Project description:Intrinsically disordered regions (IDRs) are essential for membrane receptor regulation but often remain unresolved in structural studies. TRPV4, a member of the TRP vanilloid channel family involved in thermo- and osmosensation, has a large N-terminal IDR of approximately 150 amino acids. With an integrated structural biology approach, we analyze the structural ensemble of the TRPV4 IDR and identify a network of regulatory elements that modulate channel activity in a hierarchical lipid-dependent manner through transient long-range interactions. A highly conserved autoinhibitory patch acts as a master regulator by competing with PIP2 binding to attenuate channel activity. Molecular dynamics simulations show that loss of the interaction between PIP2-binding site and the membrane reduces the force exerted by the IDR on the structured core of TRPV4. This work demonstrates that IDR structural dynamics are coupled to TRPV4 activity and highlights the importance of IDRs for TRP channel function and regulation.

Project description:In order to investigate the dynamic regulation of the APC/C by intrinsically disordered regions (IDRs) upon phosphorylation, we employed cross-linking mass spectrometry (CLMS). Given that the phosphorylation of Apc1-300L (IDR in Apc1) is a key determinant in its release from the co-activator binding site, we compared the interaction profiles of unphosphorylated and hyper-phosphorylated rAPC/C_WT complexes. The CLMS analysis highlights not only known interactions consistently identified within APC/C complexes, regardless of phosphorylation status, but also dynamic IDR-mediated interactions that are lost upon phosphorylation or are phosphorylation-dependent. Additionally, the data indicate that phosphorylation significantly reduces Apc1-300L's interaction with Apc8-L (IDR in Apc8) and Apc6, suggesting Apc1-300L's dislocation from the co-activator Cdc20 binding site, thereby facilitating Cdc20 loading onto the APC/C.

Project description:Intrinsically disordered regions (IDRs) are abundant within eukaryotic proteins, but their sequence-function relationship remains poorly understood. IDRs of transcription factors (TFs) can direct promoter selection and recruit coactivators, as exemplified by the budding-yeast TF- Msn2. To examine how low-complexity IDRs encode multiple functions, we compared genomic binding preferences, gene induction, and coactivator recruitment amongst a large set of designed Mns2-IDR mutants. We show that multiple regions across the >500AA IDR contribute to both functions. Yet, transcription activity was readily disrupted by variants having no consequences on Msn2 binding. Our data attribute this differential sensitivity to the integration of relaxed, composition-based code directing binding preferences with a more stringent, motif-based code controlling the recruitment of coactivators and transcription activity. Interwoven sequence grammar may present a general paradigm through which low-complexity IDRs encode multiple functions.

Project description:Intrinsically disordered regions (IDRs) are abundant within eukaryotic proteins, but their sequence-function relationship remains poorly understood. IDRs of transcription factors (TFs) can direct promoter selection and recruit coactivators, as exemplified by the budding-yeast TF- Msn2. To examine how low-complexity IDRs encode multiple functions, we compared genomic binding preferences, gene induction, and coactivator recruitment amongst a large set of designed Mns2-IDR mutants. We show that multiple regions across the >500AA IDR contribute to both functions. Yet, transcription activity was readily disrupted by variants having no consequences on Msn2 binding. Our data attribute this differential sensitivity to the integration of relaxed, composition-based code directing binding preferences with a more stringent, motif-based code controlling the recruitment of coactivators and transcription activity. Interwoven sequence grammar may present a general paradigm through which low-complexity IDRs encode multiple functions.

Project description:Idiosyncratic drug reactions (IDRs) cause significant morbidity and mortality. In an animal model of IDRs, 50-80% of Brown Norway rats exposed to D-penicillamine develop an autoimmune syndrome after several weeks of treatment. The symptoms of the IDR are similar to that observed in humans who take D-penicillamine. The mechanism of this reaction is unknown, and no effective biomarkers have been identified to predict susceptibility. We postulate that cell stress caused by drugs is required to initiate the response. We used a highthroughput approach to identify factors that might represent danger signals by profiling hepatic gene expression 6 h after dosing with D-penicillamine (150 mg/kg). Our results show that the drug-treated animals cluster into two distinct groups. One group exhibits substantial expression changes relative to control animals. The most significantly altered transcripts have a role in stress, energy metabolism, acute phase response, and inflammation. We used quantitative reverse transcriptase polymerase chain reaction to measure transcript levels in liver biopsies of 33 rats and found that resistant animals cluster together. This 'resistant' cluster of animals contains 87.5% (7/8) resistant animals but only 48% (12/25) 'sensitive' animals. This separation is statistically significant at the p 0.01 level. Experiment Overall Design: Single-channel Affy arrays used to profile 4 control Brown Norway rats and 8 D-Penicillamine treated Brown Norway rats.

Project description:TFIID is an essential eukaryotic transcription factor, which is required for RNA polymerase II promoter recognition and activation. As a multiprotein complex, TFIID contains several intrinsically disordered regions (IDRs), but the functions of these IDRs are unknown. Here, we show that a conserved IDR drives the TFIID subunit TAF2 to nuclear speckles, where it forms biomolecular condensates, separate from the TFIID complex. Quantitative mass spectrometry analyses reveal that the TAF2 IDR is required for the interaction with the nuclear speckle and spliceosome-associated protein SRRM2, which is thereby recruited to TFIID. The formation of SRRM2-free TFIID complexes elicits a set of unique alternative splicing events. These include events in RNAs coding for proteins involved in transcription and transmembrane transport. Together, these data identify an IDR of the basal transcription machinery as a molecular switch between nuclear compartments to control protein complex composition and pre-mRNA splicing.

Project description:Components of the transcriptional machinery are dynamically compartmentalized by weak multivalent interactions, yet we know little about how specificity or selectivity of partitioning is achieved. Here we show that condensates composed of the intrinsically disordered region (IDR) of MED1 (MED1_IDR) selectively partition positive regulators of transcription(SPT6, CTR9, IWS1) with RNA Pol II while excluding negative regulators of transcription (NELF and HP1a).This selective compartmentalization by MED1_IDR is sufficient to activate transcription and is required for gene activation during a cell state transition. Surprisingly, the IDRs of partitioned proteins are sufficient to recapitulate selective compartmentalization. We find that IDR-mediated selective partitioning requires multivalent blocks of positive and negative charge on MED1_IDR and IDRs of partitioned proteins. The charge patterns required for partitioning are also required for gene activation. These findings demonstrate that proteins can be functionally compartmentalized by specific multivalent interactions driven by the charge patterning within disordered regions.

Project description:RNA-binding proteins with intrinsically disordered regions (IDRs) such as Rbm14 can phase separate in vitro. To what extent the phase separation contributes to their physiological functions is however unclear. Here we show that zebrafish rbm14 regulates embryonic dorsoventral patterning through phase separation. Zebrafish rbm14 morphants displayed dorsalized phenotypes associated with attenuated BMP signaling. Consistently, depletion of mammalian Rbm14 downregulated BMP regulators and effectors Nanog, Smad4/5, and Id1/2, whereas overexpression of the BMP-related proteins in the morphants significantly restored the developmental defects. Importantly, rbm14's IDR demixed into liquid droplets in vitro despite poor sequence conservation with its mammalian counterpart. While its phase separation mutants or IDR failed to rescue the morphants, its chimeric proteins containing an IDR from other phase-separation proteins were effective. Rbm14 complexed with proteins involved in RNA metabolism and phase separated into cellular ribonucleoprotein compartments. Consistently, RNA deep sequencing analysis on the morphant embryos revealed increased alternative splicing events as well as largescale transcriptomic downregulations. Our results suggest that Rbm14 functions in ribonucleoprotein compartments through phase separation to modulate multiple aspects of RNA metabolism. Furthermore, IDRs conserve in phase separation ability but not primary sequence and can be functionally interchangeable.

Project description:Perinatal brain injury is a major clinical problem associated with high neonatal mortality and morbidity and an increased risk of life-long chronic disabilities. Despite improved survival rates, the absolute numbers of neurological handicaps of perinatal origin have not decreased. There is currently no pharmacological treatment providing neuroprotction in neonates. As activation of the innate immune response is a key contributing factor to brain injury in both term and preterm infants we investigated the therapeutic potential of novel immunomodulatory innate defence regulator peptides (IDRs) in perinatal brain injury. IDR-1018 significantly reduced the production of inflammatory mediators by LPS-stimulated microglia cells in vitro. IDR-1018 was also neuroprotective in a clinically-relevant animal model of neonatal brain injury, exerting effects on regulatory molecules of TLR-, Ca2+- and p53-signaling. Of utmost importance, IDR-1018 markedly protected both white and grey brain matter when administered after the injury, thus has tremendous applicability to the clinical setting. Here we demonstrate for the first time that peripheral administration of an immunomodulatory peptide is neuroprotective in vivo in a clinically relevant model of perinatal brain damage.

Project description:Mammalian SWI/SNF complexes are multi-component ATP-dependent chromatin-remodeling complexes that regulate genomic architecture. Here we present the first structural model of the human canonical BAF chromatin-remodeling complex bound to a nucleosome generated using cryo-EM, cross-linking mass spectrometry, and homology modeling. Endogenously-purified BAF tethers to the nucleosome H2A/H2B acidic patch regions bilaterally through the SMARCB1 C-terminal helix and a SMARCA4 C-terminal post-SnAc region, each of which are mutated in disease and disrupt nucleosome remodeling. We describe the structural organization of the BAF core module, a connecting ARP module and the ATPase module, scaffolded by the SMARCA4/2 ATPase subunits. Importantly, we assign and model disease-associated mutations throughout the entire BAF complex, identifying mutations that break identified subunit–nucleosome contacts and subunit–subunit interfaces of BAF in the nucleosome-bound conformation. Taken together, this comprehensive structural model of the human BAF complex provides the first insights into the functional impact of mutations that cause cancer and other diseases.