Protein signatures of oxidative stress response in a patient specific cell line model for autism.

BACKGROUND: Known genetic variants can account for 10% to 20% of all cases with autism spectrum disorders (ASD). Overlapping cellular pathomechanisms common to neurons of the central nervous system (CNS) and in tissues of peripheral organs, such as immune dysregulation, oxidative stress and dysfunctions in mitochondrial and protein synthesis metabolism, were suggested to support the wide spectrum of ASD on unifying disease phenotype. Here, we studied in patient-derived lymphoblastoid cell lines (LCLs) how an ASD-specific mutation in ribosomal protein RPL10 (RPL10[H213Q]) generates a distinct protein signature. We compared the RPL10[H213Q] expression pattern to expression patterns derived from unrelated ASD patients without RPL10[H213Q] mutation. In addition, a yeast rpl10 deficiency model served in a proof-of-principle study to test for alterations in protein patterns in response to oxidative stress. METHODS: Protein extracts of LCLs from patients, relatives and controls, as well as diploid yeast cells hemizygous for rpl10, were subjected to two-dimensional gel electrophoresis and differentially regulated spots were identified by mass spectrometry. Subsequently, Gene Ontology database (GO)-term enrichment and network analysis was performed to map the identified proteins into cellular pathways. RESULTS: The protein signature generated by RPL10[H213Q] is a functionally related subset of the ASD-specific protein signature, sharing redox-sensitive elements in energy-, protein- and redox-metabolism. In yeast, rpl10 deficiency generates a specific protein signature, harboring components of pathways identified in both the RPL10[H213Q] subjects' and the ASD patients' set. Importantly, the rpl10 deficiency signature is a subset of the signature resulting from response of wild-type yeast to oxidative stress. CONCLUSIONS: Redox-sensitive protein signatures mapping into cellular pathways with pathophysiology in ASD have been identified in both LCLs carrying the ASD-specific mutation RPL10[H213Q] and LCLs from ASD patients without this mutation. At pathway levels, this redox-sensitive protein signature has also been identified in a yeast rpl10 deficiency and an oxidative stress model. These observations point to a common molecular pathomechanism in ASD, characterized in our study by dysregulation of redox balance. Importantly, this can be triggered by the known ASD-RPL10[H213Q] mutation or by yet unknown mutations of the ASD cohort that act upstream of RPL10 in differential expression of redox-sensitive proteins.

Analysis of von Willebrand factor multimers by simultaneous high- and low-resolution vertical SDS-agarose gel electrophoresis and Cy5-labeled antibody high-sensitivity fluorescence detection.

Analysis of von Willebrand factor (vWF) multimers allows classification of the subtypes of von Willebrand disease (vWD) in human serum and platelet lysates. A novel method for multimer analysis of vWF by 2-chamber, vertical (sodium dodecyl sulfate), agarose gel electrophoresis, designed for comparing discontinuous high- and low-resolving gels for plasma and platelets, followed by Western blotting and high-sensitivity fluorescence detection (HSFD) of cyanine (Cy)5-labeled vWF multimers is presented. HSFD shows that this method has high discriminatory power for visualization and densitometric analysis of platelets and plasma vWF multimers in various types of vWD and allows rapid classification of vWD types, to separate types 2A and 2B. The described procedures of vWF multimer analysis with high-sensitivity Cy5 fluorescence detection and direct comparison of high- and low-resolving gels for screening and detection of the complete range of high- and low-molecular vWF multimers is efficient and useful for screening, detecting, and classifying vWD subtypes and makes this method diagnostically and clinically relevant.

Differential substrate specificity of group I and group II chaperonins in the archaeon Methanosarcina mazei.

Chaperonins are macromolecular machines that assist in protein folding. The archaeon Methanosarcina mazei has acquired numerous bacterial genes by horizontal gene transfer. As a result, both the bacterial group I chaperonin, GroEL, and the archaeal group II chaperonin, thermosome, coexist. A proteome-wide analysis of chaperonin interactors was performed to determine the differential substrate specificity of GroEL and thermosome. At least 13% of soluble M. mazei proteins interact with chaperonins, with the two systems having partially overlapping substrate sets. Remarkably, chaperonin selectivity is independent of phylogenetic origin and is determined by distinct structural and biochemical features of proteins. GroEL prefers well-conserved proteins with complex alpha/beta domains. In contrast, thermosome substrates comprise a group of faster-evolving proteins and contain a much wider range of different domain folds, including small all-alpha and all-beta modules, and a greater number of large multidomain proteins. Thus, the group II chaperonins may have facilitated the evolution of the highly complex proteomes characteristic of eukaryotic cells.

Blue native DIGE as a tool for comparative analyses of protein complexes.

Differential gel electrophoresis (DIGE) is based on pre-labeling of different protein fractions and their subsequent co-electrophoresis in a single gel. Cyanine based "CyDye DIGE Fluor minimal dyes" are used for the labeling reaction and 2D IEF/SDS PAGE is the preferential electrophoresis system for protein separation. The DIGE technology allows elimination of inconsistencies based on gel to gel variations and furthermore allows exact quantification of proteins separated by gel electrophoresis. Here we report applications of the DIGE technology in combination with another 2D gel system, Blue native/SDS PAGE. "Blue native DIGE" offers (i) systematic and quantitative comparison of protein complexes of related protein fractions, (ii) structural investigation of protein complexes, (iii) assignment of protein complexes to subcellular fractions like organelles and (iv) electrophoretic mapping of isoforms of subunits of protein complexes with respect to a larger proteome. The potential of "Blue native DIGE" is illustrated by analysis of organellar fractions from the plant Arabidopsis thaliana and the alga Polytomella. Use of the DIGE technology for topological investigations is discussed.

Difference gel electrophoresis based on lys/cys tagging.

Before separation, proteins of different biological samples are labeled with different fluorescent dyes, the CyDye DIGE Fluors. Currently three dyes with spectrally different excitation and emission wavelengths are available. This allows labeling up to three different samples, and coseparating them in one gel. The dyes can either be attached to the epsilon-amino side group of the lysine without derivatization of the polypeptides or to the cysteines after reduction of the disulfide bonds. For lysine labeling a so called minimal labeling approach is performed: only a low-ratio dye: protein is applied in order to prevent multiple labels per protein. Although only 3% of the proteins are tagged, the sensitivity of detection is comparable with the sensitivity of a good quality silver staining. The dyes are matched for size and charge to obtain migration of differently labeled identical proteins to the same spot positions. The spot pattern achieved with minimal labeling is similar to the pattern obtained with poststained gels. When cysteine tagging is applied, all cysteine moieties are labeled. This modification of the method affords extraordinarily high sensitivity of detection. However, because of multiple labeling, the resulting pattern will look different from nonlabeled or minimal labeled samples. The labeled samples are mixed together before they are applied on the gel of the first dimension. After separation the gels are scanned with the multifluorescent imager at the different wavelengths. Up to three images of comigrated protein mixtures are compared and evaluated from each gel. This multiplexing technique allows the application of an internal standard for each protein in a complex mixture: One of the labels is applied on a mixture of the pooled aliquots of all samples of an experiment. By coseparating this mixture with each gel an internal standard is created for reliable and reproducible detection and assessment of changes of protein expression levels. Image analysis is performed with special software, which allows codetection of protein spots across the different samples and the internal standard.

Quantitative profiling of the membrane proteome in a halophilic archaeon.

We present a large scale quantitation study of the membrane proteome from Halobacterium salinarum. To overcome problems generally encountered with membrane proteins, we established a membrane preparation protocol that allows the application of most proteomic techniques originally developed for soluble proteins. Proteins were quantified using two complementary approaches. For gel-based quantitation, DIGE labeling was combined with two-dimensional gel electrophoresis on an improved 16-benzyldimethyl-n-hexadecylammonium chloride/SDS system. MS-based quantitation was carried out by combining gel-free separation with the recently developed isotope-coded protein labeling technique. Good correlations between these two independent quantitation strategies were obtained. From computational analysis we conclude that labeling of free amino groups by isotope-coded protein labeling (Lys and free N termini) is better suited for membrane proteins than Cys-based labeling strategies but that quantitation of integral membrane proteins remains cumbersome compared with soluble proteins. Nevertheless we could quantify 155 membrane proteins; 101 of these had transmembrane domains. We compared two growth states that strongly affect the energy supply of the cells: aerobic versus anaerobic/phototrophic conditions. The photosynthetic protein bacteriorhodopsin is the most highly regulated protein. As expected, several other membrane proteins involved in aerobic or anaerobic energy metabolism were found to be regulated, but in total, however, the number of regulated proteins is rather small.

The Carcinoma-associated Antigen EpCAM Induces Glyoxalase 1 Resulting in Enhanced Methylglyoxal Turnover.

BACKGROUND: The epithelial cell adhesion molecule (EpCAM) is a homophilic adhesion molecule expressed de novo on a variety of epithelial tumors. Overexpression of EpCAM results in enhanced proliferation and rapid induction of the proto-oncogene c-myc. MATERIALS AND METHODS: The novel proteomics-based fluorescence difference gel electrophoresis (DIGE technology) was used to study EpCAM effects on the proteome of human epithelial cells. RESULTS: DIGE analysis resulted in the identification of five proteins with a significantly changed regulation ranging from -1.3 to +5.8-fold. One of the identified proteins, namely glyoxalase 1, experienced a shift in the isoelectric point from pH 5.2 to 5.0 upon EpCAM expression. This shift correlated with a gain of enzymatic activity of glyoxalase 1 resulting in an enhanced methylglyoxal turnover. CONCLUSION: We show the potential of the DIGE technology to rapidly and quantitatively analyze proteomes for changed expression levels and, importantly, posttranslational modifications. Furthermore, we describe new targets of the carcinoma antigen EpCAM including glyoxalase1.