Ultrastructural Localization and Molecular Associations of HCV Capsid Protein in Jurkat T Cells.

Hepatitis C virus core protein is a highly basic viral protein that multimerizes with itself to form the viral capsid. When expressed in CD4+ T lymphocytes, it can induce modifications in several essential cellular and biological networks. To shed light on the mechanisms underlying the alterations caused by the viral protein, we have analyzed HCV-core subcellular localization and its associations with host proteins in Jurkat T cells. In order to investigate the intracellular localization of Hepatitis C virus core protein, we have used a lentiviral system to transduce Jurkat T cells and subsequently localize the protein using immunoelectron microscopy techniques. We found that in Jurkat T cells, Hepatitis C virus core protein mostly localizes in the nucleus and specifically in the nucleolus. In addition, we performed pull-down assays combined with Mass Spectrometry Analysis, to identify proteins that associate with Hepatitis C virus core in Jurkat T cells. We found proteins such as NOLC1, PP1γ, ILF3, and C1QBP implicated in localization and/or traffic to the nucleolus. HCV-core associated proteins are implicated in RNA processing and RNA virus infection as well as in functions previously shown to be altered in Hepatitis C virus core expressing CD4+ T cells, such as cell cycle delay, decreased proliferation, and induction of a regulatory phenotype. Thus, in the current work, we show the ultrastructural localization of Hepatitis C virus core and the first profile of HCV core associated proteins in T cells, and we discuss the functions and interconnections of these proteins in molecular networks where relevant biological modifications have been described upon the expression of Hepatitis C virus core protein. Thereby, the current work constitutes a necessary step toward understanding the mechanisms underlying HCV core mediated alterations that had been described in relevant biological processes in CD4+ T cells.

Serum proteomic changes in adults with obstructive sleep apnoea.

To examine whether differentially expressed proteins are present in the serum of patients with obstructive sleep apnoea (OSA), iTRAQ techniques (isobaric tags for relative and absolute quantification) were employed in a prospective study. Individuals were assigned to either a non-OSA control group (apnoea-hypopnoea index, AHI <5) or an OSA group (AHI ≥5). Blood samples were collected, aliquoted and frozen at -80 °C. Protein digestion and tagging with iTRAQ4plex® and mass spectrometry analysis was then performed (MALDI TOF/TOF). Ten male subjects were included in the control group (age = 45 ± 9.7 years) and 30 male patients in the OSA group (age = 45 ± 10.7 years), the latter being then subdivided into three severity groups. A total of 103 proteins were identified with differential levels between patients with OSA and controls. Of these, 11 proteins were underexpressed and 19 were overexpressed in patients with OSA. C4BPA and thrombospondin were underexpressed in all three OSA severity groups. Among the overexpressed proteins, 13 were overexpressed in the mild OSA group, seven in the moderate group and five in the severe group. Analysis of interactions between the identified proteins revealed that protein alterations in OSA are primarily associated with derangements in lipid and vascular metabolic pathways. This study provides initial evidence that differential protein expression occurs in adults with OSA, and that such proteins change according to disease severity, and appear to primarily involve lipid and vascular metabolic pathways.

Phosphoproteome analysis of Lotus japonicus roots reveals shared and distinct components of symbiosis and defense.

Plant roots form an intracellular symbiosis with nitrogen-fixing bacteria while maintaining the capacity for defending themselves against bacterial pathogens. To investigate the molecular relationship between these opposing cellular responses, we compared changes in the root phosphoproteome of the legume Lotus japonicus occurring within minutes after perception of nodulation factor (NF), a symbiotic signaling molecule, to those elicited by flagellin peptide (flg22), a conserved pathogen-associated peptide motif present in flagellar protein of a wide range of bacteria. Phosphoproteins were visualized by autoradiography of two-dimensional polyacrylamide gels after in vivo labeling with 33P-orthophosphate. Comparisons of NF- and flg22-induced phosphoprotein patterns revealed signal-specific responses but also a surprisingly large overlap. Specificity of the responses was observed because the NF receptor kinases NFR1 and NFR5 were both required for NF- but not for flg22-mediated changes in the phosphoproteome. Moreover, NF did not stimulate an oxidative burst or activation of mitogen-activated protein kinases, two common markers for early defense responses that were induced by flg22. Inhibitor studies revealed that phosphorylation of at least some of the proteins in response to NF requires phospholipase D (PLD) whereas regulation of the flg22 phosphoproteome is PLD-independent. Although plant signal transduction during symbiosis and defense utilizes distinct components, phosphorylation of overlapping sets of proteins is achieved.

Phosphoproteomic analysis of nuclei-enriched fractions from Arabidopsis thaliana.

Phosphorylation is a ubiquitous regulatory mechanism, that governs the activity, subcellular localisation and molecular interactions of proteins. To identify a broad range of nuclear phosphoproteins from Arabidopsis thaliana, we enriched for nuclei from suspension cell cultures and seedlings before extensive fractionation and identification of phosphopeptides by mass spectrometry. We identified 416 phosphopeptides from 345 proteins with high confidence. Our data show that sub-cellular fractionation is an effective strategy for identifying nuclear phosphoproteins, two thirds of our dataset are known or predicted to be nuclear localised and one half of the nuclear localised proteins have novel phosphorylation sites. We identified novel phosphorylation sites on transcription factors, chromatin remodelling proteins, RNA silencing components and the spliceosome. Intriguingly, we also identified phosphorylation sites on several proteins associated with Golgi vesicle trafficking such as the exocyst complex, and speculate that these may be involved in cell plate formation during cytokinesis.

Preparative denaturing isoelectric focusing for enhancing sensitivity of proteomic studies.

Substantial evidence implicates important roles for both protein phosphorylation and protein degradation in regulation of plant defense responses. Therefore, interest is growing in applying proteomics techniques to investigate these posttranscriptional changes. We have found, however, that most proteins of interest are not visible on two-dimensional (2D) gels without previous prefractionation. This chapter describes the use of preparative denaturing isoelectric focusing to enrich for proteins of specific isoelectric points before separation by 2D gels. This method significantly increases the sensitivity of 2D gel-based comparisons.