Aurora B kinase plays a critical role in regulating mitotic progression, and its dysregulation has been linked to tumorigenesis. The structure of the kinase domain of human Aurora B and the complementary information of binding thermodynamics of known Aurora inhibitors is lacking. Towards that effort, we sought to identify a human Aurora B construct that would be amenable for large-scale protein production for biophysical and structural studies. Although the designed AurB(69-333) construct expressed at high levels in Escherichia coli, the purified protein was largely unstable and prone to aggregation. We employed thermal-shift assay for high-throughput screening of 192 conditions to identify optimal pH and salt conditions that increased the stability and minimized aggregation of AurB(69-333). Direct ligand binding analyses using temperature-dependent circular dichroism (TdCD) and TR-FRET-based Lanthascreen™ binding assay showed that the purified protein was folded and functional. The affinity rank-order obtained using TdCD and Lanthascreen™ binding assay correlated with enzymatic IC50 values measured using full-length Aurora B protein for all the inhibitors tested except for AZD1152. The direct binding results support the hypothesis that the purified human AurB(69-333) fragment is a good surrogate for its full-length counterpart for biophysical and structural analyses.
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