Abstract
All seven retinal cell types that make up the mature retina are generated from a common, multipotent pool of retinal progenitor cells (RPCs) (Wallace, 2011). One way that RPCs know when sufficient numbers of particular cell-types have been generated is through negative feedback signals, which are emitted by differentiated cells and must reach threshold levels to block additional differentiation of that cell type. A key assay to assess whether negative feedback signals are emitted by differentiated cells is a heterochronic pellet assay in which early stage RPCs are dissociated and labeled with BrdU, then mixed with a 20-fold excess of dissociated differentiated cells. The combined cells are then re-aggregated and cultured as a pellet on a membrane for 7-10 days in vitro. During this time frame, RPCs will differentiate, and the fate of the BrdU+ RPCs can be assessed using cell type-specific markers. Investigators who developed this pellet assay initially demonstrated that neonatal RPCs give rise to rods on an accelerated schedule compared to embryonic RPCs when the two cell types are mixed together (Watanabe and Raff, 1990; Watanabe et al., 1997). We have used this assay to demonstrate that sonic hedgehog (Shh), which we found acts as a negative regulator of retinal ganglion cell (RGC) differentiation, promotes RPC proliferation (Jensen and Wallace, 1997; Ringuette et al., 2014). More recently we modified the heterochronic pellet assay to assess the role of feedback signals for retinal amacrine cells, identifying transforming growth factor β2 (Tgfβ2) as a negative feedback signal, and Pten as a modulator of the Tgfβ2 response (Ma et al., 2007; Tachibana et al., 2016). This assay can be adapted to other lineages and tissues to assess cell-cell interactions between two different cell-types (heterotypic) in either an isochronic or heterochronic manner.