Spatial sensing in fibroblasts mediated by 3' phosphoinositides.

The directed movement of fibroblasts towards locally released platelet-derived growth factor (PDGF) is a critical event in wound healing. Although recent studies have implicated polarized activation of phosphoinositide (PI) 3-kinase in G protein-mediated chemotaxis, the role of 3' PI lipids in tyrosine kinase-triggered chemotaxis is not well understood. Using evanescent wave microscopy and green fluorescent protein-tagged Akt pleckstrin homology domain (GFP-AktPH) as a molecular sensor, we show that application of a shallow PDGF gradient triggers a markedly steeper gradient in 3' PI lipids in the adhesion zone of fibroblasts. Polar GFP-AktPH gradients, as well as a new type of radial gradient, were measured from front to rear and from the periphery to the center of the adhesion zone, respectively. A strong spatial correlation between polarized 3' PI production and rapid membrane spreading implicates 3' PI lipids as a direct mediator of polarized migration. Analysis of the temporal changes of 3' PI gradients in the adhesion zone revealed a fast diffusion coefficient (0.5 microm(2)/s) and short lifetime of 3' PIs of <1 min. Together, this study suggests that the tyrosine kinase-coupled directional movement of fibroblasts and their radial membrane activity are controlled by local generation and rapid degradation of 3' PI second messengers.

Mathematical modeling of epidermal growth factor receptor signaling through the phospholipase C pathway: mechanistic insights and predictions for molecular interventions.

Combining engineering analyses and mathematical modeling with intervention and detection methodologies at the molecular level will allow manipulation of intracellular signal transduction pathways, and therefore rational control of functional processes central to medicine and biotechnology. We have formulated a simple mathematical model of a key signaling pathway required for regulated migration of fibroblasts and other cell types: activation of the intracellular enzyme phospholipase C (PLC) mediated by epidermal growth factor receptor (EGFR) and a multitude of other transmembrane receptors. One of the interesting features of this pathway is that the substrate of PLC, the lipid phosphatidylinositol (4,5)-bisphosphate (PIP(2)), is turned over quite rapidly and must be constantly resupplied to the plasma membrane by a known transfer mechanism. The model, which accounts for regulation of PIP(2) concentration, is sufficiently detailed to explain unique quantitative features of recent experimental data. We find that competitive pathways that deplete PIP(2) from the membrane, as well as receptor-mediated enhancement of PIP(2) supply, must be significant for agreement between model and experiment. Importantly, the mechanistic nature of the model also allowed us to predict the efficacy of various molecular intervention strategies, including overexpression of wild-type and variant proteins in the pathway as well as treatment with specific drug inhibitors. For many parameter conditions the intuitive strategy of targeting the enzyme itself is actually predicted to be relatively inefficient, with a novel and potentially useful alternative being disruption of the reactant supply mechanism.

Internalized epidermal growth factor receptors participate in the activation of p21(ras) in fibroblasts.

Regulated activation of the highly conserved Ras GTPase is a central event in the stimulation of cell proliferation, motility, and differentiation elicited by receptor tyrosine kinases, such as the epidermal growth factor receptor (EGFR). In fibroblasts, this involves formation and membrane localization of Shc.Grb2.Sos complexes, which increases the rate of Ras guanine nucleotide exchange. In order to control Ras-mediated cell responses, this activity is regulated by receptor down-regulation and a feedback loop involving the dual specificity kinase mitogen-activated protein kinase/extracellular signal-regulated kinase kinase (MEK). We investigated the role of EGFR endocytosis in the regulation of Ras activation. Of fundamental interest is whether activated receptors in endosomes can participate in the stimulation of Ras guanine nucleotide exchange, because the constitutive membrane localization of Ras may affect its compartmentalization. By exploiting the differences in postendocytic signaling of two EGFR ligands, epidermal growth factor and transforming growth factor-alpha, we found that activated EGFR located at the cell surface and in internal compartments contribute equally to the membrane recruitment and tyrosine phosphorylation of Shc in NR6 fibroblasts expressing wild-type EGFR. Importantly, both the rate of Ras-specific guanine nucleotide exchange and the level of Ras-GTP were depressed to near basal values on the time scale of receptor trafficking. Using the selective MEK inhibitor PD098059, we were able to block the feedback desensitization pathway and maintain activation of Ras. Under these conditions, the generation of Ras-GTP was not significantly affected by the subcellular location of activated EGFR. In conjunction with our previous analysis of the phospholipase C pathway in the same cell line, this suggests a selective continuation of specific signaling activities and cessation of others upon receptor endocytosis.

Effect of epidermal growth factor receptor internalization on regulation of the phospholipase C-gamma1 signaling pathway.

The epidermal growth factor receptor (EGFR) ligands, epidermal growth factor (EGF), and transforming growth factor-alpha (TGFalpha) elicit differential postendocytic processing of ligand and receptor molecules, which impacts long-term cell signaling outcomes. These differences arise from the higher affinity of the EGF-EGFR interaction versus that of TGFalpha-EGFR in the acidic conditions of sorting endosomes. To determine whether EGFR occupancy in endosomes might also affect short-term signaling events, we examined activation of the phospholipase C-gamma1 (PLC-gamma1) pathway, an event shown to be essential for growth factor-induced cell motility. We found that EGF continues to stimulate maximal tyrosine phosphorylation of EGFR following internalization, while, as expected, TGFalpha stimulates markedly less. The resulting higher level of receptor activation by EGF, however, did not yield higher levels of phosphatidylinositol (4,5)-bisphosphate (PIP2) hydrolysis over those stimulated by TGFalpha. By altering the ratio of activated receptors between the cell surface and the internalized compartment, we found that only cell surface receptors effectively participate in PLC function. In contrast to PIP2 hydrolysis, PLC-gamma1 tyrosine phosphorylation correlated linearly with the total level of Tyr(P)-EGFR stimulated by either ligand, indicating that the functional deficiency of internal EGFR cannot be attributed to an inability to interact with and phosphorylate signaling proteins. We conclude that EGFR signaling through the PLC pathway is spatially restricted at a point between PLC-gamma1 phosphorylation and PIP2 hydrolysis, perhaps because of limited access of EGFR-bound PLC-gamma1 to its substrate in endocytic trafficking organelles.

Scratching the (cell) surface: cytokine engineering for improved ligand/receptor trafficking dynamics.

Cytokines can be engineered for greater potency in stimulating cellular functions. An obvious test criterion for an improved cytokine is receptor-binding affinity, but this does not always correlate with improved biological response. By combining protein-engineering techniques with studies of receptor trafficking and signaling, it might be possible to identify the ligand receptor-binding properties that should be sought.

Analysis of receptor internalization as a mechanism for modulating signal transduction.

The past decade has witnessed a profound explosion of knowledge in the field of signal transduction mediated by receptor tyrosine kinases. Upon binding of cognate extracellular ligands, these receptors interact with various enzymes and other signaling molecules intracellularly. These protein substrates, which are generally freely diffusing residents of the cytoplasm, as well as the predominantly membrane-associated downstream targets that they activate, are now fairly well characterized molecules. Despite this surge in signaling research, the mechanisms that regulate signaling interactions in a dynamic fashion remain poorly understood, particulary in quantitative terms. We have developed a generalized mathematical model describing the relationships among receptor, substrate, and target molecules with the aim of gaining fundamental insights into one suggested control mechanism: endocytic trafficking-the rapid and induced internalization of ligated receptors and subsequent relocation to intracellular trafficking organelles. This model is very well-suited, in particular, for the epidermal growth factor receptor. Our major conclusion is that when downstream signaling does not rely on phosphorylation of the substrate by the receptor, or when the substrate is phosphorylated to the same extent regardless of receptor location, receptor internalization can still affect signaling if the membrane-associated target of the substrate is differentially partitioned between surface and internal membrane environments. Specificity of this target "availability" effect can derive from molecular specificity of the retention mechanisms that drive this partitioning. A second conclusion is then that differences in substrate or receptor phosphorylation stoichiometries, perhaps due to partitioning of other membrane kinases or phosphatases, can provide additional influence on signaling. Whatever the mechanism, the total observed activity-i.e. the rate of activated target molecules produced per unit time- can be correlated with receptor/ligand binding and trafficking data to determine whether internalization abrogates or amplifies signaling.

Physical modulation of intracellular signaling processes by locational regulation.

Recent observations in the field of signal transduction suggest that where a protein is located within a cell can be as important as its activity measured in solution for activation of its downstream pathway. The physical organization of the cell can provide an additional layer of control upon the chemical reaction networks that govern ultimately perceived signals. Using the cytosol and plasma membrane as relevant compartmental distinctions, we analyze the effect of relocation on the rate of association with a membrane-associated target. We quantify this effect as an enhancement factor E in terms of measurable parameters such as the number of available targets, molecular diffusivities, and intrinsic reaction rate constants. We then employ two simple yet relevant example models to illustrate how relocation can affect the dynamics of signal transduction pathways. The temporal profiles and phase behavior of these models are investigated. We also relate experimentally observable aspects of signal transduction such as peak activation and the relative time scales of stimulus and response to quantitative aspects of the relocation mechanisms in our models. In our example schemes, nearly complete relocation of the cytosolic species in the signaling pair is required to generate meaningful activation of the model pathways when the association rate enhancement factor E is as low as 10; when E is 100 or greater, only a small fraction of the protein must be relocated.