Phosphoproteomics in analyzing signaling pathways

A surprisingly fewer than expected number of genes in the human genome suggests that sophistication of its biologic system is, in part, due to complex regulation of protein activities. The activities of most cellular proteins are regulated by post-translational modifications. One of the most important post-translational modifications is reversible protein phosphorylation, which decorates more than 30% of the proteome and regulates signal transduction pathways under normal conditions as well as in disorders such as diabetes, neurodegenerative diseases, autoimmune diseases and several forms of cancers. This review examines the recent developments in mass spectrometry-based methods for phosphoproteome analysis and its applications for the study of signal transduction pathways. The basic principles of non-mass spectrometry-based methods, such as chemical genetics and flow cytometry-based approaches, are also discussed as well as their specific advantages to signaling studies. Finally, signaling pathways are discussed in the light of large-scale protein interaction studies. The proteomic methods addressed in this review are emerging as some of the essential components in systems biology, which seeks to describe signaling networks through integration of diverse types of data and, in the future, to allow computational simulations of complex biologic pathways in health and disease.     

Phosphoproteomics: unraveling the signaling web

In recent years, phosphoproteomic technologies have increased our understanding of cellular signaling networks. Here, we frame recent phosphoproteomics-based advances in the context of the DNA damage response and ErbB receptor family signaling and offer a perspective on how the molecular insights arising from the integration of such proteomic approaches might be used for clinical applications.     

Phosphoproteomics of vasopressin signaling in the kidney

Protein phosphorylation plays a critical role in the signaling pathways regulating water and solute transport in the distal renal tubule (i.e., renal collecting duct). A central mediator in this process is the antidiuretic peptide hormone arginine vasopressin, which regulates a number of transport proteins including water channel aquaporin-2 and urea transporters (UT-A1 and UT-A3). Within the past few years, tandem mass spectrometry-based proteomics has played a pivotal role in revealing global changes in the phosphoproteome in response to vasopressin signaling in the renal collecting duct. This type of large-scale 'shotgun' approach has resulted in an exponential increase in the number of phosphoproteins known to be regulated by vasopressin and has expanded on the established signaling mechanisms and kinase pathways regulating collecting duct physiology. This article will provide a brief background on vasopressin action, will highlight a number of recent quantitative phosphoproteomic studies in both native rat kidney and cultured collecting duct cells, and will conclude with a perspective focused on emerging trends in the field of phosphoproteomics.     

Phosphoproteomics: new insights into cellular signaling

Developments in the field of phosphoproteomics have been fueled by the need simultaneously to monitor many different phosphoproteins within the signaling networks that coordinate responses to changes in the cellular environment. This article presents a brief review of phosphoproteomics with an emphasis on the biological insights that have been derived so far.     

Phosphoproteomics, oncogenic signaling and cancer research

The past 5 years have seen an explosion of phosphoproteomics methods development. In this review, using epidermal growth-factor signaling as a model, we will discuss how phosphoproteomics, along with bioinformatics and computational modeling, have impacted key aspects of oncogenic signaling such as in the temporal fine mapping of phosphorylation events, and the identification of novel tyrosine kinase substrates and phosphorylation sites. We submit that the next decade will see considerable exploitation of phosphoproteomics in cancer research. Such a phenomenon is already happening as exemplified by its use in promoting the understanding of the molecular etiology of cancer and target-directed therapeutics.     

Retroactive signaling in short signaling pathways

In biochemical signaling pathways without explicit feedback connections, the core signal transduction is usually described as a one-way communication, going from upstream to downstream in a feedforward chain or network of covalent modification cycles. In this paper we explore the possibility of a new type of signaling called retroactive signaling, offered by the recently demonstrated property of retroactivity in signaling cascades. The possibility of retroactive signaling is analysed in the simplest case of the stationary states of a bicyclic cascade of signaling cycles. In this case, we work out the conditions for which variables of the upstream cycle are affected by a change of the total amount of protein in the downstream cycle, or by a variation of the phosphatase deactivating the same protein. Particularly, we predict the characteristic ranges of the downstream protein, or of the downstream phosphatase, for which a retroactive effect can be observed on the upstream cycle variables. Next, we extend the possibility of retroactive signaling in short but nonlinear signaling pathways involving a few covalent modification cycles.     

Phosphoproteomics of human platelets: A quest for novel activation pathways

Besides their role in hemostasis, platelets are also highly involved in the pathogenesis and progression of cardiovascular diseases. Since important and initial steps of platelet activation and aggregation are regulated by phosphorylation events, a comprehensive study aimed at the characterization of phosphorylation-driven signaling cascades might lead to the identification of new target proteins for clinical research. However, it becomes increasingly evident that only a comprehensive phosphoproteomic approach may help to characterize functional protein networks and their dynamic alteration during physiological and pathophysiological processes in platelets. In this review, we discuss current methodologies in phosphoproteome research including their potentials as well as limitations, from sample preparation to classical approaches like radiolabeling and state-of-the-art mass spectrometry techniques.     

Phosphoproteomics identifies oncogenic Ras signaling targets and their involvement in lung adenocarcinomas

Background

Ras is frequently mutated in a variety of human cancers, including lung cancer, leading to constitutive activation of MAPK signaling. Despite decades of research focused on the Ras oncogene, Ras-targeted phosphorylation events and signaling pathways have not been described on a proteome-wide scale.

Methodology/Principal Findings

By functional phosphoproteomics, we studied the molecular mechanics of oncogenic Ras signaling using a pathway-based approach. We identified Ras-regulated phosphorylation events (n = 77) using label-free comparative proteomics analysis of immortalized human bronchial epithelial cells with and without the expression of oncogenic Ras. Many were newly identified as potential targets of the Ras signaling pathway. A majority (∼60%) of the Ras-targeted events consisted of a [pSer/Thr]-Pro motif, indicating the involvement of proline-directed kinases. By integrating the phosphorylated signatures into the Pathway Interaction Database, we further inferred Ras-regulated pathways, including MAPK signaling and other novel cascades, in governing diverse functions such as gene expression, apoptosis, cell growth, and RNA processing. Comparisons of Ras-regulated phosphorylation events, pathways, and related kinases in lung cancer-derived cells supported a role of oncogenic Ras signaling in lung adenocarcinoma A549 and H322 cells, but not in large cell carcinoma H1299 cells.

Conclusions/Significance

This study reveals phosphorylation events, signaling networks, and molecular functions that are regulated by oncogenic Ras. The results observed in this study may aid to extend our knowledge on Ras signaling in lung cancer.     

A graphic editor for analyzing signal-transduction pathways

We describe a graphical editor designed specifically to facilitate analysis and visualization of complex signal-transduction pathways. The editor provides automatic layout of complex regulatory graphs and enables users easily to maintain, edit, and exchange publication-quality images of regulatory networks.     

Sphingolipid-mediated apoptotic signaling pathways

Various sphingolipids are being viewed as bioactive molecules and/or second messengers. Among them, ceramide (or N-acylsphingosine) and sphingosine generally behave as pro-apoptotic mediators. Indeed, ceramide mediates the death signal initiated by numerous stress agents which either stimulate its de novo synthesis or activate sphingomyelinases that release ceramide from sphingomyelin. For instance, the early generation of ceramide promoted by TNF is mediated by a neutral sphingomyelinase the activity of which is regulated by the FAN adaptor protein, thereby controlling caspase activation and the cell death programme. In addition, the activity of this neutral sphingomyelinase is negatively modulated by caveolin, a major constituent of some membrane microdomains. The enzyme sphingosine kinase also plays a crucial role in apoptosis signalling by regulating the intracellular levels of two sphingolipids having opposite effects, namely the pro-apoptotic sphingosine and the anti-apoptotic sphingosine 1-phosphate molecule. Ceramide and sphingosine metabolism therefore appears as a pivotal regulatory pathway in the determination of cell fate.     

Initiator caspases in apoptosis signaling pathways

Death receptor- or mitochondrion-dependent apoptosis is initiated by the recruitment and activation of apical caspases in the apoptosis signaling pathways. In death receptor-mediated apoptosis, engagement of death receptors leads to the formation of the death-inducing signaling complex (DISC) containing the death receptors, adaptor proteins, caspase-8 and caspase-10. In mitochondrion-dependent apoptosis, release of cytochrome C into the cytosol results in the formation of apoptosome containing cytochrome C, Apaf-1 and caspase-9. Caspase-8, caspase-10 and caspase-9 are believed to be the initiator caspases at the top of the caspase signaling cascade. Recruitment of caspases to DISC and apoptosome leads to their activation by dimer formation. Recent biochemical and structural analyses of components in the DISC and apoptosome shed new lights on their roles in inducing the onset of apoptosis signaling.     

Pheromone signaling pathways in yeast.

The discovery that the transducing G protein of the Saccharomyces cerevisiae mating pheromone response figures centrally in signal adaptation was the focus of considerable excitement in the past year. Not only does activated G alpha in this system stimulate an adaptive signal but G beta undergoes a desensitizing phosphorylation in response to pheromone signaling.     

Electric field regulated signaling pathways

Physiological electric field (EF) is a potent guidance cue for many physiological development and pathological conditions. The EF induced cellular responses such as migration and proliferation, are considered to be regulated by multiple signaling pathways in a coordinated way. Unlike the signaling transduction regulating the cellular responses toward chemical gradients, the signaling network involved in electric stimulation shows a unique manner, combining the regulation of ion channels, membrane receptors and associated intracellular signaling pathways. This review shall discuss the cellular responses in EF, and summarize the primary signaling network activated during the EF-induced cellular response.