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the possibility of evolutionary convergence. Training and Skills Development You will gain expertise in: Molecular biology: RNA/DNA extraction, library preparation, next-generation sequencing Bioinformatics
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properties. Fungi are a rich source of such compounds, with notable examples including penicillin, lovastatin, and ciclosporin. Advances in genome sequencing and bioinformatics have revealed that fungal
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decisions about personalised phage therapy. The expected workload is mainly computational, using bioinformatics analyses to investigate the microbiome and phageome with supporting laboratory work for DNA
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compounds, with notable examples including penicillin, lovastatin, and ciclosporin. Advances in genome sequencing and bioinformatics have revealed that fungal genomes contain numerous biosynthetic gene
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-quality, chromosome-level genome sequences and perform additional genome resequencing of species from different mimicry rings. The project combines molecular biology with cutting-edge bioinformatics
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species, we can hopefully also contribute to better safeguarding its future. The student will receive broad training in molecular biology, historical DNA, genomics, bioinformatics and population genetics
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methodologies including, DNA isolation, library preparation and sequencing as well as bioinformatic skills to analyse the acquired sequencing data. The project will be supervised by Dr Hellmich and Prof Rushworth
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critical resistance dynamics. The project will use molecular microbiology and bioinformatics to compare traditional indicators with metagenomic data, assessing the validity of current monitoring practices
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undertake fieldwork (optional) to collect samples and extend the fitness database, molecular work to sequence additional genomes, and bioinformatics to define mutation-effect scores, thus generating
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structural variation analysis. Training: You will develop a broad set of skills in computational biology, genetic analysis, bioinformatics, and scientific writing. You will also gain expertise in evolutionary