Master Plant Sciences

Breadcrumb Navigation


Ph.D. Positions on Translational Quality Control: Mechanisms, Role in Neurodegeneration, and Drug Discovery


September 2022: Ph.D. positions are available in the Joazeiro laboratory at the Center for Molecular
Biology of Heidelberg University (ZMBH), Germany.

A general interest of the lab is to investigate the function of E3 ubiquitin ligases in biology and disease. We also take advantage of our E3 ligase expertise to develop small-molecule protein degraders, or PROTACs, a new modality of molecular therapeutics (to know more, see

For the past decade, we have devoted much focus towards elucidating a protein quality control pathway we discovered, now known as Ribosome-associated Quality Control (RQC) (Bengtson & Joazeiro 2010. Nature 467:470). In RQC, the Listerin/Ltn1 E3 ligase mediates the proteolytic targeting of incomplete polypeptides produced when ribosomes stall during translation (Filbeck et al 2022. Mol Cell 82:1451).

Our research team undertakes different approaches to study fundamental RQC mechanisms, including biochemistry, structural biology, and mammalian tissue culture (e.g., Thrun et al 2021. Mol Cell 81:2112; Filbeck et al 2021. Mol Cell 81:104).

Importantly, we have found that mutations that impair RQC cause ALS-like neurodegenerative phenotypes in mice (Chu et al. 2009. PNAS 106:2097; Martin et al. 2020. Nature Comm 11:4625) so we also investigate the molecular mechanisms of neurodegeneration caused by RQC defects. Among other approaches, we utilize human iPSCs with CRISPR-engineered RQC mutations to generate i-motor neurons for analyses in tissue culture, either alone or as organoids.

Finally, we have recently made the landmark discovery that RQC also exists in bacteria (Lytvynenko et al 2019. Cell 178:76; Cerullo et al 2022. Nature 603:509). Whereas Listerin—like the ubiquitin system in general—is absent in prokaryotes, the Listerin co-factor Rqc2/NEMF has homologs in bacteria and archaea. We have found that bacterial Rqc2 itself is able to target aberrant nascent chains for degradation, by marking nascent chains with C-terminal alanine tails that function as degrons directly recognized by proteases! By studying related processes in diverse organisms, we expect to acquire insights and, ultimately, deeper understanding of the logic of the system and its evolution.

Positions are available to study any of the above topics. The candidate should have strong theoretical background in biochemistry and molecular genetics. Please see additional application information in our website,