Modeling ciliopathies in patient-derived primary cells

Ciliopathies comprise a group of inherited diseases caused by mutations in genes encoding proteins that localize to cilia or centrosomes. They afflict multiple organs and are one of the most frequent monogenic causes of kidney failure in adults, adolescents and children. Primary cilia play diverse roles in cell signaling, cell cycle regulation, planar cell polarity and mechanosensing. The use of patient-derived cells possessing endogenous disease causing mutations enables the study of these processes and their dysregulation in disease. Here we describe methods to cultivate patient-derived dermal fibroblast and renal epithelial cells isolated from urine. Fibroblasts are highly robust, long-lived, and easy to culture cells in which ciliary assembly can be easily induced. Similarly, the ability to acquire and culture ciliated renal epithelial cells without patient-invasive-intervention holds great potential to further our understanding of ciliopathies. In addition to monolayer cultures, we also detail the formation of three-dimensional renal-epithelial organoids-so-called tubuloids-that demonstrate epithelial-polarization and transepithelial transport activities like those seen in vivo renaltubules. These in vitro models are powerful tools to investigate the underlying disease mechanisms of human ciliopathies that can be employed without the need for heavy-handed genetic or molecular manipulations.