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, molecular, physiological, and ultrastructural levels by tracing the acquisition of wild-type and genetically modified symbionts and exploring their interactions with the host using microscopic, metagenomic
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of symbiont acquisition and host-symbiont interaction at the ecological, molecular, physiological, and ultrastructural levels by tracing the acquisition of wild-type and genetically modified symbionts and
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their resistance to environmental stresses while improving yields and sustainability. The successful candidate will focus on the dynamic organization of chloroplast pathways in response to environmental stimuli (e.g
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preferred, but not required) are desired. Experiences with catalysis (biological, homogeneous, or heterogeneous), excited-state simulation methods, multiscale simulations (broadly defined), molecular dynamics
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Medicinal Natural Product Biochemistry in our dynamic and interdisciplinary team. The successful candidate will work on a cutting-edge project involving the study of bioactive natural products from medicinal
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research in the field of Plant Medicinal Natural Product Biochemistry in our dynamic and interdisciplinary team. The successful candidate will work on a cutting-edge project involving the study of bioactive
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molecular dynamics, docking (e.g., IFD), metadynamics, and free energy perturbation (FEP) techniques. Construct and contribute to the development of software tools for simulation and analysis. Integrate and
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(broadly defined), molecular dynamics simulations, sampling techniques, machine learning, or quantum computing are big pluses. The candidate should have good communication skills, both oral and written, and
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improving yields and sustainability. The successful candidate will focus on the dynamic organization of chloroplast pathways in response to environmental stimuli (e.g., high-light stress and nutrition stress