Culture of Isolated Floor Plate Tissue and Production of Conditioned Medium to Assess Functional Properties of Floor Plate-released Signals

Abstract

During development, progenitors and post-mitotic neurons receive signals from adjacent territories that regulate their fate. The floor-plate is a group of glial cells lining the ependymal canal at ventral position. The floor-plate expresses key morphogens contributing to the patterning of cell lineages in the spinal cord. At later developmental stages, the floor-plate regulates the navigation of axons in the spinal cord, acting as a barrier to prevent the crossing of ipsilateral axons and controlling midline crossing by commissural axons1. These functions are achieved through the secretion of various guidance cues. Some of these cues act as attractants and repellents for the growing axons while others regulate guidance receptors and downstream signaling to modulate the sensitivity of the axons to the local guidance cues2,3. Here we describe a method that allows investigating the properties of floor-plate derived signals in a variety of developmental contexts, based on the production of Floor-Plate conditioned medium (FPcm)4-6. We then exemplify the use of this FPcm in the context of axon guidance. First, the spinal cord is isolated from mouse embryo at E12.5 and the floor-plate is dissected out and cultivated in a plasma-thrombin matrix (Figure 1). Second two days later, commissural tissue are dissected out from E12.5 embryos, triturated and exposed to the FPcm. Third, the tissue are processed for Western blot analysis of commissural markers.