Proteomic analysis of in vivo phosphorylated synaptic proteins

In the nervous system, protein phosphorylation is an essential feature of synaptic function. Although protein phosphorylation is known to be important for many synaptic processes and in disease, little is known about global phosphorylation of synaptic proteins. Heterogeneity and low abundance make protein phosphorylation analysis difficult, particularly for mammalian tissue samples. Using a new approach, combining both protein and peptide immobilized metal affinity chromatography and mass spectrometry data acquisition strategies, we have produced the first large scale map of the mouse synapse phosphoproteome. We report over 650 phosphorylation events corresponding to 331 sites (289 have been unambiguously assigned), 92% of which are novel. These represent 79 proteins, half of which are novel phosphoproteins, and include several highly phosphorylated proteins such as MAP1B (33 sites) and Bassoon (30 sites). An additional 149 candidate phosphoproteins were identified by profiling the composition of the protein immobilized metal affinity chromatography enrichment. All major synaptic protein classes were observed, including components of important pre- and postsynaptic complexes as well as low abundance signaling proteins. Bioinformatic and in vitro phosphorylation assays of peptide arrays suggest that a small number of kinases phosphorylate many proteins and that each substrate is phosphorylated by many kinases. These data substantially increase existing knowledge of synapse protein phosphorylation and support a model where the synapse phosphoproteome is functionally organized into a highly interconnected signaling network.     

A multidimensional chromatography technology for in-depth phosphoproteome analysis

Protein phosphorylation is a post-translational modification widely used to regulate cellular responses. Recent studies showed that global phosphorylation analysis could be used to study signaling pathways and to identify targets of protein kinases in cells. A key objective of global phosphorylation analysis is to obtain an in-depth mapping of low abundance protein phosphorylation in cells; this necessitates the use of suitable separation techniques because of the complexity of the phosphoproteome. Here we developed a multidimensional chromatography technology, combining IMAC, hydrophilic interaction chromatography, and reverse phase LC, for phosphopeptide purification and fractionation. Its application to the yeast Saccharomyces cerevisiae after DNA damage led to the identification of 8764 unique phosphopeptides from 2278 phosphoproteins using tandem MS. Analysis of two low abundance proteins, Rad9 and Mrc1, revealed that approximately 50% of their phosphorylation was identified via this global phosphorylation analysis. Thus, this technology is suited for in-depth phosphoproteome studies.     

Motif-specific sampling of phosphoproteomes

Phosphoproteomics, the targeted study of a subfraction of the proteome which is modified by phosphorylation, has become an indispensable tool to study cell signaling dynamics. We described a methodology that linked phosphoproteome and proteome analysis based on Ba2+ binding properties of amino acids. This technology selected motif-specific phosphopeptides independent of the system under analysis. MudPIT (Multidimensional Identification Technology) identified 1037 precipitated phosphopeptides from as little as 250 microg of proteins. To extend coverage of the phosphoproteome, we sampled the nuclear extract of HeLa cells with three values of Ba2+ ions molarity. The presence of more than 70% of identified phosphoproteins was further substantiated by their nonmodified peptides. Upon isoproterenol stimulation of HEK cells, we identified an increasing number of phosphoproteins from MAPK cascades and AKAP signaling hubs. We quantified changes in both protein and phosphorylation levels of 197 phosphoproteins including a critical kinase, MAPK1. Integration of differential phosphorylation of MAPK1 with knowledge bases constructed modules that correlated well with its role as node in cross-talk of canonical pathways.     

Initial analysis of the phosphoproteome of Chinese hamster ovary cells using electrophoresis.

Protein phosphorylation is a common post-translational modification of enormous biological importance. Analysis of phosphorylation at the global level should shed light on the use of this modification to regulate metabolism, signal transduction, and other processes. We have begun a proteomic analysis of phosphorylation using two-dimensional gel electrophoresis. Chinese hamster ovary (CHO) cells were metabolically labeled using 32P-orthophosphate. The proteins were extracted and run on two-dimensional electrophoresis. Gels were stained using colloidal Coomassie stain, dried, and phosphorimaged. The Coomassie stain allowed the observation of 468 individual protein spots. The phosphorimage showed 181 spots. The phosphoproteome of CHO cells therefore comprises around one third as many proteins as the CHO cell abundance proteome. However, the most intense spots in the phosphoproteome usually do not correlate with intense spots in the abundance proteome. We investigated the effects of labeling time, finding that the number of observable spots increases but the relative intensities also change. We also investigated the effects of adding a phosphatase inhibitor during labeling. Finally, we evaluated a phosphoprotein-specific stain (Pro-Q Diamond) in comparison with radiolabeling methods. There is not perfect correlation between radiolabeled phosphoproteins and Pro-Q Diamond-stained phosphoproteins.     

Evaluation and properties of the budding yeast phosphoproteome

We have assembled a reliable phosphoproteomic data set for budding yeast Saccharomyces cerevisiae and have investigated its properties. Twelve publicly available phosphoproteome data sets were triaged to obtain a subset of high-confidence phosphorylation sites (p-sites), free of "noisy" phosphorylations. Analysis of this combined data set suggests that the inventory of phosphoproteins in yeast is close to completion, but that these proteins may have many undiscovered p-sites. Proteins involved in budding and protein kinase activity have high numbers of p-sites and are highly over-represented in the vast majority of the yeast phosphoproteome data sets. The yeast phosphoproteome is characterized by a few proteins with many p-sites and many proteins with a few p-sites. We confirm a tendency for p-sites to cluster together and find evidence that kinases may phosphorylate off-target amino acids that are within one or two residues of their cognate target. This suggests that the precise position of the phosphorylated amino acid is not a stringent requirement for regulatory fidelity. Compared with nonphosphorylated proteins, phosphoproteins are more ancient, more abundant, have longer unstructured regions, have more genetic interactions, more protein interactions, and are under tighter post-translational regulation. It appears that phosphoproteins constitute the raw material for pathway rewiring and adaptation at various evolutionary rates.     

Proteomics analysis of protein kinases by target class-selective prefractionation and tandem mass spectrometry

Protein kinases constitute a large superfamily of enzymes with key regulatory functions in nearly all signal transmission processes of eukaryotic cells. However, due to their relatively low abundance compared with the vast majority of cellular proteins, currently available proteomics techniques do not permit the comprehensive biochemical characterization of protein kinases. To address these limitations, we have developed a prefractionation strategy that uses a combination of immobilized low molecular weight inhibitors for the selective affinity capture of protein kinases. This approach resulted in the direct purification of cell type-specific sets of expressed protein kinases, and more than 140 different members of this enzyme family could be detected by LC-MS/MS. Furthermore the enrichment technique combined with phosphopeptide fractionation led to the identification of more than 200 different phosphorylation sites on protein kinases, which often remain occluded in global phosphoproteome analysis. As the phosphorylation states of protein kinases can provide a readout for the signaling activities within a cellular system, kinase-selective phosphoproteomics based on the procedures described here has the potential to become an important tool in signal transduction analysis.     

Analysis of the phosphoproteome of Chlamydomonas reinhardtii provides new insights into various cellular pathways

The unicellular flagellated green alga Chlamydomonas reinhardtii has emerged as a model organism for the study of a variety of cellular processes. Posttranslational control via protein phosphorylation plays a key role in signal transduction, regulation of gene expression, and control of metabolism. Thus, analysis of the phosphoproteome of C. reinhardtii can significantly enhance our understanding of various regulatory pathways. In this study, we have grown C. reinhardtii cultures in the presence of an inhibitor of Ser/Thr phosphatases to increase the phosphoprotein pool. Phosphopeptides from these cells were enriched by immobilized metal-ion affinity chromatography and analyzed by nano-liquid chromatography-electrospray ionization-mass spectrometry (MS) with MS-MS as well as neutral-loss-triggered MS-MS-MS spectra. In this way, we were able to identify 360 phosphopeptides from 328 different phosphoproteins of C. reinhardtii, thus providing new insights into a variety of cellular processes, including metabolic and signaling pathways. Comparative analysis of the phosphoproteome also yielded new functional information on proteins controlled by redox regulation (thioredoxin target proteins) and proteins of the chloroplast 70S ribosome, the centriole, and especially the flagella, for which 32 phosphoproteins were identified. The high yield of phosphoproteins of the latter correlates well with the presence of several flagellar kinases and indicates that phosphorylation/dephosphorylation represents one of the key regulatory mechanisms of eukaryotic cilia. Our data also provide new insights into certain cilium-related mammalian diseases.     

Phosphorylation of ribosomal proteins from eukaryotes in homologous and heterologous cell-free systems

The phosphorylation of ribosomal proteins from eukaryotes in homologous and heterologous cell-free systems has been studied. The ribosomes and protein kinases from yeast (Saccharomyces cerevisiae, strain Bu), wheat (Triticum vulgare) and rabbit (Orystolagus cuniculus) have been used.It has been found that five ribosomal proteins incorporate γ-³²P from ATP during the incubation of wheat ribosomes with wheat protein kinase. When the phosphorylation of isolated wheat ribosomal proteins was examined more phosphoproteins were detected. These data confirm the suggestion that the ribosomal structure affects the phosphorylation. Probably some ribosomal proteins remain hidden for the action of protein kinase.The results from the crossed experiments show that there is no barrier for phosphorylation of yeast ribosomes with liver protein kinase, of wheat ribosomes with yeast and liver protein kinases and of liver ribosomes with yeast and plant protein kinases. The wheat protein kinase does not phosphorylate the yeast ribosomes under these experimental conditions. Some differences in the set of phosphoproteins obtained with various protein kinases have been detected. These data suggest that the ribosomal protein phosphorylation is not highly species specific although it is not universal.     

Impact of phosphoproteomics on studies of bacterial physiology

Protein phosphorylation on serine, threonine and tyrosine is recognized as a major tool of signal transduction in bacteria. However, progress in the field has been hampered by the lack of global and site-specific data on bacterial phosphoproteomes. Recent advances in mass spectrometry-based proteomics have encouraged bacteriologists to start using powerful gel-free approaches for global detection of phosphorylated proteins. These studies have generated large data sets of proteins phosphorylated on serine, threonine and tyrosine, with identified phosphorylation sites which represent an excellent starting point for in-depth physiological characterization of kinases and their substrates. The list of phosphorylated proteins inspired a number of physiological studies in which the identity of the phosphorylation site facilitated the elucidation of molecular mechanisms of signaling and regulation. Bacterial phosphoproteomics also provided interesting insights into the evolutionary aspects of protein phosphorylation. The field is rapidly embracing quantitative mass spectrometry strategies, comparing phosphoproteome dynamics in changing conditions and aiming to reconstruct the entire regulatory networks by linking kinases to their physiological substrates.     

Proteomic investigations reveal a role for RNA processing factor THRAP3 in the DNA damage response

The regulatory networks of the DNA damage response (DDR) encompass many proteins and posttranslational modifications. Here, we use mass spectrometry-based proteomics to analyze the systems-wide response to DNA damage by parallel quantification of the DDR-regulated phosphoproteome, acetylome, and proteome. We show that phosphorylation-dependent signaling networks are regulated more strongly compared to acetylation. Among the phosphorylated proteins identified are many putative substrates of DNA-PK, ATM, and ATR kinases, but a majority of phosphorylated proteins do not share the ATM/ATR/DNA-PK target consensus motif, suggesting an important role of downstream kinases in amplifying DDR signals. We show that the splicing-regulator phosphatase PPM1G is recruited to sites of DNA damage, while the splicing-associated protein THRAP3 is excluded from these regions. Moreover, THRAP3 depletion causes cellular hypersensitivity to DNA-damaging agents. Collectively, these data broaden our knowledge of DNA damage signaling networks and highlight an important link between RNA metabolism and DNA repair.     

Kinase-selective enrichment enables quantitative phosphoproteomics of the kinome across the cell cycle

Protein kinases are pivotal regulators of cell signaling that modulate each other's functions and activities through site-specific phosphorylation events. These key regulatory modifications have not been studied comprehensively, because low cellular abundance of kinases has resulted in their underrepresentation in previous phosphoproteome studies. Here, we combine kinase-selective affinity purification with quantitative mass spectrometry to analyze the cell-cycle regulation of protein kinases. This proteomics approach enabled us to quantify 219 protein kinases from S and M phase-arrested human cancer cells. We identified more than 1000 phosphorylation sites on protein kinases. Intriguingly, half of all kinase phosphopeptides were upregulated in mitosis. Our data reveal numerous unknown M phase-induced phosphorylation sites on kinases with established mitotic functions. We also find potential phosphorylation networks involving many protein kinases not previously implicated in mitotic progression. These results provide a vastly extended knowledge base for functional studies on kinases and their regulation through site-specific phosphorylation.     

Phosphoproteomic analysis of Leishmania donovani pro- and amastigote stages

Following transmission to the vertebrate host, the protozoan parasite Leishmania donovani differentiates into the pathogenic amastigote stage that is adapted for intracellular survival. This developmental transition is induced by environmental factors including elevated temperature and acidic pH and is likely transduced by signaling cascades involving protein kinases and their downstream phosphoprotein substrates. These signaling networks are highly adapted to the specific nutritional and physiological requirements of the organism and thus studying Leishmania phosphorylation may allow important insight into the parasite-specific biology. We used a gel-based approach to investigate qualitative and quantitative changes of the phosphoproteome of the major L. donovani life cycle stages. Phosphoproteins were purified by immobilized metal affinity chromatography (IMAC), separated by IEF and SDS-PAGE using pH 4-7 IPG immobiline strips, revealed by fluorescent multiplex staining, and identified by MALDI-MS and MS/MS. Our analysis allowed us to establish a first repertoire of the Leishmania phosphoproteome and to identify phosphoproteins implicated in stress- and heat shock response, RNA/protein turnover, metabolism, and signaling.     

Gel-based and gel-free identification of proteins and phosphopeptides during egg-to-larva transition in polychaete Neanthes arenaceodentata

The polychaete Neanthes arenaceodentata- is cosmopolitan in distribution-, has been used as a laboratory test animal. Life history of this species has several unique features; the female dies after spawning and the male incubates the fertilized eggs through the 21-segmented stage. The larvae leave the tube and commence feeding. Changes in protein abundance and phosphorylation were examined during early development of N. arenaceodentata. A gel-based approach and gel-free enrichment of phosphopeptides coupled with mass spectrometry were used to identify proteins and phosphopeptides in fertilized ova and larval stages. Patterns of proteins and phosphoproteins changed from fertilized ova to larval stages. Twelve proteins occurred in phosphorylated form and nine as stage specific proteins. Cytoskeletal proteins have exhibited differential phosphorylation from ova to larval stages; whereas, other proteins exhibited stage-specific phosphorylation patterns. Ten phosphopeptides were identified that showed phosphorylation sites on serine or threonine residues. Sixty percent of the identified proteins were related to structural reorganization and others with protein synthesis, stress response and attachment. The abundance and distribution of two cytoskeleton proteins were examined further by 2-DE Western blot analysis. This is the first report on changes in protein expression and phosphorylation sites at Thr/Ser in early development of N. arenaceodentata. The 2-DE proteome maps and identified phosphoproteins contributes toward understanding the state of fertilized ova and early larval stages and serves as a basis for further studies on proteomics changes under different developmental conditions in this and other polychaete species.     

Using protein microarrays to study phosphorylation-mediated signal transduction

Unraveling the complexity of cell regulatory systems and monitoring their operations under normal and pathological circumstances is one of the major outstanding biomedical challenges. The phosphoproteome has emerged as a rich source of biomarkers for tracking cell signaling and disease, and many of the kinases that phosphorylate proteins represent attractive targets for drug development. Over 100,000 phosphorylation sites distributed in most of the 23,000 proteins encoded by the human genome have already been identified in a non-targeted fashion by mass-spectrometry. Antibody microarrays permit ultra-sensitive, semi-quantitative measurements of the levels of hundreds of target proteins and their phosphorylation in parallel with specimens from cells and tissues. Conversely, reverse-phase protein microarrays (RPPMs) that are printed with crude cell/tissue lysates allow tracking of a target protein with a probing antibody in hundreds to thousands of cell and tissue samples simultaneously. While more than half a million commercial antibodies are available, the identification of highly specific and potent antibodies for use in microarrays remains a major impediment. Antibody cross-reactivity is an issue for both antibody microarrays and RPPMs. The low abundance of signal transduction proteins and their substoichiometric levels of phosphorylation are also problematic. Finally, non-denaturing conditions used with standard antibody microarrays permit protein complexes, which can produce false positives and false negatives. Changes in the level of an interacting protein may be misinterpreted as alterations in the amount of a target protein or its phosphorylation state. It is critical that leads from both types of microarrays are validated by complementary approaches such as immunoblotting and ELISA. More than a hundred reports have appeared in the scientific literature that have benefited from utilization of antibody and protein lysate microarrays. We have highlighted some of the pioneering works in this field and provided recent examples of their successful deployment as tools for broad-based, targeted proteomics research.     

Quantitative phosphoproteomics of transforming growth factor-β signaling in colon cancer cells

The transforming growth factor‐β (TGF‐β) signaling pathway progresses through a series of protein phosphorylation regulated steps. Smad4 is a key mediator of the classical TGF‐β signaling pathway; however, reports suggest that TGF‐β can activate other cellular pathways independent of Smad4. By investigating the TGF‐β‐regulated phosphoproteome, we aimed to uncover new functions controlled by TGF‐β. We applied titanium dioxide to enrich phosphopeptides from stable isotope labeling with amino acids in cell culture (SILAC)‐labeled SW480 cells stably expressing Smad4 and profiled them by mass spectrometry. TGF‐β stimulation for 30 min resulted in the induction of 17 phosphopeptides and the repression of 8 from a total of 149 unique phosphopeptides. Proteins previously not known to be phosphorylated by TGF‐β including programmed cell death protein 4, nuclear ubiquitous casein and cyclin‐dependent kinases substrate, hepatoma‐derived growth factor and cell division kinases amongst others were induced following TGF‐β stimulation, while the phosphorylation of TRAF2 and NCK‐interacting protein kinase are examples of proteins whose phosphorylation status was repressed. This phosphoproteomic screen has identified new TGF‐β‐modulated phosphorylation responses in colon carcinoma cells.     

Protein phosphorylation in plant mitochondria

Reversible phosphorylation of proteins is one of the most common regulatory mechanisms in eukaryotic cells and it can affect virtually any property of a protein. We predict that plant mitochondria possess 50–200 protein kinases (PKs), at least as many target proteins and 10–30 protein phosphatases although all will not be expressed at the same time in the same cell type or tissue. Presently available high-throughput methods for the identification of phosphoproteins and their phosphorylation sites are first reviewed and a number of useful databases listed. We then discuss the known phosphoproteins, PKs and phosphatases in plant mitochondria and compare with yeast and mammalian mitochondria. Three case stories—respiratory chain complex I, pyruvate dehydrogenase and formate dehydrogenase—are briefly considered before a final treatment of mitochondrial protein phosphorylation in intracellular signal transduction and programmed cell death.