Signaling networks

Signaling Networks

This page is a placeholder, or under current development; it is here principally to establish the logical framework of the site. The material on this page is correct, but incomplete.

Just like with metabolism, signalling pathways have multiple cross-connections and intersections. This page focusses on the principles of signalling networks, on their discovery and definition from high-throughput data, on their analysis and on applications that aim to understand dysregulations that underlie disease. An important concept that sets signalling apart from metabolism - at least in part - is the need to consider space: many signalling components are regulated not through changing their expression levels, or their post-translational modification state, but through sequestering or compartmentalizing them. Another importnat aspect is that of concentration: since the number of e.g. binding sites and repressors can be very small (eg. the average lac-repressor concentration in E. coli is 0.7/cell), stochastic effects may play a large role since physical molecules obviously always appear in integral numbers.

Introductory reading

Kim et al. (2011) Reduction of complex signaling networks to a representative kernel. Sci Signal 4:ra35. (pmid: 21632468)

[ PubMed ] [ DOI ] Abstract

Further reading and resources

Principles

Kolch et al. (2005) When kinases meet mathematics: the systems biology of MAPK signalling. FEBS Lett 579:1891-5. (pmid: 15763569)

[ PubMed ] [ DOI ] Abstract

Lipshtat et al. (2009) Specification of spatial relationships in directed graphs of cell signaling networks. Ann N Y Acad Sci 1158:44-56. (pmid: 19348631)

[ PubMed ] [ DOI ] Abstract

Chatterjee & Kumar (2011) Unraveling the design principle for motif organization in signaling networks. PLoS ONE 6:e28606. (pmid: 22164309)

[ PubMed ] [ DOI ] Abstract

Network discovery and analysis

Pe'er (2005) Bayesian network analysis of signaling networks: a primer. Sci STKE 2005:pl4. (pmid: 15855409)

[ PubMed ] [ DOI ] Abstract

Shimoni et al. (2010) Plato's cave algorithm: inferring functional signaling networks from early gene expression shadows. PLoS Comput Biol 6:e1000828. (pmid: 20585619)

[ PubMed ] [ DOI ] Abstract

Improving the ability to reverse engineer biochemical networks is a major goal of systems biology. Lesions in signaling networks lead to alterations in gene expression, which in principle should allow network reconstruction. However, the information about the activity levels of signaling proteins conveyed in overall gene expression is limited by the complexity of gene expression dynamics and of regulatory network topology. Two observations provide the basis for overcoming this limitation: a. genes induced without de-novo protein synthesis (early genes) show a linear accumulation of product in the first hour after the change in the cell's state; b. The signaling components in the network largely function in the linear range of their stimulus-response curves. Therefore, unlike most genes or most time points, expression profiles of early genes at an early time point provide direct biochemical assays that represent the activity levels of upstream signaling components. Such expression data provide the basis for an efficient algorithm (Plato's Cave algorithm; PLACA) to reverse engineer functional signaling networks. Unlike conventional reverse engineering algorithms that use steady state values, PLACA uses stimulated early gene expression measurements associated with systematic perturbations of signaling components, without measuring the signaling components themselves. Besides the reverse engineered network, PLACA also identifies the genes detecting the functional interaction, thereby facilitating validation of the predicted functional network. Using simulated datasets, the algorithm is shown to be robust to experimental noise. Using experimental data obtained from gonadotropes, PLACA reverse engineered the interaction network of six perturbed signaling components. The network recapitulated many known interactions and identified novel functional interactions that were validated by further experiment. PLACA uses the results of experiments that are feasible for any signaling network to predict the functional topology of the network and to identify novel relationships.

Wang & Albert (2011) Elementary signaling modes predict the essentiality of signal transduction network components. BMC Syst Biol 5:44. (pmid: 21426566)

[ PubMed ] [ DOI ] Abstract

BACKGROUND: Understanding how signals propagate through signaling pathways and networks is a central goal in systems biology. Quantitative dynamic models help to achieve this understanding, but are difficult to construct and validate because of the scarcity of known mechanistic details and kinetic parameters. Structural and qualitative analysis is emerging as a feasible and useful alternative for interpreting signal transduction. RESULTS: In this work, we present an integrative computational method for evaluating the essentiality of components in signaling networks. This approach expands an existing signaling network to a richer representation that incorporates the positive or negative nature of interactions and the synergistic behaviors among multiple components. Our method simulates both knockout and constitutive activation of components as node disruptions, and takes into account the possible cascading effects of a node's disruption. We introduce the concept of elementary signaling mode (ESM), as the minimal set of nodes that can perform signal transduction independently. Our method ranks the importance of signaling components by the effects of their perturbation on the ESMs of the network. Validation on several signaling networks describing the immune response of mammals to bacteria, guard cell abscisic acid signaling in plants, and T cell receptor signaling shows that this method can effectively uncover the essentiality of components mediating a signal transduction process and results in strong agreement with the results of Boolean (logical) dynamic models and experimental observations. CONCLUSIONS: This integrative method is an efficient procedure for exploratory analysis of large signaling and regulatory networks where dynamic modeling or experimental tests are impractical. Its results serve as testable predictions, provide insights into signal transduction and regulatory mechanisms and can guide targeted computational or experimental follow-up studies. The source codes for the algorithms developed in this study can be found at http://www.phys.psu.edu/~ralbert/ESM.

Schulthess & Blüthgen (2011) From reaction networks to information flow--using modular response analysis to track information in signaling networks. Meth Enzymol 500:397-409. (pmid: 21943908)

[ PubMed ] [ DOI ] Abstract

Applications

Schramm et al. (2010) Regulation patterns in signaling networks of cancer. BMC Syst Biol 4:162. (pmid: 21110851)

[ PubMed ] [ DOI ] Abstract

Prasasya et al. (2011) Analysis of cancer signaling networks by systems biology to develop therapies. Semin Cancer Biol 21:200-6. (pmid: 21511035)

[ PubMed ] [ DOI ] Abstract

Hughey et al. (2010) Computational modeling of mammalian signaling networks. Wiley Interdiscip Rev Syst Biol Med 2:194-209. (pmid: 20836022)

[ PubMed ] [ DOI ] Abstract

Signaling networks

Contents

Introductory reading

Contents

Further reading and resources

Navigation menu

Personal tools

Namespaces

Variants

Views

More

Search

Sections

Tools