Project description:Proximity labeling coupled to mass spectrometry enables in situ mapping of protein-protein interactions. Here, we have developed a strategy based on tagging of proteasomes with promiscuous biotin ligases and a newly generated mouse model to monitor the interactome of proteasomes in vivo. We demonstrate that biotin ligases can be incorporated in fully assembled proteasomes without negative impact on proteasome activity. Analysis of proteins labeled by tagged proteasomes retrieved more than half of the known proteasome-interacting proteins in a single mass spectrometry analysis, including assembly factors, activators and ubiquitin-cycle related proteins. We optimized the protocol for processing of proximity labeled samples to minimize contamination from streptavidin and implemented Data Independent Acquisition (DIA) mass spectrometry for label-free analysis. We demonstrate the utility of our workflow by identifying novel proteasome-interacting proteins, charting interactomes across mouse organs, and showing that proximity-labeling can be used to identify both endogenous and small molecule-induced proteasome substrates.

Project description:Proximity labeling coupled to mass spectrometry enables in situ mapping of protein-protein interactions. Here, we have developed a strategy based on tagging of proteasomes with promiscuous biotin ligases and a newly generated mouse model to monitor the interactome of proteasomes in vivo. We demonstrate that biotin ligases can be incorporated in fully assembled proteasomes without negative impact on proteasome activity. Analysis of proteins labeled by tagged proteasomes retrieved more than half of the known proteasome-interacting proteins in a single mass spectrometry analysis, including assembly factors, activators and ubiquitin-cycle related proteins. We optimized the protocol for processing of proximity labeled samples to minimize contamination from streptavidin and implemented Data Independent Acquisition (DIA) mass spectrometry for label-free analysis. We demonstrate the utility of our workflow by identifying novel proteasome-interacting proteins, charting interactomes across mouse organs, and showing that proximity-labeling can be used to identify both endogenous and small molecule-induced proteasome substrates.

Project description:Proximity labeling coupled to mass spectrometry enables in situ mapping of protein-protein interactions. Here, we have developed a strategy based on tagging of proteasomes with promiscuous biotin ligases and a newly generated mouse model to monitor the interactome of proteasomes in vivo. We demonstrate that biotin ligases can be incorporated in fully assembled proteasomes without negative impact on proteasome activity. Analysis of proteins labeled by tagged proteasomes retrieved more than half of the known proteasome-interacting proteins in a single mass spectrometry analysis, including assembly factors, activators and ubiquitin-cycle related proteins. We optimized the protocol for processing of proximity labeled samples to minimize contamination from streptavidin and implemented Data Independent Acquisition (DIA) mass spectrometry for label-free analysis. We demonstrate the utility of our workflow by identifying novel proteasome-interacting proteins, charting interactomes across mouse organs, and showing that proximity-labeling can be used to identify both endogenous and small molecule-induced proteasome substrates.

Project description:Proximity labeling coupled to mass spectrometry enables in situ mapping of protein-protein interactions. Here, we have developed a strategy based on tagging of proteasomes with promiscuous biotin ligases and a newly generated mouse model to monitor the interactome of proteasomes in vivo. We demonstrate that biotin ligases can be incorporated in fully assembled proteasomes without negative impact on proteasome activity. Analysis of proteins labeled by tagged proteasomes retrieved more than half of the known proteasome-interacting proteins in a single mass spectrometry analysis, including assembly factors, activators and ubiquitin-cycle related proteins. We optimized the protocol for processing of proximity labeled samples to minimize contamination from streptavidin and implemented Data Independent Acquisition (DIA) mass spectrometry for label-free analysis. We demonstrate the utility of our workflow by identifying novel proteasome-interacting proteins, charting interactomes across mouse organs, and showing that proximity-labeling can be used to identify both endogenous and small molecule-induced proteasome substrates.

Project description:For many years, the ubiquitin-26S proteasome degradation pathway was considered the principal route for proteasomal degradation. However, it is now becoming clear that proteins can also be targeted for degradation by an ubiquitin-independent mechanism mediated by the core 20S proteasome itself. The fact that half of cellular proteasomes are free 20S complexes suggests that degradation by this complex is not limited to rare cases. Identifying 20S proteasome substrates is challenging, as different pools of the same protein can be sent to degradation via either 20S or 26S proteasomes. Hence, current knowledge regarding the repertoire of 20S proteasome substrates mainly originates from individual case studies. Here, in an effort to unravel the global repertoire of substrates degraded by the 20S proteasome, we used an advanced mass spectrometry approach coupled with biochemical and cellular analysis. Our analysis enabled the identification of hundreds of 20S proteasome substrates. In addition to proteins that are degraded to completion, we also identified proteins that undergo specific cleavage by the 20S proteasome, at their N- or C- termini, to possibly tune their function. We also found that 20S substrates are significantly enriched with RNA- and DNA-binding proteins that contain intrinsically disordered regions. The vast majority of them are localized in the nucleus and stress granules. Further, we demonstrate that oxidized proteasomes have reduced proteolytic activity compared to naïve proteasomes, which we propose is an adaptive advantage under conditions of cellular stress. Whereas oxidized protein substrates, rather than being folded proteins that lost their native structure due to the stress, actually display a higher degree of structural-disorder than naïve proteins. In summary, here we shed light on the nature of the 20S substrates, providing critical insight into the biological role of the 20S proteasome.

Project description:Proteasomes degrade most intracellular proteins. Several different forms of proteasomes are known. Proteasome inhibitors targeting different proteasome forms are used in clinical practice and were shown to modulate long-term potentiation (LTP) in hippocampal slices of untreated animals. Here we studied the effect of chronic administration of non-constitutive proteasome inhibitor ONX-0914 on the LTP induced by two different protocols: tetanic stimulation and theta-burst stimulation (TBS). Excitatory postsynaptic potentials (fEPSPs) in hippocampal slices from control animals and animals treated with DMSO or ONX-0914 were compared. The TBS stimulation did not change LTP kinetics in hippocampal slices, however chronic administration of ONX-0914 led to the decrease in fEPSP slopes after tetanic stimulation. Observed effects correlated with differential expression of genes involved in synaptic plasticity, glutaminergic synapse and synaptic signaling. Obtained results indicate that non-constitutive proteasomes are likely involved in the tetanus-evoked LTP but not the LTP occurring after TBS, supporting the relevance and complexity of the role of proteasomes in the synaptic plasticity.

Project description:Impaired extracellular matrix (ECM) remodeling is a hallmark of many chronic inflammatory disorders that can lead to cellular dysfunction, aging, and disease progression. The ECM of the aged heart and its effects on cardiac cells during chronological and pathological aging are relatively poorly understood in several speciesacross species. Here, we used mass spectrometry-based proteomics to quantitatively characterize age-related remodeling of the left ventricle (LV) of mice and humans during chronological and pathological (Hutchinson-Gilford progeria syndrome (HGPS)) aging. Of the approximately 300 ECM proteins quantified, we identified 13 proteins that were increased, including lactadherin (MFGE8), collagen VI 6 (COL6A6), vitronectin (VTN) and immunoglobulin heavy constant mu (IGHM), whereas fibulin-5 (FBLN5) was decreased in most of the data sets analyzed. We show that lactadherin accumulates with age in large cardiac blood vessels and when immobilized, triggers phosphorylation of several phosphosites of GSK3B, MAPK isoforms 1, 3, and 14, and MTOR kinases in aortic endothelial cells (ECs). In addition, immobilized lactadherin increased the expression of pro-inflammatory markers associated with an aging phenotype. These results extend our knowledge of the LV proteome remodeling induced by chronological and pathological aging in different species (mouse and human). The lactadherin-triggered changes in the proteome and phosphoproteome of ECs suggest a straight link between ECM component remodeling and the aging process of ECs. 

Project description:Disruption in proteostasis is a hallmark of cancer, with aberrations in proteasome-mediated degradation highly implicated in this malignancy. Proteasomes further bear critical importance in tumor immunogenicity by regulating inflammatory signaling, promoting immune cell activation and playing a crucial role in antigen processing and presentation. Indeed, response to immunotherapy in melanoma patients has been recently linked to increased expression of immunoproteasomes, a specialized form of proteasomes that are upregulated under inflammatory conditions. Yet, the percentage of patients that respond to therapy remains low, and the underlying mechanisms driving resistance remain poorly understood. Further, comprehensive analysis of the role proteasomes play in the pathophysiology of cancer and as a modulator of anti-tumor immunity is remains lacking. Here, we show that proteasome complex composition varies across cancer types and can be used to stratify patient response to immunotherapy. Specifically, we found that the proteasome regulator PSME4 is upregulated in NSCLC and associated with poor prognosis. We show that PSME4 alters proteasome activity and antigen processing attenuating the antigenic diversity and presentation. Through exacting biochemical assays, proteasome profiling of patient-derived NSCLC samples, combined with scRNA-seq, immunopeptidomics and in vivo analyses we uncovered a novel mechanism of immune evasion mediated by PSME4, which promotes an immunosuppressive tumor microenvironment and abrogates anti-tumor immunity. Collectively, our approach may be adapted to other cancer types and pathological settings and affords a novel paradigm by which proteasome composition heterogeneity should be examined and targeted in the context of precision oncology.

Project description:As the major protein degradation machinery of eukaryotic cells, the 26S proteasome is generally thought to localize in the nucleus and cytosol. A portion of proteasomes are known to associate with various membrane structures of the cell, the mechanism and biological meaning of which have been elusive. Here we show that N-myristoylation of the proteasome subunit Rpt2 is an evolutionarily conserved determinant of proteasome-membrane interaction. Loss of this modification leads to embryonic lethality in mice, significant reduction of migration ability in MEFs and profound changes in the membrane-associated proteome as determined by SILAC-MS, suggesting a key role of membrane-tethered proteasomes in carrying out compartmentalized protein degradation. And the tumorigenicity is reduced in the oncogene-transformed MEF without modification. Serendipitously, we found that the Rpt2-G2A mutation cell lines confers partial resistance to proteasome inhibitors, such as Bortezomib and MG132. Thus, N-myristoylation of Rpt2 determines the localization and activity of the proteasome at the membrane, which is critical for embryogenesis, cellular homeostasis and tumorigenesis.

Project description:Gene duplication enables the emergence of new functions by lowering the general evolutionary pressure. Previous studies have highlighted the role of specific paralog genes during cell differentiation, e.g., in chromatin remodeling complexes. It remains unexplored whether similar mechanisms extend to other biological functions and whether the regulation of paralog genes is conserved across species. Here, we analyze the expression of paralogs across human tissues, during development and neuronal differentiation in fish, rodents and humans. While ~80% of paralog genes are co-regulated, a subset of paralogs shows divergent expression profiles, contributing to variability of protein complexes. We identify 78 substitutions of paralog pairs that occur during neuronal differentiation and are conserved across species. Among these, we highlight a substitution between the paralogs Sec23a and Sec23b subunits of the COPII complex. Altering the ratio between these two genes via RNAi-mediated knockdown is sufficient to influence the differentiation of immature neuron. We propose that remodeling of the vesicular transport system via paralog substitutions is an evolutionary conserved mechanism enabling neuronal differentiation.