Identification of an Aurora-A/PinsLINKER/Dlg Spindle Orientation Pathway using Induced Cell Polarity in S2 Cells

Asymmetric cell division is intensely studied because it can generate cellular diversity as well as maintain stem cell populations. Asymmetric cell division requires mitotic spindle alignment with intrinsic or extrinsic polarity cues, but mechanistic detail of this process is lacking. Here, we develop a method to construct cortical polarity in a normally unpolarized cell line and use this method to characterize Partner of Inscuteable ( Pins; LGN/AGS3 in mammals) -dependent spindle orientation. We identify a previously unrecognized evolutionarily conserved Pins domain ( Pins LINKER) that requires Aurora-A phosphorylation to recruit Discs large (Dlg; PSD-95/hDlg in mammals) and promote partial spindle orientation. The well-characterized Pins TPR domain has no function alone, but placing the Pins TPR in cis to the Pins LINKER gives dynein-dependent precise spindle orientation. This "induced cortical polarity'' assay is suitable for rapid identification of the proteins, domains, and amino acids regulating spindle orientation or cell polarity.