Three-Dimensional Computational Reconstruction of Tissues with Hollow Spherical Morphologies using Single-Cell Gene Expression Data
Durruthy-Durruthy, R., Gottlieb, A., Heller, S.
Single-cell gene expression analysis has contributed to a better understanding of the transcriptional heterogeneity in a variety of model systems, including those used in research in developmental, cancer, and stem cell biology. Nowadays, technological advances facilitate the generation of large gene expression datasets in high-throughput format. Strategies are needed to pertinently visualize this information in a tissue–structure related context, so as to improve data analysis and aid the drawing of meaningful conclusions. Here we describe an approach that utilizes spatial properties of the tissue source to enable the reconstruction of hollow sphere–shaped tissues and organs from single-cell gene expression data in three-dimensional space. To demonstrate our method, we used cells of the mouse otocyst and the renal vesicle as examples. This protocol presents a straightforward computational expression analysis workflow and is implemented on the MATLAB and R statistical computing and graphics software platforms. Hands-on time for typical experiments can be less than 1 h using a standard desktop PC or Mac.
Durruthy-Durruthy, R., Gottlieb, A., Heller, S. "Three-Dimensional Computational Reconstruction of Tissues with Hollow Spherical Morphologies using Single-Cell Gene Expression Data" Nature Protocols (2015): 459–74