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.
For more details on the projects offered and how to apply via the online form using the apply button.
The deadline for applications is 1 April 2026. Interviews will take place at IMB in Mainz on 22 & 23 June 2026.
Starting date: 1 July - 31 December 2026
PhD Position: Regulation of genomic parasites by small non-coding RNAs (m/f/d)
Activities and responsibilities
The research group of René Ketting offers the following PhD project:
The genomes of basically all living organisms on our planet are invaded by genetic elements called transposable elements (TEs). These TEs can be considered as parasites in our genome, although they also contribute to proper gene regulation and other aspects of normal cellular homeostasis. TEs tend to be most active in the germ cells, as their activity in these cells will be remembered in new generations. Hence, the control of these elements is particularly important in these cells. One of the major defense mechanisms that helps to keep TEs in check is known as the piRNA pathway. This mechanism is driven by small non-coding RNAs (piRNAs) that help to guide the effector proteins to their targets in a sequence specific manner. Hence, deciding which RNAs will be turned into piRNAs is a crucial step. How piRNA precursor transcripts are selected and processed is poorly understood. Also, these reactions tend to occur in subcellular regions known as condensates, or germ granules. This project will help address how subcellular organization, precursor selection and processing are interconnected.
PhD Project: Interactions between small RNAs and condensates
We use the nematode C. elegans to unravel the mechanisms that steer small RNA pathways in the germ cells. This system offers great opportunities in genetic manipulation and offers fast generations times, enabling experiments that are unthinkable in slower model systems such as that in mice. C. elegans also offers a unique view on how small RNA pathways evolve, and how they re-use already existing molecular machinery to change them into machines that enable the intricate genomic immune system that is described briefly above. At the same time, by understanding how ‘basic’ machinery can be re-purposed we also learn new things about that machinery itself, making this research truly fundamental, aiming to understand the molecular biology of the cell.
In the past years we have made big steps in understanding how small RNAs can be made. We have identified novel enzymes and complexes that act together to stabilize and process specific transcripts into small RNAs, and where these machineries can come from. In the new PhD project we will aim to continue along these lines and look at novel factors that we have recently identified and how these affect the small RNA pathways. Some of these relate to germ granule formation, a type of condensate within the cell in which proteins and RNAs can become concentrated. The role of these is rather unclear, as is the role of condensates in cells in general. Using small RNA research we aim to answer questions like “what is the functional relevance of being enriched in a condensate?” and “how are these condensates regulated?”. Other factors related to the regulation of catalytic parts of the small RNA machinery more directly, such as a novel protein that regulates an RNA directed RNA polymerase. Finally, we aim to extend our recent findings on so-called Schlafen-domain enzymes into mammalian cells.
The exact PhD project will be a result of discussions between you and the group, aiming to match interest, expertise and feasibility as good as we possibly can.
If you are interested in this project, please select Ketting as your group preference in the IPP application platform.
The genomes of basically all living organisms on our planet are invaded by genetic elements called transposable elements (TEs). These TEs can be considered as parasites in our genome, although they also contribute to proper gene regulation and other aspects of normal cellular homeostasis. TEs tend to be most active in the germ cells, as their activity in these cells will be remembered in new generations. Hence, the control of these elements is particularly important in these cells. One of the major defense mechanisms that helps to keep TEs in check is known as the piRNA pathway. This mechanism is driven by small non-coding RNAs (piRNAs) that help to guide the effector proteins to their targets in a sequence specific manner. Hence, deciding which RNAs will be turned into piRNAs is a crucial step. How piRNA precursor transcripts are selected and processed is poorly understood. Also, these reactions tend to occur in subcellular regions known as condensates, or germ granules. This project will help address how subcellular organization, precursor selection and processing are interconnected.
PhD Project: Interactions between small RNAs and condensates
We use the nematode C. elegans to unravel the mechanisms that steer small RNA pathways in the germ cells. This system offers great opportunities in genetic manipulation and offers fast generations times, enabling experiments that are unthinkable in slower model systems such as that in mice. C. elegans also offers a unique view on how small RNA pathways evolve, and how they re-use already existing molecular machinery to change them into machines that enable the intricate genomic immune system that is described briefly above. At the same time, by understanding how ‘basic’ machinery can be re-purposed we also learn new things about that machinery itself, making this research truly fundamental, aiming to understand the molecular biology of the cell.
In the past years we have made big steps in understanding how small RNAs can be made. We have identified novel enzymes and complexes that act together to stabilize and process specific transcripts into small RNAs, and where these machineries can come from. In the new PhD project we will aim to continue along these lines and look at novel factors that we have recently identified and how these affect the small RNA pathways. Some of these relate to germ granule formation, a type of condensate within the cell in which proteins and RNAs can become concentrated. The role of these is rather unclear, as is the role of condensates in cells in general. Using small RNA research we aim to answer questions like “what is the functional relevance of being enriched in a condensate?” and “how are these condensates regulated?”. Other factors related to the regulation of catalytic parts of the small RNA machinery more directly, such as a novel protein that regulates an RNA directed RNA polymerase. Finally, we aim to extend our recent findings on so-called Schlafen-domain enzymes into mammalian cells.
The exact PhD project will be a result of discussions between you and the group, aiming to match interest, expertise and feasibility as good as we possibly can.
If you are interested in this project, please select Ketting as your group preference in the IPP application platform.
Qualification profile
Are you an ambitious scientist looking to push the boundaries of research while interacting with colleagues from multiple disciplines and cultures? Then joining the IPP is your opportunity to give your scientific career a flying start!
All you need is:
All you need is:
- Master or equivalent
- Interactive personality & good command of English
- 2 letters of reference
We offer
- Exciting, interdisciplinary projects in a lively international environment, with English as our working language
- Advanced training in scientific techniques and professional skills
- Access to our state-of-the-art Core Facilities and their technical expertise
- Fully funded positions with financing until the completion of your thesis
- A lively community of more than 200 PhD students from 44 different countries
For more details on the projects offered and how to apply via the online form using the apply button.
The deadline for applications is 1 April 2026. Interviews will take place at IMB in Mainz on 22 & 23 June 2026.
Starting date: 1 July - 31 December 2026
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