: Biochemiker/in

TUD Dresden University of Technology, as a University of Excellence, is one of the leading and most dynamic research institutions in the country. Founded in 1828, today it is a globally oriented, regionally anchored top university as it focuses on the grand challenges of the 21st century. It develops innovative solutions for the world's most pressing issues. In research and academic programs, the university unites the natural and engineering sciences with the humanities, social sciences and medicine. This wide range of disciplines is a special feature, facilitating interdisciplinarity and transfer of science to society. As a modern employer, it offers attractive working conditions to all employees in teaching, research, technology and administration. The goal is to promote and develop their individual abilities while empowering everyone to reach their full potential. TUD embodies a university culture that is characterized by cosmopolitanism, mutual appreciation, thriving innovation and active participation. For TUD diversity is an essential feature and a quality criterion of an excellent university. Accordingly, we welcome all applicants who would like to commit themselves, their achievements and productivity to the success of the whole institution.   At the Center for Molecular Bioengineering (B CUBE), the Chair of BioNano-Tools offers a temporary full-time position as   Research Associate / PhD Student for a MSCA-DN project (m/f/x)   starting September 1, 2025. The position is limited until August 31, 2028. The period of employment is governed by the Fixed Term Research Contracts Act (Wissenschaftszeitvertragsgesetz – WissZeitVG). The doctoral candidate will receive a salary, including a living allowance, a mobility allowance and a family allowance (if eligible). Applicants may be of any nationality. However, at the date of recruitment, the applicant must not have resided or carried out his/her main activity (work, studies etc.) in Germany for more than 12 months in the last 3 years immediately prior to the recruitment. Tasks: (i) biochemical preparation of motors proteins, (ii) setup of in vitro motility assays, (iii) development of strategies to mechanically couple molecular motors, (iv) dynamic acquisition of motor-driven cargo movement by high-resolution fluorescence microscopy and/or magnetic/optical tweezers, (iv) quantitative image processing, data analysis and modeling. The project is funded by the MARIE SKŁODOWSKA CURIE ACTIONS (MSCA) Doctoral Network (DN) MOtorized NAnomachines: fundamentaLs, InnovationS, Applications (MONALISA) within the Horizon 2020 Program of the European Commission [https://cordis.europa.eu/project/id/101169136]. DN MONALISA, a consortium of nine partners composed of high-profile universities, research institutions and companies located in Europe, will train 15 doctoral candidates in a highly innovative and interdisciplinary scientific network. Scientifically, artificial molecular machine research and technologies are critical fields with the potential to offer significant benefits to chemical synthesis, medical technologies and treatment, smart materials, and nanotechnology. However, due to their novelty, there is a shortage of specialists in this sector, resulting in limited research manpower. With the support of the Marie Skłodowska-Curie Actions program, the MONALISA project will bring together specialists, Nobel laureates, prestigious institutions, and various non-academic partners to develop and implement an innovative training program for doctoral candidates. This extensive, in-depth training from expert researchers will enable the candidates to gain a deep understanding of the field and transform their findings into innovative solutions. In this research project, the doctoral candidate will aim to reconstitute artificial systems that mimic the oscillatory behavior observed in biological processes. Thereby, the focus will be on designing and investigating systems (i) that involve the bidirectional movement of cargo bound to motor proteins with opposite polarities along microtubules and (ii) where two or more microtubules are moved relative to each other by motor proteins, effectively cross-linking these filaments. To delve deeper into the underlying mechanisms, the doctoral candidate will employ various strategies to link and couple motor proteins together within synthetic engineered systems. This may involve introducing mechanical constraints, such as restoring forces, to the system. The doctoral candidate will investigate the minimal set of components that are needed to generate robust oscillations. The outcomes of this research will offer valuable insights for designing innovative, nanoscale systems with controllable, oscillatory behavior. The key tasks of the doctoral candidate are: (i) to manage and carry out research projects, (ii) to attend and participate in research and training activities within the MONALISA network and local courses, (iii) to write scient...