Project description:Phosphorylation-mediated signaling pathways have major implications in cellular regulation and disease. Mass spectrometry-based proteomics is a well-established approach for quantifying thousands of phosphorylation events in a single experiment. However, proteins with roles in signaling pathways are frequently less abundant and phosphorylation is often sub-stoichiometric. As such, the efficient enrichment and subsequent recovery of phosphorylated peptides is vital. To understand better phosphopeptide recovery from enrichment strategies, we designed a peptide internal standard-based assay directed toward sample preparation strategies for mass spectrometry analysis. We coupled mass-differential tandem mass tag (mTMT) reagents (specifically, TMTzero and TMTsuper-heavy), nine mass spectrometry-amenable phosphopeptides (phos9), and peak area measurements from extracted ion chromatograms to determine phosphopeptide recovery. We showcase this mTMT/phos9 recovery assay by evaluating three commercial phosphopeptide enrichment workflows. Our assay provides data on the recovery of phosphopeptides, which complement other metrics, namely the number of identified phosphopeptides and enrichment specificity. Our mTMT/phos9 assay is applicable to any enrichment protocol in a typical experimental workflow irrespective of sample origin or labeling strategy.

Project description:Myosin-binding protein C (MyBP-C) is a thick filament regulatory protein found exclusively in the C-zone of the A band in the sarcomeres of vertebrate striated muscle. Cardiac, slow skeletal and fast skeletal MyBP-C (fMyBP-C) paralogs perform different functions. However, the functional role of fMyBP-C in fast skeletal muscle is completely unknown. Genetic mutations in human fMyBP-C lead to skeletal myopathies. All three isoforms share similar protein structures, but likely differ substantially in terms of expression and function, which may serve the distinct physiologies of fast and slow muscle fibers. In the present study, we developed a novel fMyBP-C global knockout (KO) mouse model (C2-/-) to investigate the structural, functional, molecular, cellular and physiological roles of fMyBP-C in skeletal muscle.

Project description:Formalin-fixed paraffin embedded (FFPE) tissues are routinely prepared and collected for diagnostics in pathology departments. Therefore, FFPE tissues are the most accessible research sources in pathology archives. In this study we investigated whether we can apply a targeted and quantitative parallel reaction monitoring (PRM) method for FFPE tissue samples in a sensitive and reproducible way. Normal brain and glioblastoma multiforme (GBM) tissues were used to demonstrate the feasibility of our approach. Two analytical methods (or workflows) were used: PRM measurement of a tryptic digest without phosphopeptide enrichment (Direct-PRM) and after Fe-NTA phosphopeptide enrichment (Fe-NTA-PRM). Applying these two methods, the phosphorylation ratio could be determined for selected four peptide pairs that originate from Neuroblast differentiation-associated protein (AHNAK S5448-p), Calcium/calmodulin-dependent protein kinase type II subunit delta (CAMK2D T337-p), Eukaryotic translation initiation factor 4B (EIF4B S93-p) and Epidermal growth factor receptor (EGFR S1166-p). In normal brain FFPE tissues, using the Fe-NTA-PRM method, we were able to quantify the targeted phosphorylated peptides with a high degree of reproducibility (CV = 14%). Our results indicate that formalin fixation does not impede relative quantification of a phosphosite and its phosphorylation ratio in FFPE tissues. The developed methods open ways to study archival FFPE tissues.

Project description:Apolipoprotein E4 (APOE4), the main susceptibly gene for Alzheimer’s disease1–5, exerts cerebrovascular toxicity6 leading to blood-brain barrier (BBB) breakdown in humans7–9 and APOE4 transgenic mice10–13. Moreover, an early BBB dysfunction predicts cognitive decline in humans7. However, the comprehensive large-scale analysis of cell-specific mechanisms underlying APOE4 cerebrovascular disorder and how it relates to neuronal disorder is lacking. Using single-nucleus RNA-sequencing, phosphoproteome and proteome analysis14–17 here we show that APOE4 compared to APOE3 leads to early disruption of the BBB transcriptome in 2-3-month old APOE4 knock-in mice18 followed by dysregulation in protein signaling networks. This includes proteins regulating cell junctions, cytoskeleton, clathrin-mediated transport, and translation in brain endothelium, and transcription and RNA-splicing suggestive of DNA damage in pericytes. Changes in the BBB signaling mechanisms paralleled an early, progressive BBB breakdown and loss of pericytes starting at 2-3 months of age. The BBB breakdown preceded loss of neurites, post-synaptic interactome dysregulation, and behavioral deficits that developed 2-5 months later, and was associated with astrocyte and microglia response protecting BBB integrity. Thus, disruption of the BBB cell-specific signaling mechanisms could be an initial central contributor to APOE4-mediated neuronal disorder, and possibly a major target to correct APOE4-related cognitive deficits.

Project description:Phosphorylated residues of the budding yeast Scc2 protein were identified using phosphopeptide enrichment and mass spectrometry.

Project description:Temporal control over protein phosphorylation and dephosphorylation is crucial for accurate chromosome segregation and for completion of the cell division cycle during exit from mitosis. In budding yeast, the Cdc14 phosphatase is thought to be a major regulator at this time, while in higher eukaryotes PP2A phosphatases take a dominant role. Here, we use time-resolved phosphoproteome analysis in budding yeast to evaluate the respective contributions of Cdc14 and the two main PP2A isoforms, PP2A(Cdc55) and PP2A(Rts1). This reveals an overlapping requirement for all three phosphatases during mitotic progression. Cdc14 instructs the sequential pattern of phosphorylation changes, in part through its preferential recognition of serine-based cyclin-dependent kinase (Cdk) substrates. PP2A(Cdc55) and PP2A(Rts1) in turn exhibit a broad substrate spectrum with some selectivity for phospho-threonines and a role for PP2A(Rts1) in sustaining Aurora kinase activity. Our results illustrate synergy and coordination between phosphatases as they orchestrate phosphoproteome dynamics during mitotic progression.

Project description:Cell-cycle transitions are generally triggered by variations in the activity of cyclin-dependent kinases (CDKs) bound to cyclins. Malaria parasites express ancestral CDKs and cyclins, whose functions and interdependency remain elusive. Here, we show that the unique Plasmodium berghei CDK-related kinase 5 (CRK5), is a critical cell-cycle regulator of gametogony required for transmission to the mosquito. It is essential for DNA replication and phosphorylates canonical S/TPxK CDK motifs on components of the pre-replicative complex otherwise regulated by distinct kinases in other eukaryotes. Over a replicative cycle, CRK5 stably interacts with a single Haemosporidia-specific cyclin (SOC2) with no evidence of SOC2 degradation. Regulation of CRK5 activity relies instead on dynamic phosphorylation of a C-terminus extension that mediates its interaction with SOC2. Our results present evidence that during the atypical cell cycles of Plasmodium gametogony, a unique and divergent cyclin/CDK pair fulfils the functional space of multiple eukaryotic cell-cycle kinases to initiate DNA replication.

Project description:Protein phosphorylation in prokaryotes has gained more attention in recent years as several studies linked it to regulatory and signalling functions indicating an importance similar to protein phosphorylation in eukaryotes. Studies on bacterial phosphorylation have so far been conducted using manual or HPLC-supported phosphopeptide enrichment while automation of phosphopeptide enrichment has been established in eukaryotes, allowing for high throughput sampling. To facilitate the prospect of studying bacterial phosphorylation on a systems‐level we here establish an automated Ser/Thr/Tyr phosphopeptide enrichment workflow on the Agilent AssayMap platform. We present optimized buffer conditions for TiO2 and Fe(III)NTA-IMAC based enrichment, and the most advantageous, species specific starting amount for S. pyogenes, L. monocytogenes, and B. subtilis. Our data represents, to the best of our knowledge, the largest phosphoproteome identified by a single study for each of these bacteria. For higher sample amounts (> 250µg) we observed a superior performance of Fe(III)NTA cartridges, while more peptides were identified from smaller sample amounts using TiO2-based enrichment. Both cartridges largely enrich the same set of phosphopeptides suggesting no improvement of peptide yield from complementary use of both cartridges. Distribution of S/T/Y phosphorylation varied between bacterial strains with threonine being the main site of phosphorylation in S. pyogenes, while in B.subtilis and L. monocytogenes showed the highest percentage of phosphorylation at serine.

Project description:In this study, the effects of three high molecular weight phthalates (DINP, DIDP, DPHP) and their metabolites (MHINP, MCINP, OHMPHP) were investigated in THP-1 macrophages. For this purpose, the phosphoproteome was evaluated.

Project description:Vasopressin regulates renal water excretion by binding to the Gs-coupled vasopressin receptor (V2R) in collecting duct cells, resulting in cyclic AMP-dependent increases in epithelial water permeability through regulation of the aquaporin-2 (AQP2) water channel. Our prior studies showed that CRISPR-mediated deletion of protein kinase A (PKA) in cultured mpkCCD cells largely eliminates these regulatory events. These PKA-null cells provide a means of identifying PKA-independent signaling downstream from the V2 receptor. We carried out large-scale quantitative protein mass spectrometry (SILAC) to identify PKA-independent phosphorylation changes in response to V2R-selective vasopressin analog, dDAVP. The results show that V2R-mediated vasopressin signaling is predominantly, but not entirely, PKA-dependent. Target motif analysis of the phosphopeptides increased in response to dDAVP in PKA-null cells indicates that the vasopressin activates of one or more members of the AMPK/SNF1 subfamily of basophilic protein kinases. Among the upregulated phosphorylation sites were three known targets of SNF1-subfamily kinases, namely Lipe (S559), Crtc1 (S151) and Arhgef2 (S151). One of the phosphorylation sites that increased in occupancy in PKA-null cells was Ser256 of AQP2, a site critical for vasopressin-mediated trafficking of AQP2 to the cell surface. Beyond this, PKA-independent active site phosphorylation changes were also seen for protein kinases Stk39 (SPAK) and Prkci (Protein kinase C iota). Cyclic AMP levels were ~10-fold higher in PKA-null than in PKA-intact cells in the presence of phosphodiesterase inhibitor IBMX, consistent with a marked acceleration of cAMP production in PKA-null cells. The findings are indicative of substantial PKA-independent signaling downstream from the Gs-coupled V2 receptor.