Project description:A fundamental step in membrane protein biogenesis is their integration into the lipid bilayer with a defined topology. Despite this, it remains unclear how cells detect and handle failures in membrane integration. Our data show that single point mutations in the membrane protein connexin 32 (Cx32), which cause Charcot-Marie-Tooth disease, can cause failures in membrane integration. This leads to Cx32 transport defects and its rapid degradation. We found multiple chaperones to detect and remedy this aberrant behavior: the ER membrane complex (EMC) aids in membrane integration of low-hydrophobicity transmembrane segments. If they fail to integrate, these are recognized by the ER lumenal chaperone BiP. Ultimately, the E3 ligase gp78 ubiquitinates Cx32 proteins targeting them for degradation. Thus, cells use a coordinated system of chaperones for the complex task of membrane protein biogenesis, which can be compromised by single point mutations, causing human disease.

Project description:p300 is a preferred client protein for Nuclear Chaperones

Project description:The endoplasmic reticulum (ER) supports biosynthesis of proteins with diverse transmembrane domain (TMD) lengths and hydrophobicity. Features in transmembrane domains such as charged residues in ion channels are often functionally important, but could pose a challenge during cotranslational membrane insertion and folding. Our systematic proteomic approaches in both yeast and human cells revealed that the ER membrane protein complex (EMC) binds to and promotes the biogenesis of a range of multipass transmembrane proteins, with a particular enrichment for transporters. Proximity-specific ribosome profiling demonstrates that the EMC engages clients cotranslationally and immediately following clusters of TMDs enriched for charged residues. The EMC can remain associated after completion of translation, which both protects clients from premature proteasomal degradation and allows recruitment of substrate-specific and general chaperones. Thus, the EMC broadly enables the biogenesis of multipass transmembrane proteins containing destabilizing features, thereby mitigating the trade-off between function and stability.

Project description:The protein quality control sensors UDP-glucose: glycoprotein glucosyltransferase (UGGT) 1 and 2 are proposed to act as gatekeepers of the early secretory pathway. They initiate rebinding to the carbohydrate-dependent chaperones calnexin and calreticulin that associate with proteins possessing monoglucosylated glycans. The UGGTs control glycoprotein exit from the endoplasmic reticulum (ER) for trafficking to the Golgi or ER retention to provide additional folding opportunities. A quantitative glycoproteomics strategy was used to identify cellular glycoproteins modified by the UGGTs at endogenous levels and delineate the specificities of UGGT1 and UGGT2. UGGT substrates were comprised of seventy-one mainly large multidomain and heavily glycosylated proteins when compared to the general N-glycome. UGGT1 was the dominant glucosyltransferase with a preference towards large plasma membrane proteins whereas UGGT2 favored the modification of smaller, soluble lysosomal proteins. This study provides insight into the cellular secretory load that utilizes multiple rounds of carbohydrate-dependent chaperone intervention for proper maturation.

Project description:Small heat-shock proteins (sHSP) are important members of the cellular stress response in all species. Their best described function is the binding of early unfolding states and the resulting prevention of protein aggregation. All sHSPs exist as oligomers but vary in size and subunit organization. Some sHSPs exist as a polydisperse composition of oligomers which undergoes changes in subunit composition, folding status and relative distribution upon heat activation. To date only an incomplete picture of the mechanism of sHSP activation exists and in particularly the molecular basis of how sHSPs bind client proteins and mediate client specificity is not fully understood. In this study we have applied cross-linking mass spectrometry (XL-MS) to obtain detailed structural information on sHSP activation and client binding for yeast Hsp26. Our cross-linking data reveals the middle domain of Hsp26 as client-independent interface in multiple Hsp26::client complexes and indicates that client-specificity is likely mediated via additional binding sites with its αCD and CTE. Our quantitative XL-MS data underpins the middle domain as the main driver of heat-induced activation and client binding but shows that global rearrangements spanning all domains of Hsp26 are taking place simultaneously. We also investigated a Hsp26::client complex in the presence of Ssa1 (Hsp70) and Ydj1(Hsp40) at the initial stage of refolding and see that the interaction between refolding chaperones is altered by the presence of a client protein, pointing to a mechanism where interaction of Ydj1 with the HSP::client complex initiates assembly of the active refolding machinery.

Project description:Heat shock protein-90 chaperone machinery is involved in the stability and activity of its client proteins. The chaperone function of Hsp90 is regulated by co-chaperones and post-translational modifications. Although structural evidence exists for Hsp90 interaction with clients, our understanding of the impact of Hsp90 chaperone function towards client activity in cells remains elusive. Here, we dissected the impact of newly identified co-chaperones in higher eukaryotes, FNIP1/2 (FNIPs) and Tsc1, towards Hsp90 client activity. Our data show that Tsc1 and FNIP2 form mutually exclusive complexes with FNIP1 and that unlike Tsc1, FNIP1/2 interact with the catalytic residue of Hsp90. Functionally, these co-chaperone complexes increase the affinity of the steroid hormone receptors glucocorticoid receptor and estrogen receptor to their ligands in vivo. Here, we provide a model for the responsiveness of the steroid hormone receptor activation upon ligand binding as a consequence of their association with specific Hsp90:co-chaperone subpopulations.

Project description:Genome wide DNA methylation profiling of samples with/without chronic or acute Temporomandibular Disorders (TMD). The Illumina Infinium Human methylationEPIC Beadchip was used to obtain DNA methylation profiles across 1,051,943 CpGs in TMD samples. Samples included 452 non-TMD and 496 chronic TMD from OPPERA I, 36 healthy and 123 acute TMD from OPPERA II.

Project description:We identified the cell cycle-regulated mRNA transcripts genome-wide in the osteosarcoma derived U2OS cell line. This resulted in 2,140 transcripts mapping to 1,871 unique cell cycle-regulated genes that show periodic oscillations across multiple synchronous cell cycles. We identified genomic loci bound by the G2/M transcription factor FOXM1 by Chromatin immunoprecipitation followed by high-throughput sequencing (ChIP-seq) and associated these with cell cycle-regulated genes. FOXM1 was bound to cell cycle-regulated genes with peak expression in both S phase and G2/M phases. ChIP-seq genomic loci were shown to be responsive to FOXM1 using a real-time luciferase assay in live cells, showing that FOXM1 strongly activates promoters of G2/M phase genes and weakly activates those induced in S phase. Analysis of ChIP-seq data from a panel of cell cycle-transcription factors (E2F1, E2F4, E2F6, and GABPA) from ENCODE and ChIP-seq data for the DREAM complex, found that a set of core cell cycle genes regulated in both U2OS and HeLa cells are bound by multiple cell cycle transcription factors. These data identify the cell cycle regulated genes in a second cancer derived cell line and provide a comprehensive picture of the transcriptional regulatory systems controlling periodic gene expression in the human cell division cycle. Cell cycle-regulated gene expression identified from three double thymidine time courses and one thymidine nocodazole time course.

Project description:This SuperSeries is composed of the SubSeries listed below. Refer to individual Series

Project description:An Arabidopsis mutant in the ER chaperones Calnexins has shown reduced primary root growth under phosphate deficiency. In order to determine which protein(s) could be implicated in this phenotype, we have performed a proteomic experiment to identify proteins differentially abundant in roots of the calnexin mutants versus wild-type.