STEAP1 is associated with the invasive and oxidative stress phenotype of Ewing tumors.

Ewing tumors comprise the second most common type of bone-associated cancer in children and are characterized by oncogenic EWS/FLI1 fusion proteins and early metastasis. Compelling evidence suggests that elevated levels of intracellular oxidative stress contribute to enhanced aggressiveness of numerous cancers, possibly including Ewing tumors. Using comprehensive microarray analyses and RNA interference, we identified the six-transmembrane epithelial antigen of the prostate 1 (STEAP1)-a membrane-bound mesenchymal stem cell marker of unknown function-as a highly expressed protein in Ewing tumors compared with benign tissues and show its regulation by EWS/FLI1. In addition, we show that STEAP1 knockdown reduces Ewing tumor proliferation, anchorage-independent colony formation as well as invasion in vitro and decreases growth and metastasis of Ewing tumor xenografts in vivo. Moreover, transcriptome and proteome analyses as well as functional studies revealed that STEAP1 expression correlates with oxidative stress responses and elevated levels of reactive oxygen species that in turn are able to regulate redox-sensitive and proinvasive genes. In synopsis, our data suggest that STEAP1 is associated with the invasive behavior and oxidative stress phenotype of Ewing tumors and point to a hitherto unanticipated oncogenic function of STEAP1.

Strong cation exchange chromatography for analysis of sialylated glycopeptides.

Glycosylations represent major and essential co- and post-translational modification forms of proteins and facilitate a multitude of functions such as cell-cell interactions as well as protein folding and stability. The analysis of protein glycosylation is still an enormous task due to the vast heterogeneity and multitude of different possible carbohydrate structures. The elucidation of glycosylation sites - the attachment points of carbohydrate structures to the polypeptide backbone - is often among the first necessary steps of analysis. Therefore, we here present a simple protocol for charge-based enrichment of sialylated glycopeptides by strong cation exchange chromatography and subsequent analysis of glycosylation sites by mass spectrometry.

Multidimensional protein identification technology.

Over the past years, large-scale analysis of proteomes gained increased interest to obtain a fast but nevertheless comprehensive overview about cellular protein content. While a complete proteome cannot be covered using current technologies because of its enormous diversity, subfractionation to reduce the complexity has become mandatory. While 2D-PAGE is well established as a high-resolution protein separation technique, it suffers from drawbacks, which can be overcome by using peptide separation methods based on multidimensional liquid chromatography. One of these technologies is multidimensional protein identification technology (MudPIT). It consists of two orthogonal separation systems--strong cation exchange (SCX) and reversed phase (RP)--coupled online in an automated fashion to mass spectrometric detection. This method offers the possibility to analyze high-complex peptide mixtures in a single experiment.

Platelet membrane proteomics: a novel repository for functional research.

Being central players in thrombosis and hemostasis, platelets react in manifold and complex ways to extracellular stimuli. Cell-matrix and cell-cell interactions are mandatory for initial adhesion as well as for final development of stable plugs. Primary interfaces for interactions are plasma membrane proteins, of which many have been identified over the past decades in individual studies. However, due to their enucleate structure, platelets are not accessible to large-scale genomic screens and thus a comprehensive inventory of membrane proteins is still missing. For this reason, we here present an advanced proteomic setup for the detailed analysis of enriched platelet plasma membranes and the so far most complete collection of platelet membrane proteins. In summary, 1282 proteins were identified, of which more than half are termed to be of membrane origin. This study provides a brief overview of gene ontology subcellular and functional classification, as well as interaction network analysis. In addition, the mass spectrometric data were used to assemble a first tentative relative quantification of large-scale data on the protein level. We therefore estimate the presented data to be of major interest to the platelet research field and to support rational design of functional studies.

Phosphorylation site mapping of soluble proteins: bioinformatical filtering reveals potential plastidic phosphoproteins in Arabidopsis thaliana.

Protein phosphorylation is a major mode of regulation of metabolism, gene expression, and cell architecture. A combination of phosphopeptide enrichment strategies based on TiO(2) and IMAC in addition to our MudPIT strategy revealed the detection of 181 phosphorylation sites which are located on 125 potentially plastidic proteins predicted by GoMiner, TargetP/Predotar in Arabidopsis thaliana. In our study phosphorylation on serine is favored over threonine and this in turn over phosphorylation on tyrosine residues, showing a percentage of 67.4% to 24.3% to 8.3% for pS:pT:pY. Four phosphorylated residues (S208, Y239, T246 and T330), identified by our approach have been fitted to the structure of the activated form of spinach RuBisCO, which are located in close proximity to the substrate binding site for ribulosebisphosphate. Potentially, these phosphorylation sites exert a direct influence on the catalytic activity of the enzyme. Such examples show nicely the value of the presented mass spectrometric dataset for further biochemical applications, since alternative mutation analysis often turns out to be unsuccessful, caused by mutations in essential proteins which result in lethal phenotypes.

Impaired photosystem I oxidation induces STN7-dependent phosphorylation of the light-harvesting complex I protein Lhca4 in Arabidopsis thaliana.

Reduction of the plastoquinone (PQ) pool is known to activate phosphorylation of thylakoid proteins. In the Arabidopsis thaliana mutants psad1-1 and psae1-3, oxidation of photosystem I (PSI) is impaired, and the PQ pool is correspondingly over-reduced. We show here that, under these conditions, the antenna protein Lhca4 of PSI becomes a target for phosphorylation. Phosphorylation of the mature Lhca4 protein at Thr16 is suppressed in stn7 psad1 and stn7 psae1 double mutants. Thus, under extreme redox conditions, hyperactivation of thylakoid protein kinases and/or reorganization of thylakoid protein complex distribution increase the susceptibility of PSI to phosphorylation.