Actin depolymerizing factor (ADF) occurs naturally in two forms, one of which contains a phosphorylated Ser and does not bind G-actin or depolymerize F-actin. Removal of this phosphate in vitro by alkaline phosphatase restores full F-actin depolymerizing activity. To identify the phosphorylation site, [32P]pADF was purified and digested with endoproteinase Lys-C. The digest contained only one 32P-labeled peptide. Further digestion with endoproteinase Asp-N and mass spectrometric analysis showed that this peptide came from the N terminus of ADF. Alkaline phosphatase treatment of one Asp-N peptide (mass 753) converted it to a peptide of mass 673, demonstrating that this peptide contains the phosphate group. Tandem mass spectrometric sequence analysis of this peptide identified the phosphorylated Ser as the encoded Ser3 (Ser2 in the processed protein). HeLa cells, transfected with either chick wild-type ADF cDNA or a cDNA mutated to code for Ala in place of Ser24 or Thr25, express and phosphorylate the exogenous ADF. Cells also expressed high levels of mutant ADF when Ser3 was deleted or converted to either Ala or Glu. However, none of these mutants was phosphorylated, confirming that Ser3 in the encoded ADF is the single in vivo regulatory site.
Systematic parallel analysis of the phosphorylation status of networks of interacting proteins involved in the regulatory circuitry of cells and tissues is certain to drive research in the post-genomics era for many years to come. Reversible protein phosphorylation plays a critical regulatory role in a multitude of cellular processes, including alterations in signal transduction pathways related to oncogene and tumor suppressor gene products in cancer. While fluorescence detection methods are likely to offer the best solution to global protein quantitation in proteomics, to date, there has been no satisfactory method for the specific and reversible fluorescent detection of gel-separated phosphoproteins from complex samples. The newly developed Pro-Q Diamond phosphoprotein dye technology is suitable for the fluorescent detection of phosphoserine-, phosphothreonine-, and phosphotyrosine-containing proteins directly in sodium dodecyl sulfate (SDS)-polyacrylamide gels and two-dimensional (2-D) gels. Additionally, the technology is appropriate for the determination of protein kinase and phosphatase substrate preference. Other macromolecules, such as DNA, RNA, and sulfated glycans, fail to be detected with Pro-Q Diamond dye. The staining procedure is rapid, simple to perform, readily reversible and fully compatible with modern microchemical analysis procedures, such as matrix-assisted laser desorption/ionization-time of flight (MALDI-TOF) mass spectrometry. Pro-Q Diamond dye technology can detect as little as 1-2 ng of beta-casein, a pentaphosphorylated protein, and 8 ng of pepsin, a monophosphorylated protein. Fluorescence signal intensity correlates with the number of phosphorylated residues on the protein. Through combination of Pro-Q Diamond phosphoprotein stain with SYPRO(R) Ruby protein gel stain, Multiplexed Proteomics technology permits quantitative, dichromatic fluorescence detection of proteins in 2-D gels. This evolving discovery platform allows the parallel determination of protein expression level changes and altered post-translational modification patterns within a single 2-D gel experiment. The linear responses of the fluorescence dyes utilized, allow rigorous quantitation of changes over an unprecedented 500-1000-fold concentration range.
We report an advanced chemoenzymatic strategy for the direct fluorescence detection, proteomic analysis, and cellular imaging of O-GlcNAc-modified proteins. O-GlcNAc residues are selectively labeled with fluorescent or biotin tags using an engineered galactosyltransferase enzyme and [3+2] azide-alkyne cycloaddition chemistry. We demonstrate that this approach can be used for direct ingel detection and mass spectrometric identification of O-GlcNAc proteins, identifying 146 novel glycoproteins from the mammalian brain. Furthermore, we show that the method can be exploited to quantify dynamic changes in cellular O-GlcNAc levels and to image O-GlcNAc-glycosylated proteins within cells. As such, this strategy enables studies of O-GlcNAc glycosylation that were previously inaccessible and provides a new tool for uncovering the physiological functions of OGlcNAc.Understanding posttranslational modifications to proteins is critical for elucidating the functional roles of proteins within the dynamic environment of cells. O-Linked β-Nacetylglucosamine (O-GlcNAc) glycosylation has emerged as important for the regulation of diverse cellular processes, including transcription, cell division, and glucose homeostasis. 1 While new chemical tools have provided rapid, sensitive methods for detecting the modification and enabled better control over the activity of O-GlcNAc enzymes, 1a,2 significant challenges remain with regard to elucidating the functions of O-GlcNAc in cells. For instance, a robust method for the direct fluorescence detection of O-GlcNAc proteins in gels would permit monitoring of changes in glycosylation levels in response to cellular stimuli and greatly extend the reach of existing technologies. Furthermore, new tools for imaging OGlcNAc-glycosylated proteins would enable the expression and dynamics of the modification to be monitored in cells and tissues. Here, we report an advanced chemoenzymatic labeling strategy that addresses these important needs. HHMI Author Manuscript HHMI Author Manuscript HHMI Author ManuscriptPrevious studies have shown that an engineered β-1,4-galactosyltransferase enzyme (Y289L GalT) efficiently transfers a ketogalactose moiety from an unnatural UDP substrate selectively onto O-GlcNAc-modified proteins. 2a However, treatment of cell lysates with an aminooxy fluorescein derivative resulted in some nonspecific labeling of proteins. We therefore investigated whether Y289L GalT would accept the UDP-azidogalactose substrate 1 (UDPGalNAz), which would allow for labeling of O-GlcNAc proteins using [3+2] azide-alkyne cycloaddition chemistry ( Figure 1A). 3 In addition to providing alternative dyes to potentially reduce nonspecific interactions, this Cu(I)-catalyzed cycloaddition reaction would have the advantage of being performed more rapidly and at physiological pH.We tested the approach using α-crystallin, a known O-GlcNAc-modified protein with a low extent (~10%) of glycosylation. α-Crystallin was treated with 1 and Y289L GalT, followed by reaction with CuSO 4 , sodium ascor...
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