Organisms develop from a single fertilized egg by increasing the number of cells through cell division, making those cells different from each other and, most importantly, organizing them in space to give rise to tissues and organs. This organization requires the emergence of systems of spatial coordinates that guide the arrangement of the different cells. A well accepted view of the process contends that there are gradients of special proteins, called morphogens, that can instruct cells what to do in a concentration dependent manner. This means that in a developing group of cells, there is always some pattern of instructions that cells read and that acts as a template for the process. An alternative view is that there is no such template and cells self organize from an initial situation in which all cells are equivalent. Understanding this second possibility has been difficult for lack of an adequate experimental system. Recently we have used mouse Embryonic Stem cells to create a system that recapitulates the events that take place in the early mouse embryo. This system is robust and reproducible and, together with classical genetic analysis, provides a versatile experimental tool to study processes of pattern formation. Here we propose to use this system to explore the mechanisms that pattern the early mouse embryo. Specifically we focus on a protein called Nodal that genetic analysis has shown to be crucial for the early patterning of the mouse embryo. One of the challenges of modern biology is to integrate large amounts of data, particularly from gene expression, into coherent frameworks that account for specific processes e.g the development of an organ like the heart, or a tissue, like the skin. In this process the acquisition of quantitative data about the system and its integration into predictive models is a most important part of the research. In this project we propose to do exactly this by focusing on Nodal and following preliminary results that suggest that it acts as the key element in the process of pattern formation in the aggregates as it does in the embryo, though we do not understand the mechanism of the process that mediates the patterning. In the proposed experiments we shall engineer versions of Nodal and associated proteins that will allow us to follow the patterning process live, extract quantitative data about it and combine it with classical genetic analysis in a useful and fruitful manner. The experimental system will be our patterned aggregates that will allow us to bypass the embryo and explore the role that mechanical forces play in the pattern forming process and how it interferes with the better understood biochemical events.