycle of a model mushroom-forming fungus, Coprinopsis cinerea, and we observed a molecular hourglass over its development. The "young fruiting body" is the stage that expresses the evolutionarily oldest (lowest transcriptome age index) transcriptome and gives the strongest signal of purifying selection (lowest transcriptome divergence index). We also demonstrated that all three kingdoms-animals, plants, and fungi-display high expression levels of genes in "information storage and processing" at the waist stages, whereas the genes in "metabolism" become more highly expressed later. Besides, the three kingdoms all show underrepresented "signal transduction mechanisms" at the waist stages. The synchronic existence of a molecular "hourglass" across the three kingdoms reveals a mutual strategy for eukaryotes to incorporate evolutionary innovations.

Project description:Dendropsophus microcephalus

Project description:Dendropsophus rubicundulus clade

Project description:We report time-series transcriptome of developing bamboo shark fin buds and mouse forelimb buds, and open chromatin regions of developing mouse forelimb buds. The major contributions of this study are 1) transcriptomic data with an accurate orthology map for a systematic comparison between the two species; 2) high quality chromatin accessibility data for mouse limb development; 3) discovery of mass heterochronic genes between fins and limbs; 4) hourglass-shaped conservation between fins and limbs, providing insights into a general trend of gene regulatory evolution.

Project description:The M-bM-^@M-^Xdevelopmental hourglassM-bM-^@M-^Y concept suggests that intermediate developmental stages are most resistant to evolutionary changes and that differences between species arise through divergence later in development. This high conservation during mid-development is illustrated by the M-bM-^@M-^XwaistM-bM-^@M-^Y of the hourglass and it represents a low probability of evolutionary change. Earlier molecular surveys both on animals and plants have shown that the genes expressed at the waist stage are more ancient and more conserved in their expression. The existence of such a developmental hourglass has not been explored in fungi, another eukaryotic kingdom. In this study, we generated a series of transcriptomic data covering the entire lifecycle of a model mushroom-forming fungus, Coprinopsis cinerea, and we observed a molecular hourglass over its development. The M-bM-^@M-^Xyoung fruiting bodyM-bM-^@M-^Y (YFB) is the stage that expresses the evolutionarily oldest (lowest transcriptome age index, TAI) transcriptome and gives the strongest signal of purifying selection (lowest transcriptome divergence index, TDI). We also demonstrated that all three kingdoms M-bM-^@M-^S animals, plants and fungi M-bM-^@M-^S display high expression levels of genes in M-bM-^@M-^Xinformation storage and processingM-bM-^@M-^Y at the waist stages, whereas the genes in M-bM-^@M-^XmetabolismM-bM-^@M-^Y become more highly expressed later. Besides, the three kingdoms all show underrepresented M-bM-^@M-^Xsignal transductionM-bM-^@M-^Y at the waist stages. The synchronic existence of a molecular M-bM-^@M-^XhourglassM-bM-^@M-^Y across the three kingdoms reveals a mutual strategy for eukaryotes to incorporate evolutionary innovations. NimbleGen custom microarray with total RNAs extracted from two biological replicates for each stage of mycelium, fruiting initials (~2mm tall), stage 2 primordium (~1cm tall), young fruiting body (~2cm tall) and the fully-expanded cap of the mature fruiting body (~4cm tall). Mycelia from 5 agar plates were collected and pooled to form one replicate. For the other stages, 4-5 independent structures were isolated and their RNA extracted as one replicate sample.

Project description:The observation that animal morphology tends to be conserved during the embryonic phylotypic period led to the proposition that embryogenesis diverges more extensively early and late than in the middle, known as the hourglass model. This pattern of conservation is thought to reflect a major constraint on the evolution of animal body plans. Despite a wealth of morphological data confirming that there is often remarkable divergence in the early and late embryos of species from the same phylum, it is not yet known to what extent gene expression evolution, which plays a central role in the elaboration of different animal forms, underpins the morphological hourglass. Here we address this question using species-specific microarrays designed from six sequenced Drosophila species. Although it is generally appreciated that gene expression divergence plays a key role in the evolution of morphological diversity, no studies to date have addressed the extent to which expression divergence underpins the hourglass pattern at the genome-wide level. We test the molecular basis of the hourglass model of developmental evolution using gene expression data from six Drosophila species with sequenced genomes (D. ananassae, D. melanogaster, D. persimilis, D. pseudoobscura, D. simulans, and D. virilis) thereby enabling unambiguous quantitative comparisons across orthologous genes for a set of species separated by up to 40 million years. Gene expression levels were measured for 3019 genes, known to be expressed during embryonic development from RNA in situ data, at 2 hour intervals for the majority of embryogenesis using a microarray time-course with three biological replicates per species and four species-specific probes per gene.