Using Pathway Logic to Integrate Signal Transduction and Gene Expression Data Pathway Logic (http://pl.csl.sri.com/) is an approach to the modeling and analysis of molecular and cellular processes based on rewriting logic. Pathway Logic (PL) models reflect the ways that biologists think about problems using informal models. They are curated from the literature, and written and analyzed using Maude, a rewriting-logic-based formalism (http://maude.cs.uiuc.edu). A Pathway Logic knowledge base includes data types representing cellular components such as proteins, small molecules, complexes, compartments/locations protein state, and post-translational modifications. Modifications can be abstract, just specifying being activated, bound, or phosphorylated, or more specific, for example, phosphorylation at a particular site. Collections of entities, treated as `liquid' mixtures, are represented as multisets (unordered collections). Rewrite rules describe the behavior of proteins and other components depending on modification state and biological context. Each rule represents a step in a biological process such as metabolism or intra/inter- cellular signaling. A specific model is assembled by specifying an initial state (called a dish): the cells, their components, and entities such as ligands in the supernatant. The Pathway Logic Assistant (PLA) provides an interactive visual representation of PL models. Using PLA one can display the network of signaling reactions for a specified model; formulate and submit queries to find pathways, for example activating one protein without activating a second protein, or exhibiting a phenotype signature such as apoptosis; compare two pathways; find single or double knockouts---individual or pairs of proteins whose omission prevents reaching a specified state; compute and display the subnet relevant to one or more proteins; and visualize gene expression data in the context of a network (by coloring the coded proteins according to expression level). The poster will illustrate this approach in the context of a model of TLR signaling. In this PL model of TLR signaling, one can show that the Interferon beta gene can not be turned on by activating TLR2. In fact there is no pathway that jointly achieves the goals of activating TLR2 and turning on Ifnbgene. On the surface, this is an artifact of the way the model treats competition of TLR2 and TLR4 for Lps. But it suggests investigation of this competition. Does one of the receptors dominate? What if one is highly over expressed and not the other? Activation of TLR2 does lead to the Il6 gene being turned on.