The Collaborative Research Centre 960 (SFB960) ‘RNP biogenesis: assembly of ribosomes and non-ribosomal RNPs and control of their function’ has recently been awarded funding for another four years (see this post). The 18 group leaders (pictuerd below) will head 16 research and 3 service projects and a graduate school.

We are looking forward to four more years of collaborative research and exciting new findings.

Principal Investigators third funding period (from left to right): J. Medenbach, J. Griesenbeck, T. Heise, P. Milkereit, W. Seufert, A. Bruckmann, S. Ferreira-Cerca, M. Kretz, J. Perez-Fernandez, T. Dresselhaus, G. Längst, R. Sprangers, H. Tschochner, D. Grohmann, and C. Engel;
missing on the photo: G. Sommer, S. Sprunck, G. Meister, K. Grasser

Today, Moritz Freyberg joined the lab for his MSc work. He already spent some time with us for an extended practical and he will now continue to work on stress-mediated gene regulation in mammalian cells. Welcome back!

Picture courtesy of S. Buchhauser

Anna Bichler has joined the lab for her BSc thesis work. She will follow up on some novel candidate proteins that we found to be induced by the Unfolded Protein Response. A warm welcome to our new colleague!

In a collaborative effort spearheaded by the Ahrends lab at the ISAS (Leibniz-Institut für Analytische Wissenschaften) in Dortmund, we established a targeted proteomics approach aimed at analyzing components of the Unfolded Protein Response (UPR), an adaptive signal transduction pathway triggered by the accumulation of unfolded proteins in the endoplasmic reticulum. The UPR comprises an important cellular stress response that aims at re-instating cellular homoeostasis and it plays a key role in a variety of disorders (including diabetes, neurodegenerative disorders, and inflammatory processes). It has also emerged as an attractive target for therapeutic intervention in cancer due to its implication in tumor progression, malignancy and resistance to therapy. The newly developed high-resolution targeted proteomics strategy combines high specificity and sensitivity, allowing the accurate quantification of UPR proteins down to the lower attomol range in a straightforward way without any prior enrichment or fractionation approaches. This has allowed us to determine cellular protein copy numbers of UPR receptors, transducers and effectors, yielding novel insights into an important cellular stress response pathway.

Read the full manuscript at Scientific Reports: Nguyen et al. A sensitive and simple targeted proteomics approach to quantify transcription factor and membrane proteins of the unfolded protein response pathway in glioblastoma cells.

We could successfully extend funding of the Collaborative Research Centre 960 (SFB960) ‘RNP biogenesis: assembly of ribosomal and non-ribosomal RNPs and control of their function’. To continue our ambitious research programs, we are now seeking highly motivated PhD students. We offer a highly competitive research environment and exciting research projects. For more information click here.

Mutations that alter the activity of RNA-binding proteins or their abundance have been implicated in numerous diseases such as neurodegenerative disorders and various types of cancer. This highlights the importance of RBP proteostasis and the necessity to tightly control the expression levels and activities of RBPs. In many cases, RBPs engage in an auto-regulatory feedback by directly binding to and influencing the fate of their own mRNAs, exerting control over their own expression.

Together with our colleagues Michaela Müller-McNicoll from the Institute of Cell Biology and Neuroscience at the Goethe University Frankfurt, Oliver Rossbach from the Institute of Biochemistry at the Justus-Liebig-University Giessen, and Jingyi Hiu at the State Key Laboratory of Molecular Biology (CAS Center for Excellence in Molecular Cell Science, Shanghai Institute of Biochemistry and Cell Biology), we have reviewed RBP-mediated autogenous feedback regulation in eukaryotic organisms. For this feedback control, RBPs employ a variety of mechanisms operating at all levels of post-transcriptional regulation of gene expression to either to maintain protein abundance within a physiological range (exerting negative feedback) or to enforce and stabilize cell fate decisions through generation of binary, genetic on/off switches.

The article has just been published in the Journal of Molecular Cell Biology – click here to read the full version.

Good news: the SFB 960 ‘RNP biogenesis: assembly of ribosomes and non-ribosomal RNPs and control of their function’ has been granted another funding period. We are grateful for the generous support by the Deutsche Forschungsgemeinschaft (DFG) that will allow us and our colleagues to continue and extend our scientific programs and to ensure further top-level education of PhD students within the Graduate Research Academy RNA Biology. We want to thank all reviewers that were involved in the selection process and we are looking forward to another four years of exciting science!

A news article on this topic can also be found on the homepage of the University of Regensburg (in German): DFG verlängert Regensburger Sonderforschungsbereich zur Ribosomen-Entstehung

A collaborative effort lead by Björn Tews and supported by the research consortium ‘Systems Biology of the Unfolded Protein Response in Glioma’ (SUPR-G, generously funded by the BMBF in the framework of the e:med initiative) has resulted in a recent publication in Acta Neuropathologica that demonstrates a function of the peptide SPARC in migration and infiltrative growth of glioblastoma cells. SPARC production and secretion is enhanced via regulation of the UPR sensor IRE1 via AKT. SPARC secretion then prevents Nogo-A from inhibiting migration via RhoA. Advanced ultramicroscopy in undissected mouse brains reveals that gliomas require SPARC for invading into white matter structures and its depletion reduces tumor dissemination which significantly prolongs survival and improves response to cytostatic therapy. The discovery of a novel RhoA-IRE1 axis now provides a druggable target for interfering with SPARC production and underscores its therapeutic value. The full publiation can be accessed here.