, 2004). CaMKII and CaN are necessary for attraction and repulsion respectively. Inhibiting CaMKII can block attraction, whereas inhibiting CaN can block repulsion and even convert repulsion to attraction if there are high levels of calcium influx (Wen et al., 2004). Therefore, the ratio of CaMKII to CaN appears to be crucial for determining attraction versus repulsion in guidance responses, CDK inhibitor rather than the absolute activity of each of these molecules. CaMKII and CaN can also regulate activity of one another at different calcium levels through CaN inhibition of the protein inhibitor 1 (I1), an inhibitor of protein phosphatase 1 (PP1), which in turn is an inhibitor of CaMKII (Wen et al.,

2004; Figure 1A). The regulation

of growth cone turning becomes even more complex when one considers other important factors such as the baseline levels of calcium and the activity of cAMP and cGMP. Decreasing the baseline calcium level in the growth cone Selleck AZD2281 converts attraction to repulsion, implying an interaction between the baseline calcium level and the amount of calcium influx in determining the sign of the response (Zheng, 2000). Furthermore, increasing cAMP on one side of the growth cone by presenting an extracellular gradient of cAMP promotes attraction (Lohof et al., 1992 and Murray et al., 2009), whereas lowering the ratio of cAMP to cGMP activity in the presence of a guidance cue gradient can switch turning from attraction to repulsion (Ming et al., 1997, Song et al., 1997, Song et al., 1998 and Nishiyama et al.,

2003). cAMP activates protein kinase A (PKA), which is also known to activate I1 (normally inhibited by CaN), and thus helps to promote attraction by reducing inhibition of CaMKII (Han et al., 2007; Figure 1A). Interpretation of this complex signaling process for guidance must allow for comparison between opposite Phosphatidylinositol diacylglycerol-lyase sides of the growth cone, so that an asymmetric response is possible. Here, we quantitatively test the hypothesis that turning occurs toward the side of the growth cone with the higher CaMKII:CaN ratio, by constructing a mathematical model of the signaling events discussed above. The model is inspired by previous work modeling the analogous switch between long-term potentiation (LTP) and long-term depression (LTD) based on the relative levels of CaMKII and CaN (Lisman, 1989 and Graupner and Brunel, 2007). However, crucially, we consider distinct events occurring on the up-gradient and down-gradient sides of the growth cone, which allows the CaMKII:CaN ratio to be different between the two sides. We first show that this model quantitatively explains the known phenomenology for how calcium and cAMP levels affect the sign of growth cone turning. We then derive predictions from the model for the sign of the response in conditions previously untested experimentally.