Räumlich-zeitliche Kontrolle der Rho Protein Signalwege

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Dr. Oliver Rocks

31.1: Max-Delbrück Haus (Hochbau)

Raum 2029

Tel. 3610



Rho family GTPase proteins are the master regulators of the cytoskeleton, controlling fundamental morphogenetic processes ranging from embryonic development to wound repair. We investigate how the signaling function of Rho GTPases is regulated in space and time and how its specificity is achieved.

Rho activity is controlled by three factors: GTPase activating proteins (RhoGAPs) and guanine nucleotide exchange factors (RhoGEFs), which drive the GDP/GTP activity cycle, and guanine nucleotide dissociation inhibitors (GDIs), which keep the lipid-anchored GTPases in the cytosol. Our genome encodes as many as 145 RhoGEFs and GAPs. These multi-domain proteins can target the GTPases to distinct cellular locations and act as scaffolds to connect to upstream cues, further signaling programs and downstream effectors.

We have previously assembled a complete cDNA library of all RhoGEFs and GAPs and performed a systematic analysis of their interactors, localization and substrate specificities. Combining advanced microscopy with cell biology and work in model organisms, we now exploit this unique dataset and toolbox to characterize novel RhoGEFs and GAPs in different signaling contexts. These currently include: control of cell-cell adhesion, guidance receptor and G protein coupled receptor signaling, with implications in muscle development, endocrine signaling and neural cancer development.

Another research interest is to analyze the membrane interaction dynamics of the lipid-anchored Rho proteins and how it is regulated. How on membranes Rho signaling complexes are formed, maintained and disassembled is not well studied. We use state-of-the-art imaging to elucidate such modes of temporal Rho signal regulation.