Time-course analysis of mouse serum proteome changes following exposure of the skin to ionizing radiation

Radiation-induced lesion outcomes of normal tissues are difficult to predict. In particular, radiotherapy or local exposure to a radioactive source by accident can trigger strong injury to the skin. The finding of biomarkers is of fundamental relevance for the prediction of lesion apparition and its evolution, and for the settlement of therapeutic strategies. In order to study radiation-induced cutaneous lesions, we developed a mouse model in which the dorsal skin was selectively exposed to ionizing radiation (IR). 2-D difference gel electrophoresis (2-D DIGE) coupled with MS was used to investigate proteins altered in expression and/or PTM in serum. Proteome changes were monitored from 1 day to 1 month postirradiation, at a dose of 40 Gy, in this specific model developing reproducible clinical symptoms ranging from erythema to skin ulceration with wound healing. About 60 proteins (including some isoforms and likely post-translational variants), representing 20 different proteins, that exhibited significant and reproducible kinetic expression changes, were identified using MS and database searches. Several proteins, down- or up-regulated from day one, could prove to be good candidates to prognosticate the evolution of a skin lesion such as necrosis. In addition, we observed shifts in pI of several spot trains, revealing potential PTM changes, which could also serve as indicators of irradiation or as predictors of lesion severity.     

Altered protein expression pattern in colon tissue of mice upon supplementation with distinct selenium compounds

The essential trace element selenium (Se) is controversially discussed concerning its role in health and disease. Its various physiological functions are largely mediated by Se incorporation in the catalytic center of selenoproteins. In order to gain insights into the impact of Se deficiency and of supplementation with different Se compounds (selenite, selenate, selenomethionine) at defined concentrations (recommended, 150 μg/kg diet; excessive, 750 μg/kg diet) in murine colon tissues, a 20‐week feeding experiment was performed followed by analysis of the protein expression pattern of colon tissue specimens by 2D‐DIGE and MALDI‐TOF MS. Using this approach, 24 protein spots were identified to be significantly regulated by the different Se compounds. These included the antioxidant enzyme peroxiredoxin‐5 (PRDX5), proteins with binding capabilities, such as cofilin‐1 (COF1), calmodulin, and annexin A2 (ANXA2), and proteins involved in catalytic processes, such as 6‐phosphogluconate dehydrogenase (6PGD). Furthermore, the Se compounds demonstrated a differential impact on the expression of the identified proteins. Selected target structures were validated by qPCR and Western blot which mainly confirmed the proteomic profiling data. Thus, novel Se‐regulated proteins in colon tissues have been identified, which expand our understanding of the physiologic role of Se in colon tissue.     

Hypophosphorylation of the architectural chromatin protein DEK in death-receptor-induced apoptosis revealed by the isotope coded protein label proteomic platform

During apoptosis nuclear morphology changes dramatically due to alterations of chromatin architecture and cleavage of structural nuclear proteins. To characterize early events in apoptotic nuclear dismantling we have performed a proteomic study of apoptotic nuclei. To this end we have combined a cell-free apoptosis system with a proteomic platform based on the differential isotopic labeling of primary amines with N-nicotinoyloxy-succinimide. We exploited the ability of this system to produce nuclei arrested at different stages of apoptosis to analyze proteome alterations which occur prior to or at a low level of caspase activation. We show that the majority of proteins affected at the onset of apoptosis are involved in chromatin architecture and RNA metabolism. Among them is DEK, an architectural chromatin protein which is linked to autoimmune disorders. The proteomic analysis points to the occurrence of multiple PTMs in early apoptotic nuclei. This is confirmed by showing that the level of phosphorylation of DEK is decreased following apoptosis induction. These results suggest the unexpected existence of an early crosstalk between cytoplasm and nucleus during apoptosis. They further establish a previously unrecognized link between DEK and cell death, which will prove useful in the elucidation of the physiological function of this protein.     

Proteomic analysis of oligodendrogliomas expressing a mutant isocitrate dehydrogenase-1

Gliomas are primary tumors of the human central nervous system with unknown mechanisms of progression. Isocitrate dehydrogenase-1 (IDH1) mutation is frequent in diffuse gliomas such as oligodendrogliomas. To gain insights into the physiopathology of oligodendrogliomas that have a better prognosis than other diffuse gliomas, we combined microdissection, 2-D DIGE and MS/MS focusing on proteome alterations associated with IDH1 mutation. We first compared tumor tissues (TT) and minimally infiltrated parenchymal tissues (MIT) of four IDH1-mutated oligodendrogliomas to verify whether proteins specific to oligodendroglioma tumor cells could be identified from one patient to another. This study resulted in identification of 68 differentially expressed proteins, with functions related to growth of tumor cells in a nervous parenchyma. We then looked for proteins distinctly expressed in TT harboring either mutant (oligodendrogliomas, n=4) or wild-type IDH1 (oligodendroglial component of malignant glio-neuronal tumors, n=4). This second analysis resulted in identification of distinct proteome patterns composed of 42 proteins. Oligodendrogliomas with a mutant IDH1 had noteworthy enhanced expression of enzymes controlling aerobic glycolysis and detoxification, and anti-apoptosis proteins. In addition, the mutant IDH1 migrated differently from the wild-type IDH1 form. Comparative proteomic analysis might thus be suitable to identify proteome alterations associated with a well-defined mutation.     

Quantitative proteomic analysis of differential proteins in the stroma of nasopharyngeal carcinoma and normal nasopharyngeal epithelial tissue

The importance of stromal cells and the factors that they expressed during cancer initiation and progression have been highlighted by recent literature. To identify the stromal proteins involved in nasopharyngeal carcinoma (NPC) carcinogenesis, we assessed differences in protein expression of the stroma from NPC and normal nasopharyngeal epithelium tissues (NNET) using a quantitative proteomic approach combined with laser capture microdissection (LCM). LCM was performed to purify stromal cells from the NPC and NNET, respectively. The differential proteins between the pooled microdissected tumor and normal stroma were analyzed by two‐dimensional difference gel electrophoresis (2D‐DIGE) combined with mass spectrometry (MS). Twenty differential proteins were identified, and the expression and location of two differential proteins (L ‐plastin and S100A9) were further confirmed by Western blotting and immunohistochemical analysis. Our results will be helpful to study the role of stroma in the NPC carcinogenesis, as well as discover the interaction between NPC cells and their surrounding microenvironment. J. Cell. Biochem. 106: 570–579, 2009. © 2009 Wiley‐Liss, Inc.     

Proteomic analysis of doxorubicin‐induced changes in the proteome of HepG2cells combining 2‐D DIGE and LC‐MS/MS approaches

HepG‐2 cells are widely used as a cell model to investigate hepatocellular carcinomas and the effect of anticancer drugs such as doxorubicin, an effective antineoplastic agent, which has broad antitumoral activity against many solid and hematological malignancies. To investigate the effect of doxorubicin on the protein pattern, we used complementary proteomic workflows including 2‐D gel‐based and gel‐free methods. The analysis of crude HepG2 cell extracts by 2‐D DIGE provided data on 1835 protein spots which was then complemented by MS‐centered analysis of stable isotope labeling by amino acids in cell culture‐labeled cells. The monitoring of more than 1300 distinct proteins, including proteins of the membrane fraction provides the most comprehensive overview on the proteome of the widely used model cell line HepG2. Of the proteins monitored in total, 155 displayed doxorubicin‐induced changes in abundance. Functional analysis revealed major influences of doxorubicin on proteins involved in protein synthesis, DNA damage control, electron transport/mitochondrial function, and tumor growth. The strongest decrease in level was found for proteins involved in DNA replication and protein synthesis, whereas proteins with a function in DNA damage control and oxidative stress management displayed increased levels following treatment with doxorubicin compared with control cells. Furthermore, the doxorubicin‐associated increase in levels of multiple forms of keratins 8, 18, and 19 and other structural proteins revealed an influence on the cytoskeleton network.     

Comparative proteomic analysis of the Arabidopsis cbl1 mutant in response to salt stress

Many environmental stimuli, including light, biotic and abiotic stress factors, induce changes in cellular Ca(2+) concentrations in plants. Such Ca(2+) signatures are perceived by sensor molecules such as calcineurin B-like (CBL) proteins. AtCBL1, a member of the CBL family which is highly inducible by multiple stress signals, is known to function in the salt stress signal transduction pathway and to positively regulate the plant tolerance to salt. To shed light into the molecular mechanisms of the salt stress response mediated by AtCBL1, a two-dimensional DIGE proteomic approach was applied to identify the differentially expressed proteins in Arabidopsis wild-type and cbl1 null mutant plants in response to salt stress. Seventy-three spots were found altered in expression by least 1.2-fold and 50 proteins were identified by MALDI-TOF/TOF-MS, including some well-known and novel salt-responsive proteins. These proteins function in various processes, such as signal transduction, ROS scavenging, energy production, carbon fixation, metabolism, mRNA processing, protein processing and structural stability. Receptor for activated C kinase 1C (RACK1C, spot 715), a WD40 repeat protein, was up-regulated in the cbl1 null mutant, and two rack1c mutant lines showed decreased tolerance to salt stress, suggesting that RACK1C plays a role in salt stress resistance. In conclusion, our work demonstrated the advantages of the proteomic approach in studies of plant biology and identified candidate proteins in CBL1-mediated salt stress signaling network.     

Insulin‐like growth factor 1 receptor signaling induced by supraphysiological doses of IGF‐1 in human peripheral blood lymphocytes

Insulin‐like growth factor‐1 (IGF‐1) mediates some of growth hormone anabolic functions through its receptor, IGF‐1R. Following ligand binding, intracellular signaling pathways are activated favouring proliferation, cell survival, tissue growth, development, and differentiation. IGF‐1 is included in the World Anti‐Doping Agency Prohibited List. While the evidence for IGF‐1 as performance‐enhancing substrate in healthy humans is still weak, clinical studies demonstrated that the endogenous growth hormone/IGF‐1 excess is associated with cardiovascular implications. Previously, we demonstrated that human peripheral blood lymphocytes represent a suitable system to identify a gene signature, related to dihydrotestosterone or IGF‐1 abuse, independent from the type of sport. In addition, in a proteomic study, we demonstrated that dihydrotestosterone hyperdosage affects cell motility and apoptosis. Here, we investigate the doping action of IGF‐1 by means of a differential proteomic approach and specific protein arrays, revealing an active cytoskeletal reorganization mediated by Stat‐1; moreover, IGF‐1 stimulation produces a sustained activation of different signaling pathways as well as an overproduction of cytokines positively related to immune response and inflammation. In conclusion, these data indicate that, following IGF‐1 hyperdosage, circulating peripheral blood lymphocytes could be more prone to transendothelial migration.     

Metabolic alteration of HepG2 in scaffold-based 3-D culture: proteomic approach

3-D cell culture models are important in cancer biology since they provide improved understanding of tumor microenvironment. We have established a 3-D culture model using HepG2 in natural collagen-based scaffold to mimic the development of small avascular tumor in vivo. Morphological characterization showed that HepG2 colonies grew within the interior of the scaffold and showed enhanced extracellular matrix deposition. High levels of cell proliferation in the outermost regions of the scaffold created a hypoxic microenvironment in the 3-D culture system, as indicated by hypoxia-inducible factor-1α stabilization, detectable by Western blotting and immunohistochemistry. Proteomic studies showed decreased expression of several mitochondrial proteins and increased expression of proteins in anaerobic glycolysis under 3-D culture compared to monolayer culture. Creatine kinase was also upregulated in 3-D culture, indicating its possible role as an important energy buffer system under hypoxic microenvironment. Increased levels of proteins in nucleotide metabolism may relate to cellular energy. Thus, our results suggest that HepG2 cells under 3-D culture adapt their energy metabolism in response to hypoxic conditions. Metabolic alterations in the 3-D culture model may relate to physiological changes relevant to development of small avascular tumor in vivo and their study may improve future therapeutic strategies.     

Honokiol inhibits HepG2 migration via down‐regulation of IQGAP1 expression discovered by a quantitative pharmaceutical proteomic analysis

Honokiol (HNK), a natural small molecular product, inhibited proliferation of HepG2 cells and exhibited anti‐tumor activity in nude mice. In this article, we applied a novel sensitive stable isotope labeling with amino acids in cell culture‐based quantitative proteomic method and a model of nude mice to investigate the correlation between HNK and the hotspot migration molecule Ras GTPase‐activating‐like protein (IQGAP1). The quantitative proteomic analysis showed that IQGAP1 was 0.53‐fold down‐regulated under 10 μg/mL HNK exposure for 24 h on HepG2 cells. Migration ability of HepG2 cells under HNK treatment was correlated with its expression level of IQGAP1. In addition, the biochemical validation on HepG2 cells and the tumor xenograft model further demonstrated that HNK decreased the expression level of IQGAP1 and its upstream proteins Cdc42/Rac1. These data supported that HNK can modulate cell adhesion and cell migration by acting on Cdc42/Rac1 signaling via IQGAP1 interactions with its upstream Cdc42/Rac1 proteins, which is a new molecular mechanism of HNK to exert its anti‐tumor activity.     

Differential proteomic analysis of lymphatic,venous, and arterial endothelial cells extracted from bovine mesenteric vessels

Differential protein profiling by 2‐D PAGE is generally useful in biomarker discovery, proteome analysis and routine sample preparation prior to analysis by MS. The goal of this study was to compare 2‐D PAGE‐resolved protein profile of lymphatic endothelial cells to those of venous, and arterial endothelial cells isolated from lymphatic and blood vessels of bovine mesentery (bm). Three 2‐D PAGE electrophoretograms were produced for each of the three cell types and quantitatively analyzed. Protein identification by LC‐MS/MS was performed to identify 39 proteins found to be present at statistically significantly different levels in the three cell types (p<0.05). Most of the 39 proteins have not been previously reported in EC proteomic studies of 2‐D PAGE electrophoretograms. Three proteins, HSPA1B (HSP70 family member), HSPB1 (HSP27 family member), and UBE2D3 (a member of E2 ubiquitin‐conjugating enzymes) found to be at highest levels in bm arterial endothelial cells, bm venous endothelial cells, and bm lymphatic endothelial cells, respectively, were validated by immunoblotting with appropriate antibodies. The lack of substantial overlap between our results and those of other groups' comparative studies are discussed. Functional implications of differences in levels of various proteins identified in the three cell types are also discussed.     

Synergistic effect of DHT and IGF‐1 hyperstimulation in human peripheral blood lymphocytes

The abuse of mixed or combined performance‐enhancing drugs is widespread among athletes and amateurs, adults and adolescents. Clinical studies demonstrated that misuse of these doping agents is associated with serious adverse effects to many organs in human. Previously, we demonstrated in human peripheral blood lymphocytes that high doses of anabolic androgenic steroids, such as dihydrotestosterone (DHT) and growth factors, such as insulin‐like growth factor‐1 (IGF‐1), have effects at gene and protein levels. Supraphysiological treatments of DHT and IGF‐1 affected the expression of genes involved in skeletal muscle disorders as well as in cell‐mediated immunological response. At protein level, DHT hyperdosage affects cell motility and apoptosis; IGF‐1 hyperstimulation triggers an active cytoskeletal reorganization and an overproduction of immune response‐ and inflammation‐related cytokines. In this study, we investigate the combined effects of DHT and IGF‐1 hyperdosage in peripheral blood lymphocytes using a differential proteomic approach. DHT and IGF‐1 combined treatment affects cell adhesion, migration, and survival through modulation of expression levels of cytokines and paxillin‐signaling‐related proteins, and activation of several pathways downstream focal adhesion kinase. Our results indicate a synergistic effect of DHT and IGF‐1 which has potential implications for health risk factors.     

A Quantitative Proteomics Study of Early Heat‐Regulated Proteins by Two‐Dimensional Difference Gel Electrophoresis Identified OsUBP21 as a Negative Regulator of Heat Stress Responses in Rice

To understand the early heat shock (HS)‐regulated cellular responses that influence the tolerance of rice plant to high environmental temperatures, two‐dimensional difference gel electrophoresis (2D‐DIGE) is performed to explore the early HS‐regulated proteome. Multiple proteins that show abundance changes after 1 and 5 min of HS treatment are identified. Of the early HS‐regulated proteins identified, the abundance of a ubiquitin‐specific protease, OsUBP21, and its Arabidopsis homolog, AtUBP13, is found to be upregulated by 5 min of HS treatment. Further, knocking the expression of OsUBP21 or AtUBP13 down or out increases the tolerance of rice and Arabidopsis plants to HS stress, suggesting that the function of these ubiquitin‐specific proteases in regulating plant HS responses is conserved between monocots and dicots. 2D‐DIGE showed a group of proteins are differentially regulated in wild‐type and ubp21 mutant after 30 min of HS treatment. Among these proteins, 11 are found to interact directly with OsUBP21; thus, they may be targets of OsUBP21. Future analyses of the roles of these OsUBP21‐interacting proteins in plant HS responses will help reveal the protein ubiquitination/deubiquitination‐regulated cellular responses induced by HS in rice.     

The interaction profile of homologous recombination repair proteins RAD51C,RAD51D and XRCC2 as determined by proteomic analysis

The RAD51 family of proteins is involved in homologous recombination (HR) DNA repair and maintaining chromosome integrity. To identify candidates that interact with HR proteins, the mouse RAD51C, RAD51D and XRCC2 proteins were purified using bacterial expression systems and each of them used to co‐precipitate interacting partners from mouse embryonic fibroblast cellular extracts. Mass spectroscopic analysis was performed on protein bands obtained after 1‐D SDS‐PAGE of co‐precipitation eluates from cell extracts of mitomycin C treated and untreated mouse embryonic fibroblasts. Profiling of the interacting proteins showed a clear bias toward nucleic acid binding and modification proteins. Interactions of four candidate proteins (SFPQ, NONO, MSH2 and mini chromosome maintenance protein 2) were confirmed by Western blot analysis of co‐precipitation eluates and were also verified to form ex vivo complexes with RAD51D. Additional interacting proteins were associated with cell division, embryo development, protein and carbohydrate metabolism, cellular trafficking, protein synthesis, modification or folding, and cell structure or motility functions. Results from this study are an important step toward identifying interacting partners of the RAD51 paralogs and understanding the functional diversity of proteins that assist or regulate HR repair mechanisms.     

Differential proteomic analysis of white adipose tissues from T2D KKAy mice by LC‐ESI‐QTOF

Type 2 diabetes (T2D) has become a worldwide increasingly social health burden for its high morbidity and heightened prevalence. As one of the main tissues involved in uptake of glucose under the stimulation of insulin, WAT plays very important role in metabolic and homeostasis regulation. We performed a differential proteomics study to investigate alterations in epididymis fat pad of high fat diet fed T2D KKAy mice compared to normal fed C57BL/6J mice, by ¹⁸O‐labeling relative quantitative technique. Among 329 confidently identified proteins, 121 proteins showed significant changes with CV ≤ 20% (fold changes of >2 or <0.5 as threshold). According to GO classification, we found that altered proteins contained members of biological processes of metabolic process, oxidative stress, ion homeostasis, apoptosis and cell division. In metabolic, proteins assigned to fatty acid biosynthesis (FAS etc.) were decreased, the key enzyme (ACOX3) in β‐oxidation process was increased. Increased glycolysis enzymes (ENOB etc.) and decreased TCA cycle related enzymes (SCOT1 etc.) suggested that glucose metabolism in mitochondria of T2D mice might be impaired. Elevated oxidative stress was observed with alterations of a series of oxidordeuctase (QSOX1 etc.). Besides, alterations of ion homeostasis (AT2C1 etc.) proteins were also observed. The enhancement of cell proliferation associated proteins (ELYS etc.) and inhibition of apoptosis associated proteins (RASF6 etc.) in WAT might contributed to the fat pad and body weight gain. Overall, these changes in WAT may serve as a reference for understanding the functional mechanism of T2D.     

The stromal‐vascular fraction of adipose tissue contributes to major differences between subcutaneous and visceral fat depots

Adipose tissue represents a complex tissue both in terms of its cellular composition, as it includes mature adipocytes and the various cell types comprising the stromal‐vascular fraction (SVF), and in relation to the distinct biochemical, morphological and functional characteristics according to its anatomical location. Herein, we have characterized the proteomic profile of both mature adipocyte and SVF from human visceral adipose tissue (VAT) and subcutaneous adipose tissue (SAT) fat depots in order to unveil differences in the expression of proteins which may underlie the distinct association of VAT and SAT to several pathologies. Specifically, 24 proteins were observed to be differentially expressed between SAT SVF versus VAT SVF from lean individuals. Immunoblotting and RT‐PCR analysis confirmed the differential regulation of the nuclear envelope proteins lamin A/C, the membrane‐cytoskeletal linker ezrin and the enzyme involved in retinoic acid production, aldehyde dehydrogenase 1A2, in the two fat depots. In sum, the observation that proteins with important cell functions are differentially distributed between VAT and SAT and their characterization as components of SVF or mature adipocytes pave the way for future research on the molecular basis underlying diverse adipose tissue‐related pathologies such as metabolic syndrome or lipodystrophy.     

2-D DIGE analysis of UV-C radiation-responsive proteins in globe artichoke leaves

Plants respond to ultraviolet stress inducing a self-defence through the regulation of specific gene family members. The UV acclimation is the result of biochemical and physiological processes, such as enhancement of the antioxidant enzymatic system and accumulation of UV-absorbing phenolic compounds (e.g. flavonoids). Globe artichoke is an attractive species for studying the protein network involved in UV stress response, being characterized by remarkable levels of inducible antioxidants. Proteomic tools can assist the evaluation of the expression patterns of UV-responsive proteins and we applied the difference in-gel electrophoresis (DIGE) technology for monitoring the globe artichoke proteome variation at four time points following an acute UV-C exposure. A total of 145 UV-C-modulated proteins were observed and 119 were identified by LC-MS/MS using a ～144,000 customized Compositae protein database, which included about 19,000 globe artichoke unigenes. Proteins were Gene Ontology (GO) categorized, visualized on their pathways and their behaviour was discussed. A predicted protein interaction network was produced and highly connected hub-like proteins were highlighted. Most of the proteins differentially modulated were chloroplast located, involved in photosynthesis, sugar metabolisms, protein folding and abiotic stress. The identification of UV-C-responsive proteins may contribute to shed light on the molecular mechanisms underlying plant responses to UV stress.