Project description:To investigate the effect of aging on mitochondrial gene expression we isolated liver mitochondria from 4 12-week and 4 65-week C57BL/6N WT mice. We then isolated RNA and prepared the barcoded library using PCR-cDNA Barcoding Kit SQK-PCB109 and ran it on MinIOn R9.4.1 Flow cells.
Project description:Species identification of fragmentary bones remains a challenging task in archeology and forensics. A species identification method for such fragmentary bones that has recently attracted interest is the use of bone collagen proteins. We developed a method similar to DNA barcoding that reads collagen protein sequences in bone and automatically determines the species by performing sequence database searches. We tested our method using bone samples from 30 vertebrate species ranging from mammals to fish.
Project description:In the context of human evolution, the study of proteins may overcome the limitation of the high degradation of ancient DNA over time for providing biomolecular information useful to precise the phylogeny of hominid taxa. Here, we have analysed and compared the tooth proteome of five extant primates (human, gorilla, chimpanzee, orangutan and baboon) using a shotgun proteomics approach. Twenty five proteins were shared by the five datasets, and may be considered as the most representative tooth proteins with a chance of being retrieved from older samples. Some of them were identified by peptides specific to the species, thus allowing to draw up a combinatory panel of peptides with species signature that could be helpful for the taxonomic characterization of ancient samples
Project description:Genomic safe harbors (GSHs) are utilized as an ideal integration site for generating transgenic organisms and cells. Discovery of GSHs is one of the crucial factors for the advancement of basic and applied biology in the species. Such GSHs were discovered in Pv11 (Polypedilum vanderplanki) cell line, which can survive extreme desiccation. To identify the integration sites, high-molecular-weight genomic DNAs were extracted. The DNA libraries were prepared and sequenced with a Nanopore MinION sequencer. In the way to confirm that GSHs loci are localized in open chromatin regions we prepared ATAC-seq libraries, which were sequenced in Illumina HiSeq2500.
Project description:The need for species identification and taxonomic discovery has led to the development of innovative technologies for large-scale plant identification. DNA barcoding has been useful, but fails to distinguish among many species in species-rich plant genera, particularly in tropical regions. Here, we show that chemical fingerprinting, or “chemocoding”, has great potential for plant identification in challenging tropical biomes. Using untargeted metabolomics in combination with multivariate analysis, we constructed species-level fingerprints, which we define as chemocoding. We evaluated the utility of chemocoding with species that were defined morphologically and subject to next-generation DNA sequencing in the diverse and recently radiated neotropical genus, Inga (Leguminosae), both at single study sites and across broad geographic scales. Our results show that chemocoding is a robust method for distinguishing morphologically similar species at a single site and for identifying widespread species across continental-scale ranges. Given that species are the fundamental unit of analysis for conservation and biodiversity research, the development of accurate identification methods is essential. We suggest that chemocoding will be a valuable additional source of data for a quick identification of plants, especially for groups where other methods fall short.