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Background Avocado ( Persea americana ) is an economically important tropical fruit considered to be a good source of fatty acids. Despite its importance, the molecular and cellular characterization of biochemical and developmental processes in avocado is limited due to the lack of transcriptome and genomic information. Results The transcriptomes of seeds, roots, stems, leaves, aerial buds and flowers were determined using different sequencing platforms. Additionally, the transcriptomes of three different stages of fruit ripening (pre-climacteric, climacteric and post-climacteric) were also analyzed. The analysis of the RNAseqatlas presented here reveals strong differences in gene expression patterns between different organs, especially between root and flower, but also reveals similarities among the gene expression patterns in other organs, such as stem, leaves and aerial buds (vegetative organs) or seed and fruit (storage organs). Important regulators, functional categories, and differentially expressed genes involved in avocado fruit ripening were identified. Additionally, to demonstrate the utility of the avocado gene expression atlas, we investigated the expression patterns of genes implicated in fatty acid metabolism and fruit ripening. Conclusions A description of transcriptomic changes occurring during fruit ripening was obtained in Mexican avocado, contributing to a dynamic view of the expression patterns of genes involved in fatty acid biosynthesis and the fruit ripening process.

The genome of the carnivorous bladderwort plant Utricularia gibba is described here; despite having undergone at least three rounds of whole-genome duplication, its genome is unusually small and virtually devoid of intergenic DNA. Tiny bladderwort genome sequenced Bladderworts are carnivorous plants found in fresh water and damp soil, where they feed on minute prey such as protozoa and rotifers. They lack clearly distinguishable roots, leaves or stems but produce tiny orchid-like flowers. The genome of one of these plants, Utricularia gibba , has now been sequence and analysed. The genome is unusually small (at 82 megabases), in part due to the near absence of intergenic DNA, but it encodes a typical number of genes for a plant and is sufficient to regulate the development and reproduction of a complex organism. Though Although remaining small, the genome has undergone at least three rounds of whole-genome duplication since common ancestry with tomato ( Solanum ) and grape ( Viti s). It has been argued that the evolution of plant genome size is principally unidirectional and increasing owing to the varied action of whole-genome duplications (WGDs) and mobile element proliferation 1 . However, extreme genome size reductions have been reported in the angiosperm family tree. Here we report the sequence of the 82-megabase genome of the carnivorous bladderwort plant Utricularia gibba . Despite its tiny size, the U. gibba genome accommodates a typical number of genes for a plant, with the main difference from other plant genomes arising from a drastic reduction in non-genic DNA. Unexpectedly, we identified at least three rounds of WGD in U. gibba since common ancestry with tomato ( Solanum ) and grape ( Vitis ). The compressed architecture of the U. gibba genome indicates that a small fraction of intergenic DNA, with few or no active retrotransposons, is sufficient to regulate and integrate all the processes required for the development and reproduction of a complex organism.