Membrane lipids were once thought to be homogenously distributed in the 2D surface of a membrane, but the lipid raft theory suggests that cholesterol and sphingolipids partition away from other membrane lipids. Lipid raft theory further implicates these cholesterol-rich domains in many processes such as signaling and vesicle traffic. However, direct characterization of rafts has been difficult, because they cannot be isolated in pure form. In the first functional proteomic analysis of rafts, we use quantitative high-resolution MS to specifically detect proteins depleted from rafts by cholesterol-disrupting drugs, resulting in a set of 241 authentic lipid raft components. We detect a large proportion of signaling molecules, highly enriched versus total membranes and detergent-resistant fractions, which thus far biochemically defined rafts. Our results provide the first large-scale and unbiased evidence, to our knowledge, for the connection of rafts with signaling and place limits on the fraction of plasma membrane composed by rafts.
Protein localization to membrane-enclosed organelles is a central feature of cellular organization. Using protein correlation profiling, we have mapped 1,404 proteins to ten subcellular locations in mouse liver, and these correspond with enzymatic assays, marker protein profiles, and confocal microscopy. These localizations allowed assessment of the specificity in published organellar proteomic inventories and demonstrate multiple locations for 39% of all organellar proteins. Integration of proteomic and genomic data enabled us to identify networks of coexpressed genes, cis-regulatory motifs, and putative transcriptional regulators involved in organelle biogenesis. Our analysis ties biochemistry, cell biology, and genomics into a common framework for organelle analysis.
Focal adhesions are specialized attachment and signaling centers that form at sites of cell-matrix contacts. We employed a quantitative mass spectrometry-based method called SILAC to identify and quantify proteins interacting in an attachment-dependent manner with focal adhesion proteins. Subsequent confocal microscopy revealed a previously undescribed structure, which we have termed a spreading initiation center (SIC), existing only in early stages of cell spreading. SICs contain focal adhesion markers, appear to be surrounded by an actin sheath, and, surprisingly, contain numerous RNA binding proteins, ribosomal RNA, and perhaps other RNAs. Interfering with the function of FUS/TLS, hnRNP K, and hnRNP E1 results in increased spreading. Spreading initiation centers are ribonucleoprotein complexes distinct from focal adhesions and demonstrate a role for RNA and RNA binding proteins in the initiation of cell spreading.
The genome sequences of important model systems are available and the focus is now shifting to large-scale experiments enabled by this data. Following in the footsteps of genomics, we have functional genomics, proteomics, and even metabolomics, roughly paralleling the biological hierarchy of the transcription, translation, and production of small molecules. Proteomics is initially concerned with determining the structure, expression, localization, biochemical activity, interactions, and cellular roles of as many proteins as possible. There has been great progress owing to novel instrumentation, experimental strategies, and bioinformatics methods. The area of protein-protein interactions has been especially fruitful. First pass interaction maps of some model organisms exist, and the proteins in many important organelles are about to be determined. Researchers are also beginning to integrate large-scale data sets from various "omics" disciplines in targeted investigations of specific biomedical areas and in pursuit of a general framework for systems biology.
Small GTPase proteins such as Ras are key regulators of cellular proliferation and are activated by guanine nucleotide exchange/releasing factors (GEFs/GRFs). Three classes of Ras GRFs have been identified to date, represented by Sos1/2, Ras-GRF1/2 and Ras-GRP. Here, we describe a novel candidate Ras activator, cyclic nucleotide rasGEF (CNrasGEF), which contains CDC25, Ras exchange motif (REM), Ras-association (RA), PDZ and cNMP (cAMP/cGMP) binding (cNMP-BD) domains, two PY motifs and a carboxy-terminal SxV sequence. CNrasGEF can activate Ras in vitro, and it binds cAMP directly via its cNMP-BD. In cells, CNrasGEF activates Ras in response to elevation of intracellular cAMP or cGMP, or treatment with their analogues 8-Br-cAMP or 8-Br-cGMP, independently of protein kinases A and G (PKA and PKG). This activation is prevented in CNrasGEF lacking its CDC25 domain or cNMP-BD. CNrasGEF can also activate the small GTPase Rap1 in cells, but this activation is constitutive and independent of cAMP. CNrasGEF is expressed mainly in the brain and is localized at the plasma membrane, a localization dependent on the presence of intact PDZ domain but not the SxV sequence. These results suggest that CNrasGEF may directly connect cAMP-generating pathways or cGMP-generating pathways to Ras.
SummaryEnterohaemorrhagic and enteropathogenic Escherichia coli (EHEC and EPEC respectively) are diarrhoeal pathogens that cause the formation of attaching and effacing (A/E) lesions on infected host cells. These pathogens encode a type III secretion system (T3SS) used to inject effector proteins directly into host cells, an essential requirement for virulence. In this study, we identified a function for the type III secreted effector EspZ. Infection with EPEC DespZ caused increased cytotoxicity in HeLa and MDCK cells compared with wild-type EPEC, and expressing espZ in cells abrogated this effect. Using yeast two-hybrid, proteomics, immunofluorescence and co-immunoprecipitation, it was demonstrated that EspZ interacts with the host protein CD98, which contributes to protection against EPEC-mediated cytotoxicity. EspZ enhanced phosphorylation of focal adhesion kinase (FAK) and AKT during infection with EPEC, but CD98 only appeared to facilitate FAK phosphorylation. This study provides evidence that EspZ and CD98 promote host cell survival mechanisms involving FAK during A/E pathogen infection.
Ras and Rac are membrane-associated GTPases that function as molecular switches activating intracellular mitogen-activated protein kinase (MAPK) cascades and other effector pathways in response to extracellular signals [1]. Activation of Ras and Rac into their GTP-bound conformations is directly controlled by specific guanine-nucleotide exchange factors (GEFs), which catalyze GDP release. Several Ras-specific GEFs that are related to the budding yeast protein Cdc25p have been described, whereas GEFs for Rac-related GTPases contain a region that is homologous to the oncoprotein DbI [2-3]. The Ras-GRF1 and Ras-GRF2 proteins, which couple Ras activation to serpentine receptors and calcium signals, contain both Cdc25 and DbI homology (DH) regions [3-4]. Here, we demonstrate that Ras-GRF2 is a bifunctional signaling protein that is able to bind and activate Ras and Rac, and thereby coordinate the activation of the extracellular-signal-regulated kinase (ERK) and stress-activated protein kinase (SAPK) pathways.
Gram-negative bacterial pathogens have developed specialized secretion systems to transfer bacterial proteins directly into host cells. These bacterial effectors are central to virulence and reprogram host cell processes to favor bacterial survival, colonization, and proliferation. Knowing the complete set of effectors encoded by a particular pathogen is the key to understanding bacterial disease. In addition, the identification of the molecular assemblies that these effectors engage once inside the host cell is critical to determining the mechanism of action of each effector. In this work we used stable isotope labeling of amino acids in cell culture (SILAC), a powerful quantitative proteomics technique, to identify the proteins secreted by the Salmonella pathogenicity island-2 type three secretion system (SPI-2 T3SS) and to characterize the host interaction partners of SPI-2 effectors. We confirmed many of the known SPI-2 effectors and were able to identify several novel substrate candidates of this secretion system. We verified previously published host protein-effector binding pairs and obtained 11 novel interactions, three of which were investigated further and confirmed by reciprocal co-immunoprecipitation. The host cell interaction partners identified here suggest that Salmonella SPI-2 effectors target, in a concerted fashion, cellular processes such as cell attachment and cell cycle control that are underappreciated in the context of infection. The technology outlined in this study is specific and sensitive and serves as a robust tool for the identification of effectors and their host targets that is readily amenable to the study of other bacterial pathogens.Bacterial pathogens have evolved specialized secretion systems to transfer bacterial virulence proteins, also called effectors, from the bacterium to the host cell cytoplasm. The type three secretion system (T3SS) 9 is a large macromolecular machine consisting of three transmembrane complexes: an inner membrane ring, an outer membrane ring, and a translocon pore that forms within the host cell membrane. Effectors are transferred from bacteria to the host cell through a needleshaped structure that connects the outer membrane ring and the translocon (1). Effectors translocated by the T3SS are central to pathogenesis, as mutations that prevent proper assembly of the secretion machinery result in significant virulence defects and often completely hinder bacterial colonization of the host. Consequently, technology to identify and characterize effectors is the key to our understanding of bacterial disease.Salmonella enterica serovar typhimurium (S. typhimurium) is an intracellular pathogen that causes gastroenteritis in humans and a systemic infection resembling typhoid fever in mice (2). S. typhimurium virulence depends on two T3SSs that are encoded on Salmonella pathogenicity islands 1 and 2 (SPI-1 and -2) (2, 3). The SPI-1 T3SS is key during the early stages of infection and effectors translocated by this secretion system mediate entry of S. typhimurium...
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