RNF12 X-linked intellectual disability mutations disrupt E3 ligase activity and neural differentiation

Summary: X-linked intellectual disability (XLID) is a heterogeneous syndrome affecting mainly males. Human genetics has identified >100 XLID genes, although the molecular and developmental mechanisms underpinning this disorder remain unclear. Here, we employ an embryonic stem cell model to explore developmental functions of a recently identified XLID gene, the RNF12/RLIM E3 ubiquitin ligase. We show that RNF12 catalytic activity is required for proper stem cell maintenance and neural differentiation, and this is disrupted by patient-associated XLID mutation. We further demonstrate that RNF12 XLID mutations specifically impair ubiquitylation of developmentally relevant substrates. XLID mutants disrupt distinct RNF12 functional modules by either inactivating the catalytic RING domain or interfering with a distal regulatory region required for efficient ubiquitin transfer. Our data thereby uncover a key function for RNF12 E3 ubiquitin ligase activity in stem cell and neural development and identify mechanisms by which this is disrupted in intellectual disability. : Bustos et al. show that the RNF12 E3 ubiquitin ligase regulates stem cell maintenance and neuronal differentiation. They demonstrate that RNF12/RLIM mutations identified in X-linked intellectual disability patients disrupt regions required for catalytic activity, which leads to compromised stem cell maintenance and abnormal neural differentiation. Keywords: ubiquitin, protein ubiquitylation, E3 ubiquitin ligase, proteasomal degradation, RNF12/RLIM, intellectual disability, X-linked intellectual disability, embryonic stem cells, neural differentiatio

Self-Assembled Plasmonic DNA Origami Nanoantennas for Diagnostics Applications with Low-Tech Devices

The DNA origami technique provides an unprecedented method to create multiple copies of well-defined self-assembled nanostructures.1 Methods of modern chemistry allow to functionalize DNA with molecules and functional groups of interest. Exploiting these features we designed a pillar-shaped 3D DNA origami nanostructure functionalized with biotins for the surface immobilization and docking strands allowing to precisely position plasmonic nanoparticles. Upon illumination with freely propagating light, the local electric field between nanoparticles increases and a dye placed in the plasmonic hotspot exhibits a fluorescence gain of several orders of magnitude.2 In our present work, we modified a hotspot region with molecular recognition units (molecular beacon3 or sandwich assay) to detect an enhanced signal only in the presence of a specific nucleic acid target (Figure 1)

Systems analysis of RhoGEF and RhoGAP regulatory proteins reveals spatially organized RAC1 signalling from integrin adhesions.

Rho GTPases are central regulators of the cytoskeleton and, in humans, are controlled by 145 multidomain guanine nucleotide exchange factors (RhoGEFs) and GTPase-activating proteins (RhoGAPs). How Rho signalling patterns are established in dynamic cell spaces to control cellular morphogenesis is unclear. Through a family-wide characterization of substrate specificities, interactomes and localization, we reveal at the systems level how RhoGEFs and RhoGAPs contextualize and spatiotemporally control Rho signalling. These proteins are widely autoinhibited to allow local regulation, form complexes to jointly coordinate their networks and provide positional information for signalling. RhoGAPs are more promiscuous than RhoGEFs to confine Rho activity gradients. Our resource enabled us to uncover a multi-RhoGEF complex downstream of G-protein-coupled receptors controlling CDC42-RHOA crosstalk. Moreover, we show that integrin adhesions spatially segregate GEFs and GAPs to shape RAC1 activity zones in response to mechanical cues. This mechanism controls the protrusion and contraction dynamics fundamental to cell motility. Our systems analysis of Rho regulators is key to revealing emergent organization principles of Rho signalling