-
*Computational approaches to biomolecular assembly *Mapping ribonucleoprotein structure *Proteomics approaches The project lead will be based in the Brangwynne lab at Princeton University, but will have the
-
to apply: cell culture, CRISPR genome editing techniques, genomics, proteomics, microscopy, model systems such as C.elegans, RNA biology; interest in quantitative approaches would also be helpful. Candidates
-
-evolutionary biology -ecological genetics -metabolomics -proteomics -cell signaling -bacterial/yeast/animal cell molecular biology and genetics
-
to computational analysis of and machine-learning approaches to mass spectrometry-based metabolomics and/or proteomics data. Positions are available starting March 2024, and will remain open until excellent fits
-
to apply: cell culture, CRISPR genome editing techniques, genomics, proteomics, microscopy, model systems such as C.elegans, RNA biology; interest in quantitative approaches would also be helpful. Candidates
-
*Computational approaches to biomolecular assembly *Mapping ribonucleoprotein structure *Proteomics approaches The project lead will be based in the Brangwynne lab at Princeton University, but will have the
-
*Computational approaches to biomolecular assembly *Mapping ribonucleoprotein structure *Proteomics approaches The project lead will be based in the Brangwynne lab at Princeton University, but will have the
-
*Mapping ribonucleoprotein structure *Proteomics approaches The project lead will be based in the Brangwynne lab at Princeton University, but will have the opportunity to collaborate with multiple labs and
-
learning for parsing biological data sets (genomics, proteomics, imaging, neuroscience), bioinformatics, molecular dynamics simulations, and related areas at the interface of computer/data science and the
-
-metabolomics -proteomics -cell signaling -bacterial/yeast/animal cell molecular biology and genetics