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connections with laboratory specialists, researchers, and clinicians. The Functional Genomics subteam develops mass‑spectrometry‑based proteomics, glycoproteomics, and metabolomics methodologies
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connections with laboratory specialists, researchers, and clinicians. The Functional Genomics subteam develops mass‑spectrometry‑based proteomics, glycoproteomics, and metabolomics methodologies
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in advanced bioimaging (including super-resolution, confocal and electron microscopy), genomics, proteomics, metabolomics, high-performance computing and field research. We promote research
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clinical research on pharmacology, toxicology, and exposure science. Dr. Bernstein’s research team has access to outstanding facilities of Genomics, Genetics, Proteomics, Confocal and high-content imaging
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Cellular and Molecular Structure and Function; Computational and Systems Biology; Functional Genomics and Proteomics; Genetic Models of Development and Disease; Molecular Medicine and Human Genetics; and
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microscopy, CRISPR, omics approaches (Chip-seq, proteomics), or bioinformatics. How to apply: Cover letter: your motivation to apply for this position and description of your research interests. CV: Highlight
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grant-funded research as directed by the PI (Dr. Zander). This research will include performing genetic, (epi)genomics and proteomic analyses in crop and medicinal plant species. It is expected
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at the Department of Medical Biochemistry and Biophysics, which offers an international, collaborative, and open-minded research environment. Please visit the lab’s webpage for more information: https://www.umu.se/en
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(DC2, DC3, DC12 or DC13) with expected synergies between DC2-DC3 (in vitro models, proteomics methodology) and DC12-DC13 (receptor modelling and engineering). The students will also collaborate with
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. This project will utilise a combination of molecular and cell biology approaches, microbiology and advanced quantitative proteomic methods. ZDHHC5 knockout cells will be used to study the perturbed cell surface