From the Cell Signalling Group, Ludwig Institute for Cancer Research, 91 Riding House Street, London, W1W 7BS, || Proteomics Unit, Ludwig Institute for Cancer Research, Cruciform Building, London, W1C 6BT, and the ¶ Department of Biochemistry and Molecular Biology, University College London, Gower Street, London, WC1E 6BT, United Kingdom
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ABSTRACT |
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The assessment of the phosphorylation status of specific proteins is commonly performed by immunochemical methods using antisera raised against a peptide containing the site of phosphorylation of the target protein. This approach is restricted to the study of known phosphorylation sites and cannot be used to monitor and discover novel phosphorylated proteins and their sites of phosphorylation. To overcome this problem, quantitative methods to analyze proteins and their sites of modification in a less discriminatory manner are needed.
MS can be used for large scale protein identification (3, 4) and determination of sites of phosphorylation (57). Most of these studies, however, cannot be used for quantitative analysis. Although progress in this area is being made, quantitation of proteins and their sites of modification by MS-based methods is still an analytical challenge for the cell biologist.
Quantitative mass spectrometric methods can be classified into those that require labeling of peptides and those that rely on the intrinsic quantitative nature of LC-ESI-MS. For quantitative LC-MS, it is possible to use synthetic isotopically labeled phosphorylated and unphosphorylated IS1 peptides to mimic a peptide derived from the target protein (8). However, this method, termed Aqua, requires the synthesis of internal peptide standards with the same sequence as the target peptide and thus has the same limitations as immunochemical methods in that it is a targeted approach. This analytical strategy can also only be used to quantify a small set of proteins at a time.
Another MS-based strategy, involving metabolic labeling of proteins using stable isotopes (the SILAC approach), has been applied to the analysis of proteins phosphorylated on Tyr (9, 10). This method is proving to be of value in unraveling the mechanisms that control signaling pathways in cultured cells. Unfortunately metabolic labeling frequently cannot be applied to primary tissues such as those from patients or animals. SILAC also requires costly and custom based reagents, such as isotopes of at least one common amino acid, and special formulation of cell culture media. An alternative method uses ICAT reagents for the quantification of cysteine-containing proteins extracted from any type of cell type and tissue (11), but this strategy cannot be used as a general method for the quantification of phosphorylated peptides.
To overcome some of the limitations in the approaches discussed above, a novel method (called iTraq) has been developed recently in which quantitation is achieved by labeling protein-derived peptides using isobaric reagents. Such labeled peptides produce fragment ions that have four different masses upon fragmentation by collision-induced dissociation, thus allowing the simultaneous analytical comparison of up to four protein samples in a single experiment (12). A potential problem associated with this method is that the labeling reaction is performed after proteolytic digestion of the whole sample without correction for dissimilar protease activities in different reaction vessels.
MS-based quantification approaches that do not depend on protein derivatization or isotopic labeling have also been reported (1315). These methods have used the information that is inherent in the integrated peak areas that are generated in LC-MS and two-dimensional (2D) LC-MS experiments, which are in principle proportional to protein abundance. Such methods that do not require protein labeling are attractive because of their simplicity and affordability and because they do not require the use of chemical reactions that could in principle be a source of experimental variability. However, quantification by LC-MS using peak integration has not been applied to the quantification of proteins separated by gel electrophoresis, one of the most commonly used techniques of protein fractionation. This is most likely due to the fact that sample processing during in-gel digestion and differences in the activities of trypsin in separate reaction vessels can introduce undesirable experimental variation. Here we have addressed such potential shortcomings through the introduction of a protein IS during in-gel digestion and peptide extraction and report that quantitation by peak area integration can also be used for the quantification of proteins separated by 1D SDS-PAGE. This is the basis for our strategy to obtain quantitative information by LC-MS that involves first the parallel separation of samples to be analyzed by 1D SDS-PAGE, isolation of gel pieces, and in-gel tryptic digestion during which a protein IS is added. The latter step corrects for differences in enzymatic activities in different reaction vessels and for differences in sample losses and extraction efficiencies that may occur during the in-gel digestion procedure. Thus, by correcting analyte intensity using the IS, our LC-MS method can be used for relative and absolute quantitation of gel-separated proteins and thus to compare protein abundance in related samples.
We used this peak area measurement with an internal standard (PAIS) method in an ongoing study of PI3K signaling and as part of a proteomic approach to investigate the effects of the carcinogenic compound pV on signal transduction through analysis of the phosphoproteome of the WEHI-231 B lymphoma cell line. Vanadium compounds are potent Tyr phosphatase inhibitors and as such activate pathways controlled by Tyr kinases, including the PI3K pathway and its downstream targets such as the Ser/Thr kinases PDK-1 and Akt/PKB (8, 1621). More than 200 proteins that become phosphorylated upon pV treatment were detected; several of these were found to be sensitive to PI3K inhibition and are therefore candidate proteins in PI3K signaling pathways.
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EXPERIMENTAL PROCEDURES |
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Measurement of Activation of Akt/PKB
Cells were stimulated with 500 µM pV for different time points. Wortmannin (WM) was used at 100 nM and added 20 min before the start of pV treatment. Cells were then lysed, and the same amount of protein was loaded in each lane of 1D SDS-polyacrylamide gels. Blots were probed with antibodies (Cell Signaling Technology Inc.) against Akt/PKB-Thr(P)-308, Akt/PKB-Ser(P)-473, or total Akt/PKB and detected by enhanced chemiluminescence.
Phosphoprotein Enrichment
Exponentially growing cells (9·107 cells in 100 ml of culture medium) were either left unstimulated or treated with pV with or without WM as described above followed by lysis and protein quantification. From the time of lysis, all further steps were carried out at 0 or 4 °C. IP using anti-Tyr(P) monoclonal antibodies (clone 4G10, Upstate Biotechnology) covalently coupled to Sepharose was performed essentially as recommended by the manufacturer and as described before (22). Sepharose-protein A beads (Amersham Biosciences) (500 µl of a 50% slurry), prewashed three times in modified RIPA buffer, were added to 14 mg of each protein sample and left tumbling for 6 h. Samples were then centrifuged at 150 x g for 2 min, and the supernatant was transferred to a fresh tube to which 300 µl of a 50% slurry of agarose-conjugated 4G10 anti-Tyr(P) antibodies were added. Samples were left tumbling for another 6 h. Beads were collected by centrifugation as above and washed three times with RIPA buffer, and bound antigens were eluted using 100 mM phenyl phosphate dissolved in RIPA buffer. Phosphoprotein isolation by IMAC was performed in packed phosphoprotein columns as recommended by the manufacturer (Qiagen, Crowley, UK). Eluates from the Tyr(P) IPs or phosphoprotein columns were loaded on a 1D SDS-polyacrylamide gel consisting of a 0.1 x 15 x 3-cm stacking gel over a 10% (0.1 x 15 x 10-cm) separation gel. After separation, proteins were visualized by colloidal Coomassie Brilliant Blue (CBB) staining.
In-gel Digestion
Protein standards and buffer components were from Sigma. In-gel digestion and LC solvents were from Rathburn. Except when indicated, all volumes were adjusted so that solvents covered gel pieces. After excision, gel pieces were washed three times with 50% (v/v) acetonitrile and dried in a SpeedVac followed by addition of 10 mM DTT in 25 mM ammonium bicarbonate, pH 8.8. Samples were then left at 50 °C for 45 min after which the DTT solution was aspirated, and 50 mM iodoacetamide in 25 mM ammonium bicarbonate was added. Alkylation was performed for 60 min in the dark. Gel pieces were subsequently washed three times and dried as above. Following addition of reduced and alkylated fetuin (15 µl of a 100 fmol·µl1 solution), 100 ng of trypsin (dissolved in 25 mM ammonium bicarbonate) was included and incubated at 37 °C for 4 h. Another aliquot of 100 ng of trypsin was added to each sample 4 h later and then incubated overnight at 37 °C. Tryptic peptides were extracted three times from gel pieces using a 5% (v/v) trifluoroacetic acid in 50% (v/v) acetonitrile solution. Extracted peptides were dried in a SpeedVac and subsequently dissolved in 15 µl of 0.1% (v/v) formic acid.
Liquid Chromatography-Tandem Mass Spectrometry
LC-MS/MS was performed as described previously (23) by injecting 5 µl of digest in a reversed phase capillary column (dimensions, 75 µm x 150 mm; PepMap, LC Packings) using a nanoflow HPLC system (Ultimate, LC Packings) connected on-line with an ESI Q-TOF mass spectrometer (Micromass). Flow rate was 200 nl·min1, and separation was performed by gradient elution from 5% solution B to 45% solution B in 90 min followed by an isocratic step at 95% solution B for 10 min. Solution B was 80% (v/v) acetonitrile, 0.1% formic acid; balance solution A was 0.1% formic acid. MS scans were acquired every second, and MS/MS was performed on automatically selected peptide ions, also for 1 s, using the function switching in the software (MassLynx).
Data Analysis
Raw MS/MS data were converted into peak lists using either MassLynx (Waters) or Distiller (Matrix Science). Spectra were smoothed (Savitzky Golay, two channels twice) and centroid at 80% top using the same software. Charge states were calculated by the software, and peaks were deisotoped. Mascot (Version 2.0.02) (24) was used for searching the IPI mouse data base last updated on November 15, 2004. At the time of searching this data base contained 42,023 sequences. We followed recommended criteria for protein identification when using LC-MS/MS data (25). Proteins were considered identified when at least two peptides matched an entry and the Mascot score was above 40. Correctness of selected identifications (and those derived from one peptide only) was confirmed manually by assigning all the fragment ions in MS/MS spectra to theoretical peptide fragmentations (Protein Prospector (26) was used to obtain theoretical fragment ions). Quantitative data were obtained from protein-derived peptides by inputting their m/z values and retention times into the "Quantify Method" provided with the MassLynx software. This feature of the software automatically obtains extracted ion chromatograms for each of the input m/z values, which together with retention time knowledge are the basis for peak area selection and integration. Integrated peak area values for each protein-derived peptide were divided by the area of a co-eluting IS peptide. In cases where an IS peptide did not co-elute with an analyte peptide, analyte areas were divided by the area of the most proximal eluting IS peptide.
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RESULTS |
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CBB is a commonly used protein stain that is known to produce linear OD signals during scanning with respect to protein amount present in SDS-polyacrylamide gels. Indeed as expected, in this experiment the scanned ODs of the BSA and TfR bands were found to be linear with respect to amount of protein loaded on the gels (Fig. 1a, topand middle panel; only the data for BSA is shown here to illustrate the concept). Similarly, the integrated peak areas of BSA and TfR peptides obtained by LC-ESI-MS (normalized against those of the IS) were also linear with respect to the amounts of BSA and TfR on the gels (Fig. 1A, bottom panel). When the concentrations of the BSA and TfR standards were recalculated using the functions derived from the standard curves, quantitation by our LC-MS approach was found to be comparable to those concentrations obtained using CBB staining (Fig. 1B); indeed they shared similar coefficients of variation (12 and 21%, respectively; Table I). However, LC-MS was found to be more sensitive than CBB in that 13 and 7 ng of BSA loaded on the gel could only be detected by LC-MS with 13 ng of BSA still producing a signal of sufficient intensity to allow accurate quantification.
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Pervanadate Induces Protein Tyr Phosphorylation and the PI3K/Akt Pathway in the WEHI-231 Lymphoma B Cell Line
pV (oxidized vanadate) is a potent inhibitor of protein Tyr phosphatases, and its addition to the culture medium of the WEHI-231 B cell line resulted in an increase in Tyr phosphorylation in a time- and concentration-dependent manner (Fig. 2A and data not shown). Changes in certain pathways that utilize Tyr(P) signaling can lead to PI3K activation. This also was found to be the case in the WEHI-231 cells as demonstrated by the induction of Thr-308 and Ser-473 phosphorylation of the Ser/Thr protein kinase Akt/PKB, a key downstream target of PI3K, in a manner that was sensitive to the PI3K inhibitor WM (Fig. 2B). These results show that pV, a compound that can indirectly induce Tyr phosphorylation in cells in culture, also induces changes in the phosphorylation on certain Ser and Thr residues; these are the consequence, in part at least, of the activation of the PI3K pathway, which is known to lead to a cascade of phosphorylation events upstream and downstream of Akt/PKB by activating several Ser/Thr protein kinases such as PDK-1, p70 S6K, mTOR (mammalian target of rapamycin), and many others (19, 20).
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Fig. 3 shows an example of the data from this PAIS analysis for gel fractions corresponding to the 140160-kDa molecular mass range. Eight proteins matching 3 peptide sequences and having Mascot Scores >60 were identified. Elution profiles of peptides derived from some of these proteins are shown in Fig. 3B.
Quantitative data for these eight proteins, obtained from averaging the integrated chromatographic peak areas of all protein-derived peptides normalized to the areas of the internal standard peptides, is shown in Fig. 3C. Whereas the amounts of most proteins in this gel fraction were unaltered by pV treatment, phospholipase C
2 (PLC
2) and clathrin heavy chain (designated as MKIAA0034 in the IPI data base) were found to be more abundant in the phosphoprotein eluates after pV treatment. These observations suggest that these proteins are phosphorylated upon pV treatment, consistent with previously published data on reversible phosphorylation of PLC
2 (27) and clathrin heavy chain (28). The levels of PLC
2 in the phosphoprotein fraction were reduced upon WM treatment, consistent with PLC
2 phosphorylation being, at least partially, dependent on PI3K activation (29).
Several proteins in the other molecular weight fractions were also found to be increased in IMAC eluates upon pV treatment. These data are summarized in Table II, and some detailed examples are shown in Fig. 4. Candidate proteins that become phosphorylated upon pV treatment include STAT1, mitogen-activated protein kinase (MAPK) 1, MAPK3, and inosine-5'-monophosphate dehydrogenase, whereas other proteins such as MAPK kinase 2 do not seem to be significantly affected by pV treatment. STAT1 and MAPKs are known to become phosphorylated on Ser, Thr, and Tyr residues (30). Interestingly STAT1 levels in IMAC eluates were sensitive to WM treatment (Fig. 4), suggesting that STAT1 is a candidate protein downstream of PI3K.
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A total of 214 different proteins were identified in anti-Tyr(P) IPs, only three of which (heat shock cognate 71-kDa protein, 78-kDa glucose-regulated protein, and chaperone-activity of bc1 complex) were detected in the unstimulated sample. This result is indicative of a low basal level of Tyr(P) phosphorylation and an effective induction of Tyr phosphorylation by pV. Comparison of the proteins present in the IMAC phosphoprotein fractions and Tyr(P) IPs indicates that in general these two types of affinity chromatography isolate similar classes of proteins with signaling proteins being slightly more represented in the Tyr(P) IPs (Fig. 5A). A total of 44 of the proteins enriched in IMAC eluates were also detected in the anti-Tyr(P) eluates (Fig. 5B), illustrating the suitability of IMAC chromatography for the isolation of full-length phosphoproteins.
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Dynamics of Tyr Phosphorylation in PLC2
To assess whether PAIS could be used to monitor the dynamics of protein phosphorylation, PLC2 was immunoprecipitated at several time points following pV stimulation (with or without prior WM pretreatment), and the phosphorylation at four Tyr sites (Tyr-753, Tyr-759, Tyr-1217, and Tyr-1245) was followed by measuring the appearance of Tyr(P)-containing peptides and the disappearance of their unphosphorylated counterparts (Fig. 6). Tyr-753 and Tyr-759 phosphorylation on PLC
2 have been reported previously to be downstream of PI3K, whereas phosphorylation on Tyr-1217 appears not to depend on PI3K activity (29). We found that only Tyr-753 phosphorylation was slightly sensitive to PI3K inhibition at all time points (Fig. 6), whereas other sites of Tyr phosphorylation were unaltered (Tyr(P)-759 and Tyr(P)-1245) or even enhanced by WM treatment
(Tyr(P)-1217). These results are indicative of pV-induced signaling pathways leading to PLC
2 Tyr phosphorylation in a PI3K-dependent or -independent manner. Our findings on PLC
2 illustrate an important application for PAIS as an alternative to antibody-based methods for the detection and quantitation of phosphorylated residues. A further advantage of LC-MS methods of quantitation, such as PAIS, over immunochemical methods is that the relative amounts of phosphorylated residues are followed by measuring the levels of both phosphorylated and unphosphorylated peptides bearing the site of modification.
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DISCUSSION |
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Here we demonstrate that integrated chromatographic peak areas, when normalized to those of a closely co-eluting IS, can be used for the quantitation of gel-separated proteins. Because quantitation is carried out at the peptide level after proteolytic digestion and because each protein generates several peptides upon proteolysis, the redundancy of quantitative data adds confidence to the differences observed and excludes unlikely artifacts that may occur during LC-MS analysis. Therefore, an important aspect of the PAIS method is that quantitation does not rely on isotopic labeling or derivatization of proteins, thus avoiding potential sources of variability that could in principle occur during the course of these chemical reactions. Another key feature is that the PAIS method can be applied to a broad variety of cell and tissue sources as it does not involve metabolic labeling steps. In addition, it uses off the shelf reagents, is not restricted by custom reagents or culture media, and because of its simplicity can be readily applied in any laboratory with access to LC-MS instrumentation. We have used the PAIS method to identify several proteins phosphorylated upon pV treatment and to assess the role that WM, a PI3K inhibitor, has on some of these phosphorylation events.
Enrichment and Quantification of Phosphoproteins
As part of an unbiased strategy to investigate pV-mediated phosphorylation, we used both IMAC and anti-Tyr(P) IPs to obtain phosphoprotein fractions from the WEHI-231 B lymphoma cell line. Several proteins were found in IMAC eluates only after pV stimulation. This illustrates that, in addition to its previously reported use for the isolation of phosphopeptides, IMAC is also an efficient method for enrichment of intact phosphoproteins. Accordingly the relative levels of phosphoproteins in IMAC eluates and anti-Tyr(P) IPs may be proportional to their degree of phosphorylation stoichiometry such that protein amounts in phosphoprotein fractions (e.g. from IMAC or Tyr(P) IPs) can be used to infer their extent of phosphorylation (9). The potential presence of contaminating, non-phosphorylated proteins in IMAC phosphoprotein eluates does not invalidate the method in cases where we define the nature of the phosphorylation and where the levels of specific proteins are increased in the IMAC eluates as a result of pathway activation.
As a result, quantitative MS methods, as the one reported here, can be used for extensive comparative analysis of the relative amounts of proteins in IMAC and anti-Tyr(P) IP phosphoprotein fractions. This is exemplified by our current investigation in which a large number of candidate proteins that become phosphorylated upon pV treatment were detected (Table II, Supplemental Table I, and data not shown). Of those, STAT1 was identified as a protein whose phosphorylation is sensitive to PI3K inhibition (Fig. 4). Although this finding is consistent with published work linking PI3K with STAT signaling pathways (4143), further studies will be required to investigate the involvement of PI3K on STAT1 regulation in B cells. Other proteins were found at higher levels in IMAC eluates after WM treatment (Table II), indicative of a potential role of PI3K in negative feedback loops similar to that previously shown in dendritic cells treated with WM (44).
A more global analysis of our data indicates that anti-Tyr(P) IPs may be comparatively more effective in enriching for signaling components than IMAC (Fig. 5). IMAC enriches for all phosphoproteins classes, including proteins containing Tyr(P), Thr(P), and Ser(P). The latter two are more common post-translational modifications than Tyr(P), and the abundance of Thr(P)- and Ser(P)-containing proteins may mask the presence of Tyr(P)-containing proteins in IMAC eluates. It is of note that several proteins involved in B cell receptor signaling, such as p85, BCAP, and B cell linker (known to be phosphorylated on Tyr residues), were only detected in the Tyr(P) IPs. In contrast, MAPKs and other Ser/Thr kinases were detected in IMAC eluates but not in the Tyr(P) IPs, illustrating the complementarily of these two approaches for the isolation of signaling components.
Identification and Quantification of Phosphorylation Sites
Our studies led to the identification of over 40 phosphorylation sites, many of which have not been reported before. Using PLC2 as a paradigm, we further demonstrated the capacity of PAIS not only for the detection but also for the quantification of post-translational modifications (Fig. 6). Watanabe et al. (27) mapped Tyr(P)-753, Tyr(P)-759, Tyr(P)-1197, and Tyr(P)-1217 sites on PLC
2 by performing an in vitro kinase reaction with Btk using PLC
2 as a substrate, whereas Kim et al. (29) used antibodies against these sites to monitor their induction quantitatively in cells following stimulation. Like Kim et al. (29), we detected phosphorylation on all these sites, apart from Tyr(P)-1197 (Fig. 6), indicating that this Tyr is not always used as a substrate in intact cells in vivo (29). In addition to the sites mentioned above, we also detected Tyr(P)-1245 as a PLC
2 phosphorylation site. This site has been reported before (31) but is not as well characterized as the other PLC
2 Tyr(P) sites due to the
lack of phosphospecific antibodies. Tyr(P)-1245 was also not detected by Watanabe et al. (27), indicating that this site is not a substrate of Btk. In our experiments only Tyr(P)-753 was sensitive to PI3K inhibition. Thus, this example illustrates that PAIS overcomes the need for antibodies against phosphorylated residues for detection and quantitation of their modification. In addition, PAIS allows the determination of quantitative changes in phosphorylation stoichiometry twice, namely by measuring relative amounts of peptides bearing the phosphorylated sites and the corresponding unphosphorylated species, which is clearly a further advantage of PAIS over immunochemical methods for phosphorylation site detection.
It should be noted, however, that not all phosphorylated residues may be amenable to quantification by mass spectrometry. Some residues may be flanked by recognition motifs for trypsin and other proteases, thus producing peptides of sizes unsuitable for mass spectrometric detection. Moreover phosphorylated residues may affect protease substrate recognition when this residue is close to a cleavage site such that the set of proteolytic peptides may be different between phosphorylated and unphosphorylated protein isoforms. These potential problems may be more accentuated when analyzing Ser/Thr sites phosphorylated by kinases such as PKB/Akt whose recognition motif lies close to Arg/Lys residues. Nevertheless this shortcoming, common to all quantitative mass spectrometric methods and not exclusive to our approach, could be addressed by performing parallel experiments using proteases with different specificities to obtain complementary sets of protein-derived peptides.
In conclusion, the PAIS method of quantitative LC-MS allowed identification of several candidate proteins involved in B cell signaling, illustrating the potential of this approach for quantitative profiling of signaling pathways. We envisage that the use of simple and unbiased quantitative mass spectrometric methods, as the one presented here, in combination with affinity techniques for phosphorylated proteins and peptides, such as those used in this study and others performed at the peptide level reported recently (6, 32), will be fundamental to discover new members of signaling pathways, to follow changes in phosphorylation of signaling proteins upon agonist stimulation in a quantitative manner, and to assess the effects that pharmacological inhibitors and gene inactivation may have on signaling pathways.
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ACKNOWLEDGMENTS |
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FOOTNOTES |
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Published, May 4, 2005
Published, MCP Papers in Press, May 5, 2005, DOI 10.1074/mcp.M500078-MCP200
1 The abbreviations used are: IS, internal standard; CBB, Coomassie Brilliant Blue; 2D, two-dimensional; 1D, one-dimensional; IP, immunoprecipitation; IPI, International Protein Index; MAPK, mitogen-activated protein kinase; PAIS, peak area measurement with internal standard; PI3K, phosphoinositide 3-kinase; PLC2, phospholipase C
2; STAT, signal transducer and activator of transcription; TfR, transferrin; pV, pervanadate; WM, wortmannin; SILAC, stable isotope labeling with amino acids in cell culture; PKB, protein kinase B; PDK-1, 3-phosphoinositide-dependent protein kinase-1; CV, coefficient of variation; Btk, Brutons Tyr kinase; BCAP, B cell adaptor protein.
* Research in the laboratories of B. V. and M. D. W. was supported by the Ludwig Institute for Cancer Research with additional grant support from the Association for International Cancer Research (to P. C.), Roche Research Foundation, Switzerland (to B. G.), Overseas Research Scheme UK (to B. G.), Uarda Frutiger Fonds, Switzerland (to B. G.), and Janggen Poehn Stiftung, Switzerland (to B. G.).
S The on-line version of this manuscript (available at http://www.mcponline.org) contains supplemental material.
To whom correspondence should be addressed. E-mail: pedro{at}ludwig.ucl.ac.uk
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REFERENCES |
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