PhD position in Super-Resolution Microscopy
Our research: Most bacteria in the biosphere live on surfaces. To efficiently colonize surfaces they must control attachment, surface-associated motility, and interactions between bacteria. Molecular motors are important for all of these aspects (1, 2). We aim at understanding their molecular mechanism, coordination, and role in biofilm formation. To this end, physicists and bio-scientists work in close collaboration.
Research techniques applied in this project will include, but are not limited to:
- establish super-resolution microscopy (Photo-Activated Localization Microscopy, PALM and Stochastic Optical Reconstitution Microscopy, STORM) for imaging of molecular motors
- design and test bacterial strains for PALM
- molecular microbiology
- development of image and data analysis algorithms
- developing and planning research projects
The position: Start in January 2017 or later (0.65 E13). Our laboratories are located at the Biocenter of the University of Cologne. PhD candidates are encouraged to apply for membership at the International Helmholtz Research School BioSoft (http://www.fz-juelich.de/ihrs-biosoft/EN/Home/home_node.html).
Your profile: Required criteria are: M.Sc. in biochemistry or comparable, skills in molecular cloning and strong interest in optical methods are mandatory. Experience in biophysics is beneficial but not essential. Applicants should be highly motivated, creative and independent individuals and have an excellent academic record.
1) Maier, B. & Wong, G.C.L. (2015) Trends Microbiol., 23(12), 775
2) Marathe, R. et al (2014) Nature Commun., 5, 3750
Bitte beziehen Sie sich bei Ihrer Bewerbung auf jobvector
Disabled individuals with equal personal and technical eligibility will be favored. The UoC is committed to increasing the ratio of women in research. Women are therefore invited to apply for this position.
Details der Stellenanzeige
Über Universität zu Köln
Our research group addresses the question how individual molecules (so-called molecular motors) and molecular complexes generate directed movement. To study mechanism, control, and function of molecular motors, a team of biologists, physicists, and biotechnologists combines physical techniques such as single molecule manipulation and quantitative image analysis with techniques from microbiology...Mehr über die Universität zu Köln