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fidelity is experimentally challenging and we are using specially-developed methods for library prep for high-throughput sequencing to achieve this. The research involves next-generation sequence library
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experimentally challenging and we are using specially-developed methods for library prep for high-throughput sequencing to achieve this. The research involves next-generation sequence library preparation in
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clonal fate-mapping, flow cytometry, and various in vitro and in vivo stem cell assays. The projects that the new postdoc will primarily be involved in, will apply the same type of DNA sequencing analysis
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related to grain protein quality, aroma profiles, and protein structure-function relationship relevant to diverse food applications. The phenotypic data obtained will be aligned with genotypic data (e.g
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apply the same type of DNA sequencing analysis as in a recent publication in which we retrospectively (through phylogenetic analysis) lineage-fate mapped human HSCs (7). Projects will be pursued in part
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main focus on uveal melanoma. Analyse clinical, pathological and molecular genetic data, including next generation sequencing data. Prepare and coordinate applications for external research funding
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identification methods). Documented experience with Next Generation Sequencing and associated bioinformatics. Assessment criteria This is a career development position primarily focused on research. The position
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of 3D genome and epigenomic landscape orchestrates gene expression programs that underlie neuron-to-glioma communication. In this project, we will use single-cell sequencing methods, bioinformatics, and
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will use single-cell sequencing methods, bioinformatics, and genome editing approaches, as well as co-culture systems modeling neuron–glioma interactions, with the main focus on investigating the impact
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this, we will apply novel tools based on semi-permeable capsules, including various analytical and biochemical methods, molecular barcoding, sequencing, and high dimensional data analytics. The project will