Analysis of DCM associated protein alterations of human right and left ventricles.

Dilated cardiomyopathy (DCM) is characterized by ventricular chamber enlargement and impaired myocardial function. Endomyocardial biopsies (EMB) enable immunohistochemical and molecular characterization of this disease. However, knowledge about specific molecular patterns and their relation to cardiac function in both ventricles is rare. Therefore, we performed a mass spectrometric analysis of 28 paired EMBs of left (LV) and right ventricles (RV) of patients with DCM or suspected myocarditis allowing quantitative profiling of 743 proteins. We analysed associations between protein abundance of LV and RV as well as the echocardiographic parameters LVEF, TAPSE, LVEDDI, and RVEDDI by linear regression models. Overall, more LV than RV proteins were associated with LV parameters or with RVEDDI. Most LV and RV proteins increasing in level with impairing of LVEF were annotated to structural components of cardiac tissue. Additionally, a high proportion of LV proteins with metabolic functions decreased in level with decreasing LVEF. Results were validated with LV heart sections of a genetic murine heart failure model. The study shows, that remodelling and systolic dysfunction in DCM is mirrored by distinct alterations in protein composition of both ventricles. Loss of LV systolic function is reflected predominantly by alterations in proteins assigned to metabolic functions in the LV whereas structural remodelling was more obvious in the RV. Alterations related to intermediate filaments were seen in both ventricles and highlight such proteins as early indicators of LV loss of function. SIGNIFICANCE: The present study report protein sets in the RV and the LV being associated with ventricular function and remodelling in DCM. Protein abundances in the LV and the RV emphasize and expand current knowledge on pathophysiological changes in heart failure and DCM. While RV and LV EMBs do not differ concerning diagnostic assessment of inflammatory status and virus persistence, additional information reflecting disease severity associated protein alterations can be gained by EMB protein profiling. RV and LV protein data provided complementary information. The protein pattern of the LV reflects metabolic changes and an impaired energy production, which is associated with the degree of LV systolic dysfunction and remodelling and may yield important information about the disease status in DCM. On the other hand, at this disease stage of DCM with still preserved RV function, RV alterations in structural proteins may reflect myocardial compensatory protective mechanisms for maintenance of structure and cellular function. The study highlight particular proteins being of interest as heart failure biomarkers in both ventricles which seem to reflect the severity of the disease. Further comparative studies between different HF aetiologies have to evaluate those proteins as markers specific for DCM.

From Proteomics to Personalized Medicine: The Importance of Isoflavone Dose and Estrogen Receptor Status in Breast Cancer Cells.

Continuing efforts are directed towards finding alternative breast cancer chemotherapeutics, with improved safety and efficacy profiles. Soy isoflavones represent promising agents but, despite extensive research, limited information exists regarding their impact on the breast cancer cell proteome. The purpose of this study was to compare the proteomic profiles of MCF-7 (estrogen responsive) and MDA-MB-231 (estrogen non-responsive) breast cancer cells exposed to different concentrations of genistein, daidzein, and a soy seed extract, using a high throughput LC-UDMSE protein profiling approach. The 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) assay confirmed the dual activity of soy isoflavones on MCF-7 cells and the inhibitory effect on MDA-MB-231 cells. Proteome profiling of paramagnetic beads prepared peptides by nano-LC UDMSE and pathway enrichment analysis revealed that isoflavones affected distinct molecular pathways in MCF-7 and MDA-MB-231 cells, such as tyrosine kinases signaling pathway, cytoskeleton organization, lipid and phospholipid catabolism, extracellular matrix degradation and mRNA splicing. Also, in MCF-7 cells, low and high isoflavone doses induced different changes of the proteome, including cell cycle alterations. Therefore, the expression of estrogen receptors and the isoflavone dose are determinant factors for the molecular impact of isoflavones and must be taken into account when considering adjuvant breast cancer therapy towards personalized medicine.

Plasma protein absolute quantification by nano-LC Q-TOF UDMSE for clinical biomarker verification.

BACKGROUND AND AIMS: Proteome-based biomarker studies are targeting proteins that could serve as diagnostic, prognosis, and prediction molecules. In the clinical routine, immunoassays are currently used for the absolute quantification of such biomarkers, with the major limitation that only one molecule can be targeted per assay. The aim of our study was to test a mass spectrometry based absolute quantification method for the verification of plasma protein sets which might serve as reliable biomarker panels for the clinical practice. METHODS: Six EDTA plasma samples were analyzed after tryptic digestion using a high throughput data independent acquisition nano-LC Q-TOF UDMSE proteomics approach. Synthetic Escherichia coli standard peptides were spiked in each sample for the absolute quantification. Data analysis was performed using ProgenesisQI v2.0 software (Waters Corporation). RESULTS: Our method ensured absolute quantification of 242 non redundant plasma proteins in a single run analysis. The dynamic range covered was 105. 86% were represented by classical plasma proteins. The overall median coefficient of variation was 0.36, while a set of 63 proteins was found to be highly stable. Absolute protein concentrations strongly correlated with values reviewed in the literature. CONCLUSIONS: Nano-LC Q-TOF UDMSE proteomic analysis can be used for a simple and rapid determination of absolute amounts of plasma proteins. A large number of plasma proteins could be analyzed, while a wide dynamic range was covered with low coefficient of variation at protein level. The method proved to be a reliable tool for the quantification of protein panel for biomarker verification in the clinical practice.

Data on the impact of the blood sample collection methods on blood protein profiling studies.

Complete blood protein profiles of 4 different blood sample collection methods (EDTA-, heparin- and citrate plasma and serum) were investigated and the data presented herein is an extension of the research article in Ilies et al. [1]. Specimens were depleted of 6 highly abundant proteins and protein profiling was assessed by nano-LC UDMSE. Exhaustive protein sets and protein abundances before and after depletion are presented in tables and figures. Also, the core protein set and the unique proteins for each sample collection method previously described [1] are disclosed.

Impact of blood sample collection methods on blood protein profiling studies.

Pre-analytical factors have a significant impact on the integrity of blood samples used for qualitative and quantitative protein profiling. Important factors are the type of the blood collection tube and the anticoagulant used. Only a few studies have been performed to assess these variables by comparing only serum and EDTA plasma collection tubes with some target proteins or peptides. In this study, we investigated the protein profile of blood samples collected in serum, EDTA-, heparin-, and citrate plasma tubes. Furthermore, we compared the depletion efficiency of 6 high abundant proteins, the detectable blood protein profile, the variance, and the coverage of the detectable protein sets. The largest differences were found between serum and plasma samples with respect to the peptide number and the occurrence of classical blood proteins. The heparin plasma evidenced a high number of detectable proteins, low global variance and a high similarity to EDTA- and citrate plasma and may therefore be also a useful test tube for blood protein profiling. In addition, a core set of blood proteins were described and the portions and compositions of sampling specific proteins were disclosed. Therefore, pre-analytical issues such as the sample collection method should be considered for protein profiling studies.

Mass spectrometric phosphoproteome analysis of small-sized samples of human neutrophils.

BACKGROUND: Global analysis of stimulus-dependent changes in the neutrophil phosphoproteome will improve the understanding of neutrophil signal transduction and function in diverse disease settings. However, gel-free phosphoproteomics of neutrophils in clinical studies is hampered by limited sample amounts and requires protein extract stability, efficient tryptic digestion and sensitive phosphopeptide enrichment in a protease-rich environment. For development of an appropriate workflow, we assessed neutrophil protein stability in urea-based lysis buffers and determined feasibility of gel-free phosphoproteomic analyses using polymer-based metal ion affinity capture (PolyMAC). METHODS: Western blotting, phosphopeptide enrichment and mass spectrometric analyses of samples of neutrophils were performed. RESULTS: Degradation of proteins in neutrophil extracts was observed after preparation with a urea-containing lysis buffer and could be prevented by addition of highly concentrated protease inhibitors. Subsequent tryptic digestion and PolyMAC-based phosphopeptide enrichment proved efficient with accordingly prepared neutrophil samples. Applying the new workflow, formyl­methionyl­leucyl­phenylalanine-induced phosphorylation of extracellular signal-regulated kinases 1 and 2 (ERK1/2) was detected after gel-free and gel-based phosphoproteomic analyses as proof of principle from 20 ml of whole blood. Furthermore, phosphorylation of other ERK1/2 pathway-associated proteins was monitored. CONCLUSION: We provide a workflow for efficient, gel-free phosphoproteome analyses with small-sized neutrophil samples, suitable for application in clinical studies.

Activated Protein C Ameliorates Renal Ischemia-Reperfusion Injury by Restricting Y-Box Binding Protein-1 Ubiquitination.

Ischemia-reperfusion injury (IRI) is the leading cause of ARF. A pathophysiologic role of the coagulation system in renal IRI has been established, but the functional relevance of thrombomodulin (TM)-dependent activated protein C (aPC) generation and the intracellular targets of aPC remain undefined. Here, we investigated the role of TM-dependent aPC generation and therapeutic aPC application in a murine renal IRI model and in an in vitro hypoxia and reoxygenation (HR) model using proximal tubular cells. In renal IRI, endogenous aPC levels were reduced. Genetic or therapeutic reconstitution of aPC efficiently ameliorated renal IRI independently of its anticoagulant properties. In tubular cells, cytoprotective aPC signaling was mediated through protease activated receptor-1- and endothelial protein C receptor-dependent regulation of the cold-shock protein Y-box binding protein-1 (YB-1). The mature 50 kD form of YB-1 was required for the nephro- and cytoprotective effects of aPC in vivo and in vitro, respectively. Reduction of mature YB-1 and K48-linked ubiquitination of YB-1 was prevented by aPC after renal IRI or tubular HR injury. aPC preserved the interaction of YB-1 with the deubiquitinating enzyme otubain-1 and maintained expression of otubain-1, which was required to reduce K48-linked YB-1 ubiquitination and to stabilize the 50 kD form of YB-1 after renal IRI and tubular HR injury. These data link the cyto- and nephroprotective effects of aPC with the ubiquitin-proteasome system and identify YB-1 as a novel intracellular target of aPC. These insights may provide new impetus for translational efforts aiming to restrict renal IRI.

Proteome analysis of heart biopsies using a TRIzol-based protein extraction.

BACKGROUND: When dealing with rare samples of which only minute amounts are available, e.g. human heart tissue, simultaneous extraction of DNA, RNA, and proteins from the same sample is crucial for a comprehensive analysis on the physiological or pathological state of such precious tissue. In this study we provethe efficacy of a modified TRIzol protocol to extract proteins from samples of small size, such as endomyocardial biopsies (EMBs). METHOD: Initially, we compared TRIzol protein extraction efficacy to urea/thiourea extraction from total murine left ventricles and then small amounts of left and right murine ventricles. Finally, we applied the modified TRIzol protocol to the proteomic profiling of EMBs from human left and right ventricles. RESULTS: Analysis of the proteins extracted from mouse and human samples revealed sufficient protein amount for downstream applications. Thus, LC-tandem mass spectrometry permitted highly sensitive protein identifications and comparable protein patterns and coverage of cellular components as a standard extraction protocol. 2D gel-based analysis confirmed the high quality and reproducibility of the TRIzol derived protein extracts. CONCLUSION: Our results prove the utility of the modified TRIzol protocol for proteomics analyses involving minute amounts of precious samples.

Comparative evaluation of peptide desalting methods for salivary proteome analysis.

BACKGROUND: Reliability and reproducibility are common requirements for high-quality generation of proteome data using mass spectrometry. The aim of this study was to compare four single-step desalting devices to provide a reproducible, high-recovery method for concentrating and purifying tryptic peptides before LC-MS/MS measurements. MATERIAL AND METHODS: Four different methods for peptide purification prior LC-MS/MS analyses (µC18 ZipTip® pipette tips, C18 ZipTip® pipette tips, TopTip C-18 and OASIS® HLB µElution Plate) were tested using whole saliva from healthy volunteers. A number of protein identifications and salivary protein patterns were analyzed comparatively. RESULTS: Each desalting device facilitated the identification of about 340 proteins. Purification-method dependent variations in protein composition were observed. Nevertheless, the overall inter-approach Pearson correlation coefficients of >0.95 indicate high reproducibility, reliability and recovery of proteins. CONCLUSION: The applied devices performed equally well in the removal of low molecular weight contaminants and provide high-quality data for quantitative proteomic analysis. Thus, selection should be primarily based on the amount of peptide extract available and the number of samples to be processed.

Bone marrow-derived macrophages from BALB/c and C57BL/6 mice fundamentally differ in their respiratory chain complex proteins, lysosomal enzymes and components of antioxidant stress systems.

Macrophages are essential components of the innate immune system and crucial for pathogen elimination in early stages of infection. We previously observed that bone marrow-derived macrophages (BMMs) from C57BL/6 mice exhibited increased killing activity against Burkholderia pseudomallei compared to BMMs from BALB/c mice. This effect was particularly pronounced when cells were treated with IFN-γ. To unravel mechanisms that could explain these distinct bactericidal effects, a comparative combined proteome and transcriptome analysis of untreated and IFN-γ treated BALB/c and C57BL/6 BMMs under standardized serum-free conditions was carried out. We found differences in gene expression/protein abundance belonging to cellular oxidative and antioxidative stress systems. Genes/proteins involved in the generation of oxidant molecules and the function of phagosomes (respiratory chain ATPase, lysosomal enzymes, cathepsins) were predominantly higher expressed/more abundant in C57BL/6 BMMs. Components involved in alleviation of oxidative stress (peroxiredoxin, mitochondrial superoxide dismutase) were more abundant in C57BL/6 BMMs as well. Thus, C57BL/6 BMMs seemed to be better equipped with cellular systems that may be advantageous in combating engulfed pathogens. Simultaneously, C57BL/6 BMMs were well protected from oxidative burst. We assume that these variations co-determine differences in resistance between BALB/c and C57BL/6 mice observed in many infection models. BIOLOGICAL SIGNIFICANCE: In this study we performed combined transcriptome and proteome analyses on BMMs derived from two inbred mouse strains that are frequently used for studies in the field of host-pathogen interaction research. Strain differences between BALB/c and C57BL/6 BMMs were found to originate mainly from different protein abundance levels rather than from different gene expression. Differences in abundance of respiratory chain complexes and lysosomal proteins as well as differential regulation of components belonging to various antioxidant stress systems help to explain long-known differences between the mouse strains concerning their different susceptibility in several infection models.

Characterization of the EGFR interactome reveals associated protein complex networks and intracellular receptor dynamics.

Growth factor receptor mediated signaling is meanwhile recognized as a complex signaling network, which is initiated by recruiting specific patterns of adaptor proteins to the intracellular domain of epidermal growth factor receptor (EGFR). Approaches to globally identify EGFR-binding proteins are required to elucidate this network. We affinity-purified EGFR with its interacting proteins by coprecipitation from lysates of A431 cells. A total of 183 proteins were repeatedly detected in high-resolution MS measurements. For 15 of these, direct interactions with EGFR were listed in the iRefIndex interaction database, including Grb2, shc-1, SOS1 and 2, STAT 1 and 3, AP2, UBS3B, and ERRFI. The newly developed Cytoscape plugin ModuleGraph allowed retrieving and visualizing 93 well-described protein complexes that contained at least one of the proteins found to interact with EGFR in our experiments. Abundances of 14 proteins were modulated more than twofold upon EGFR activation whereof clathrin-associated adaptor complex AP-2 showed 4.6-fold enrichment. These proteins were further annotated with different cellular compartments. Finally, interactions of AP-2 proteins and the newly discovered interaction of CIP2A could be verified. In conclusion, a powerful technique is presented that allowed identification and quantitative assessment of the EGFR interactome to provide further insight into EGFR signaling.

Comparative evaluation of saliva collection methods for proteome analysis.

BACKGROUND: Saliva collection devices are widely used for large-scale screening approaches. This study was designed to compare the suitability of three different whole-saliva collection approaches for subsequent proteome analyses. METHODS: From 9 young healthy volunteers (4 women and 5 men) saliva samples were collected either unstimulated by passive drooling or stimulated using a paraffin gum or Salivette® (cotton swab). Saliva volume, protein concentration and salivary protein patterns were analyzed comparatively. RESULTS: Samples collected using paraffin gum showed the highest saliva volume (4.1±1.5 ml) followed by Salivette® collection (1.8±0.4 ml) and drooling (1.0±0.4 ml). Saliva protein concentrations (average 1145 µg/ml) showed no significant differences between the three sampling schemes. Each collection approach facilitated the identification of about 160 proteins (≥2 distinct peptides) per subject, but collection-method dependent variations in protein composition were observed. CONCLUSION: Passive drooling, paraffin gum and Salivette® each allows similar coverage of the whole saliva proteome, but the specific proteins observed depended on the collection approach. Thus, only one type of collection device should be used for quantitative proteome analysis in one experiment, especially when performing large-scale cross-sectional or multi-centric studies.

Noncovalent interaction of G-quadruplex DNA with acridine at low concentration monitored by MALDI-TOF mass spectrometry.

The telomeric G-rich single-stranded DNA d(T(2)G(8)) can adopt in vitro G-quadruplex structure, even at low DNA concentration. Studies on stability of telomeric structures, has gained importance recently as the molecules, which can stabilize quadruplex structure, can inhibit cancer progression. In this study, G-quadruplex structure is formed by 1.0 mM NH(4)(I) ion. Stability of G-quadruplex complex is studied on interaction with acridine using CD and MALDI-TOF mass spectrometry. MALDI-TOF mass spectrometric experiments were carried out mainly to observe the noncovalent drug-DNA interactions at low concentration. From MALDI-TOF spectrum, it is identified that three ammonium ions are required for the formation of G-quadruplex structure and to provide stability to NH(4)(I)-G-quadruplex complex. With MALDI-TOF it is evident that two acridine molecules interact with NH(4)(I) G-quadruplex complex. CD studies, shows that stability of NH(4)(I) G-quadruplex, decreases and conformation change takes place on interaction with acridine. Interaction with drug reduces mostly due to transformation of G-quadruplex complex to single stranded DNA.