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, dense packing, phase transition, and rehydration of plant storage proteins. The project combines expertise in plant protein biochemistry (BIA, Nantes), microfluidics and soft matter physics (LOF, Bordeaux
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candidate will use protein biochemistry, AI-guided protein design and molecular dynamics simulations to characterize natural and designed proteoforms of a novel regulatory node in barley temperature
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The University of North Carolina at Chapel Hill | Chapel Hill, North Carolina | United States | 12 days ago
computational methods and AI techniques for accelerated simulations of biomolecular recognition (such as drug binding and protein-protein interactions) and cellular signaling, and cutting-edge applications in
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microbiota. The guidelines (KDIGO 2024) recommend tailored diets (low-protein followed by high-protein) with a reduction in animal protein. These diets alter the microbiota, which is involved in the production
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barley signalling hubs that mediate the response to elevated temperature. Moreover, the successful candidate will use protein biochemistry, AI-guided protein design and molecular dynamics simulations
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daily maintenance. • Work independently to design and execute experiments and maintain hard-copy and electronic laboratory records. • Compile and analyze data. • Generate and maintain appropriate
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, metabolic enzymes). Experience with developing protein binders (e.g. nanobodies). Experience with molecular dynamics simulations. Strong quantitative assay development/analysis skills; experience bridging
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these resources, a one-stop-shop open access platform Turku Protein Core (TuProtCore) was established (https://turkuproteincore.utu.fi ). TuProtCore is governed by a steering committee composed of expert
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Our research aims to answer fundamental questions about how cells and organisms work at the molecular and biochemical level. We study the structures and properties of DNA, RNA and protein molecules
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for the investigation of membrane proteins. The central objective is to design electrochemical platforms compatible with plasmonic substrates (e.g., gold nanoantennas) that enable coupled infrared and Raman spectroscopic