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| general:community_news [2020/04/29 08:35] – sisamakis | general:community_news [2020/05/04 12:11] (current) – sisamakis |
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| * **29.04.20** [[https://www.fret.community/announcement-protein-folding-and-dynamics-webinar/|Protein folding and dynamics Webinar-Series.]] \\ \\ | * **29.04.20** [[https://www.fret.community/announcement-protein-folding-and-dynamics-webinar/|Protein folding and dynamics Webinar-Series.]] \\ \\ |
| * **14.04.20** [[https://analyticalscience.wiley.com/do/10.1002/was.00050003/full/bioimagedataanalysis.pdf|Bioimage Data Analysis.]] New Expanded version of a nice open-source introduction. \\ \\ | * **14.04.20** [[https://analyticalscience.wiley.com/do/10.1002/was.00050003/full/bioimagedataanalysis.pdf|Bioimage Data Analysis.]] New Expanded version of a nice open-source introduction. \\ \\ |
| * **14.04.20** [[https://science.sciencemag.org/content/368/6486/78|De novo design of protein logic gates.]] Fundamendal enzymology work. Chen et al. describe the design of logic gates that can regulate protein association. The gates were built from small, designed proteins that all have a similar structure but where one module can be designed to interact specifically with another module. Using monomers and covalently connected monomers as inputs and encoding specificity through designed hydrogen-bond networks allowed the construction of two-input or three-input gates based on competitive binding. \\ \\ | * **14.04.20** [[https://science.sciencemag.org/content/368/6486/78|De novo design of protein logic gates.]] Fundamental enzymology work. Chen et al. describe the design of logic gates that can regulate protein association. The gates were built from small, designed proteins that all have a similar structure but where one module can be designed to interact specifically with another module. Using monomers and covalently connected monomers as inputs and encoding specificity through designed hydrogen-bond networks allowed the construction of two-input or three-input gates based on competitive binding. \\ \\ |
| * **31.03.20** FRET community has a new advisory board, [[https://www.fret.community/|FRET community]]. Happy that Dr. Marcelle König , a senior scientist in PicoQuant was elected. \\ \\ | * **31.03.20** FRET community has a new advisory board, [[https://www.fret.community/|FRET community]]. Happy that Dr. Marcelle König , a senior scientist in PicoQuant was elected. \\ \\ |
| * **31.03.20** Extremely helpful reference paper about confocal microscopy. [[https://www.nature.com/articles/s41596-020-0313-9|Tutorial: guidance for quantitative confocal microscopy]]. Available as a poster [[https://www.nature.com/articles/s41596-020-0307-7|here.]] \\ \\ | * **31.03.20** Extremely helpful reference paper about confocal microscopy. [[https://www.nature.com/articles/s41596-020-0313-9|Tutorial: guidance for quantitative confocal microscopy]]. Available as a poster [[https://www.nature.com/articles/s41596-020-0307-7|here.]] \\ \\ |
