Beschreibung

Thinking of doing your PhD in the Life Sciences? The International PhD Programme (IPP) Mainz is offering talented scientists the chance to work on cutting edge research projects within the open call on “Molecular Mechanisms in Genome Stability & Gene Regulation”. As an IPP PhD student, you will join a community of exceptional scientists working on diverse topics ranging from how organisms age or how our DNA is repaired, to how epigenetics regulates cellular identity or neural memory. The research group of Helle Ulrich offers the following 2 PhD projects:

We study regulatory mechanisms that govern cellular quality control. On the one hand, we are interested in DNA repair pathways and factors that ensure complete and accurate DNA replication in the face of DNA damage. On the other hand, we investigate the diverse signalling functions of the posttranslational protein modifiers, ubiquitin and SUMO. Most of our ongoing projects are therefore situated at the interface between protein regulation and genome maintenance. In our research, we combine methods in genetics, molecular and cell biology with protein biochemistry and advanced genomics tools, using both budding yeast and human cells as models.

PhD Project 1: Deciphering the ubiquitin code

The ubiquitin system plays a key role in determining the function and fate of proteins in virtually every biological pathway, including genome maintenance and gene expression. Most often, ubiquitin signalling is mediated by polyubiquitin chains attached to selected substrate proteins. Depending on the linkage between the individual ubiquitin moieties, such chains can adopt many distinct geometries and - by means of linkage-selective downstream effectors - convey distinct biological effects. In this manner, the ubiquitin system is implicated in a variety of pathways that protect us from diseases such as cancer, neurodegeneration and inflammation.

In our lab, we have developed tools that allow us to a) induce the polyubiquitylation of relevant cellular proteins in a controlled and linkage-selective manner, as well as b) identify selectively modified substrates, the responsible enzymes and linkage-selective interaction partners. Here we will apply these tools to the investigation of ubiquitin signalling in selected biological contexts, including the processing of DNA polymerase-blocking lesions during DNA replication and the ubiquitin-dependent damage response pathway at DNA double-strand breaks. The project will involve biochemical as well as cell and molecular biological approaches and aims to eluciate the relevance of ubiquitin signalling in cellular resilience mechanisms against ageing and disease.

If you are interested in this project, please select Ulri_ubi as your group preference in the IPP application platform.

PhD Project 2: Mechanisms of replicative DNA damage bypass

One of the areas where ubiquitylation plays a major regulatory role is during genome replication, where DNA is particularly vulnerable to decay. Accordingly, the capacity of cells to deal with replication stress is a major factor protecting us from genome instability and cancer. Yet, the molecular details of how a replication fork travels across a damaged template are poorly understood. A multitude of factors, including the ubiquitylation of the replication factor PCNA, have been implicated in this process, but many questions remain: what determines whether a replisome stalls or simply moves across a lesion? How do replication forks reverse or collapse upon prolonged stalling? How do they recover? What is the influence of chromatin?

To address these questions, we are combining tools such as fluorescence microscopy, chromatin immunoprecipitation, next-generation sequencing, and quantitative mass spectrometry, to examine the influence of factors like chromatin structure, cell cycle, and replication timing on damage processing. We engage in collaborative research for real-time measurements of replication fork pro...