Project description:To identify the genes regulated by the androgen receptor (AR), we performed RNA-seq in the U2OS-AR cell line (derived from U2OS ATTC:HTB-96, stably transfected with an expression construct for human AR), upon androgen (R1881) or vehicle (DMSO) treatment for 24 hours.

Project description:Polo-like kinase 4 (PLK4) is the master regulator of centriole duplication in metazoan organisms. Catalytic activity and protein turnover of PLK4 are tightly coupled in human cells, since changes in PLK4 concentration and catalysis have profound effects on centriole duplication and supernumerary centrosomes, which are associated with aneuploidy and cancer. Recently, PLK4 has been targeted with a variety of small molecule kinase inhibitors exemplified by centrinone, which induces inhibitory effects on PLK4 and can lead to on-target centrosome depletion. Despite this, relatively few PLK4 substrates have been identified unequivocally in human cells, and the extent of PLK4 signalling remains poorly characterised. We report an unbiased mass spectrometry-based quantitative analysis of cellular protein phosphorylation in stable PLK4-expressing human cells exposed to the small molecule inhibitor centrinone. PLK4 phosphorylation was itself sensitive to brief exposure to centrinone, resulting in PLK4 stabilization. A drug-resistant PLK4 mutant (G95R) confirmed several on-target effects of the compound towards PLK4. Using this experimental system, we report hundreds of centrinone-regulated phosphoproteins in U2OS cells, including centrosomal and cell cycle proteins and a variety of likely non cell-cycle substrates. Surprisingly, sequence interrogation of ~300 significantly downregulated phosphoproteins reveals an extensive network of centrinone-sensitive [Ser/Thr]Pro phosphorylation target sequence motifs, which based on our analysis might be either direct or indirect targets of PLK4. In addition, we confirm NMYC and PTPN12 as new PLK4 substrates, both in vitro and in human cells. Our findings suggest that PLK4 catalytic output directly controls the phosphorylation of a diverse set of cellular proteins, including Pro-directed targets that are likely to be important in PLK4-mediated cell signalling.

Project description:Protein import and genome replication are essential processes for mitochondrial biogenesis and propagation. The J-domain proteins Pam16 and Pam18 regulate the presequence translocase of the mitochondrial inner membrane. In the protozoan Trypanosoma brucei, their counterparts are TbPam16 and TbPam18, which are essential for the procyclic form of the parasite, though not involved in mitochondrial protein import. Here, we show that during evolution, the two proteins have been repurposed to regulate the replication of maxicircles within the intricate kDNA network, the most complex mitochondrial genome known. TbPam18 and TbPam16 have inactive J-domains suggesting a function independent of heat shock proteins. However, their single transmembrane domain is essential for function. Pulldown of TbPam16 identifies a putative client protein, termed MaRF11, the depletion of which causes the selective loss of maxicircles, akin to the effects observed for TbPam18 and TbPam16. The level of MaRF11 is controlled by the mitochondrial proteasome. Thus, we propose a model for a membrane-bound regulatory circuit that controls maxicircle replication in response to an unknown nuclear signal. This model posits that MaRF11 directly mediates maxicircle replication, that its activity is regulated by the mitochondrial proteasome that its level is controlled by proteasomal digested that it is protected from degradation by binding to the TbPam18/TbPam16 dimer.

Project description:Protein import and genome replication are essential processes for mitochondrial biogenesis and propagation. The J-domain proteins Pam16 and Pam18 regulate the presequence translocase of the mitochondrial inner membrane. In the protozoan Trypanosoma brucei, their counterparts are TbPam16 and TbPam18, which are essential for the procyclic form of the parasite, though not involved in mitochondrial protein import. Here, we show that during evolution, the two proteins have been repurposed to regulate the replication of maxicircles within the intricate kDNA network, the most complex mitochondrial genome known. TbPam18 and TbPam16 have inactive J-domains suggesting a function independent of heat shock proteins. However, their single transmembrane domain is essential for function. Pulldown of TbPam16 identifies a putative client protein, termed MaRF11, the depletion of which causes the selective loss of maxicircles, akin to the effects observed for TbPam18 and TbPam16. The level of MaRF11 is controlled by the mitochondrial proteasome. Thus, we propose a model for a membrane-bound regulatory circuit that controls maxicircle replication in response to an unknown nuclear signal. This model posits that MaRF11 directly mediates maxicircle replication, that its activity is regulated by the mitochondrial proteasome that its level is controlled by proteasomal digested that it is protected from degradation by binding to the TbPam18/TbPam16 dimer.

Project description:Protein turnover rate is finely regulated through intracellular mechanisms and signals that are still incompletely understood but that are essential for the correct function of cellular processes. Indeed, a dysfunctional proteostasis often impacts on the ability of the cell to remove unfolded, misfolded, degraded, non-functional or damaged proteins. Thus, altered cellular mechanisms controlling protein turnover impinge on the pathophysiology of many diseases, making the study of protein synthesis and degradation rates an important step for a more comprehensive understanding of these pathologies. In this study we describe the application of a dynamic-SILAC approach to study the turnover rate and the abundance of proteins in a cellular model of diabetic nephropathy. We estimated protein half-lives and relative abundance for thousands of proteins, several of which are characterized by either an altered turnover rate or altered abundance between diabetic nephropathic subjects and diabetic controls. Many of these proteins were previously shown to be related to diabetic complications and represent therefore possible biomarkers or therapeutic targets.Beside the aspects strictly related to the pathological condition, our data represent alsoa consistent compendium of protein half-lives in human fibroblasts and a rich source of important information related to basic cell biology.

Project description:In the present work, we sought to identify exhaustively the endogenous substrates ubiquitinated and degraded by the E3 ubiquitin ligase RNF111 in presence of TGF-β signaling by performing label free quantitative proteomics after enrichment of ubiquitinated proteins (ubiquitome) in parental U2OS cell line compared to U2OS CRISPR engineered clones expressing a truncated form of RNF111 devoid of C-terminal Ring domain. We compare two methods of enrichment for ubiquitinated proteins prior to mass spectrometry proteomics analysis, the diGly remnant peptide immunoprecipitation with a K-e-GG antibody and a novel approach using protein immunoprecipitation with an ubiquitin pan (Pan UB) nanobody that recognizes all ubiquitin chains and mono-ubiquitination. These ubiquitomes were compared to the corresponding proteome to identify proteins ubiquitinated and degraded by RNF111 upon TGF-β signaling pathway.

Project description:Protein import and genome replication are essential processes for mitochondrial biogenesis and propagation. The J-domain proteins Pam16 and Pam18 regulate the presequence translocase of the mitochondrial inner membrane. In the protozoan Trypanosoma brucei, their counterparts are TbPam16 and TbPam18, which are essential for the procyclic form of the parasite, though not involved in mitochondrial protein import. Here, we show that during evolution, the two proteins have been repurposed to regulate the replication of maxicircles within the intricate kDNA network, the most complex mitochondrial genome known. TbPam18 and TbPam16 have inactive J-domains suggesting a function independent of heat shock proteins. However, their single transmembrane domain is essential for function. Pulldown of TbPam16 identifies a putative client protein, termed MaRF11, the depletion of which causes the selective loss of maxicircles, akin to the effects observed for TbPam18 and TbPam16. The level of MaRF11 is controlled by the mitochondrial proteasome. Thus, we propose a model for a membrane-bound regulatory circuit that controls maxicircle replication in response to an unknown nuclear signal. This model posits that MaRF11 directly mediates maxicircle replication, that its activity is regulated by the mitochondrial proteasome that its level is controlled by proteasomal digested that it is protected from degradation by binding to the TbPam18/TbPam16 dimer.

Project description:Targeted protein degradation (TPD) has emerged as a powerful strategy to selectively eliminate cellular proteins using small-molecule degraders, offering therapeutic promise for targeting proteins that are otherwise undruggable. However, a remaining challenge is to unambiguously identify primary TPD targets that are distinct from secondary downstream effects in the proteome. Here we introduce an approach that combines stable isotope labeling and click-chemistry for selective quantification of protein degradation by mass spectrometry, excluding confounding effects of altered transcription and translation induced by target depletion. We show that the approach efficiently operates at the time scale of TPD (hours) and we demonstrate its utility by analyzing the Cyclin K degraders dCeMM2 and dCeMM4, which induce widespread transcriptional downregulation, and the GSPT1 degrader CC-885, an inhibitor of protein translation. Additionally, we apply it to characterize compound 1, a previously uncharacterized degrader, and identify the zinc-finger protein FIZ1 as a degraded target.

Project description:To identify the subproteome degraded by endosomal microautophagy (eMI) in a Bag6-dependent manner, we compared the proteome of late endosomal compartments LE/MVBs isolated from control(wild type) and Bag6(-) cells using SILAC labeling and quantitative proteomics.

Project description:Psoriasis is a chronic inflammatory disease of the skin for which current treatments are only partially effective. There is therefore an urgent need to develop novel therapies with higher efficacy through a better understanding of disease aetiology. Recently, it has been demonstrated that individuals with specific mutations in the gene encoding the adapter protein CARD14 have a high risk of developing psoriasis. Psoriasis associated CARD14 mutations result in enhanced activation of NF-kB transcription factors in keratinocytes. The CARD14/NF-kB axis may therefore be central in driving the pathogenesis of psoriasis. The aim of this project is to investigate the molecular mechanisms by which CARD14 activates the NF-kB pathway. Specifically, within this project, we aim to detail the interaction partners of both WT and a gain-of-function mutant CARD14 (E138A) via SILAC and mass spectrometry.