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record in exploring urology‑relevant sensory mechanisms, with translational relevance for conditions such as chronic pain, bladder dysfunction, and other urinary tract disorders. The urinary bladder plays
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to unravel how plants control gene expression across different tissues and stress conditions by combining single-cell genomics, artificial intelligence, and synthetic biology. Apart from shedding light on
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and stress conditions by combining single-cell genomics, artificial intelligence, and synthetic biology. Apart from shedding light on the fundamental aspects of transcriptional control, this project
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opportunities! Our team of approximately 20 researchers is dedicated to unravelling the underlying causes of CNS disorders, identifying therapeutic targets and assessing their potential for intervention. We're
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temperature signalling in plants, such as the model plant Arabidopsis thaliana and the crop plants wheat and soybean. To unravel this, we focus on dynamic changes in protein phosphorylation status, since
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-resistant forms. By identifying the biochemical factors that govern carbon storage in the ocean, we hope to better assess the impact of human activities on this reservoir and provide transferable results
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disease into specific subclasses. You will develop AI algorithms to train models that predict if individuals (from which we create circuits) are prone to develop disease and to identify conditions that have
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significant potential for applications in agriculture and human health. However, many remain undiscovered, as their biosynthesis is often inactive under laboratory conditions. Our goal is to uncover these novel
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, CRISPR/Cas9 gene editing, viral vectors, conditional knockout mice, optogenetics, and in vivo imaging. The successful candidate will be based in Leuven, Belgium. The two labs will interact regularly via