A DNA-binding protein capture technology that purifies proteins by directly isolating the target DNA

DNA-protein interactions are critical to almost all cellular functions, and identification of the proteins that bind to an DNA site of interest (gene-centered approach) is an important investigation area. However, gene-centered methods are mainly based on DNA hybridization to isolate target proteins, which is complex and inefficient. Here, we built a gene-centered approach involving direct isolation of target DNA, termed protein capture based on biolistic transformation (PCaB). The target DNA was labeled with biotin and cyanine 3 (Cy3) at its 5 & PRIME; and 3 & PRIME; DNA ends, respectively, and introduced into the host plants through biolistic transformation. The DNA and its binding proteins were crosslinked using formaldehyde. The labeled DNAs were obtained using gel excision and biotin-Streptavidin affinity according to the indication of Cy3 fluorescence, which make harvest of target DNA with a low background. The DNA-binding proteins were identified using mass spectrometry analysis. The PCaB method allowed us to identify and confirm 16 putative upstream regulators of the BpERF3 gene from Betula platyphylla. Theoretically, PCaB could be adapted to all plant species that can be transformed using biolistic bombardment, and captures DNA-binding proteins quickly with a low background. Therefore, PCaB will provide a powerful tool to discover DNA-protein interactions.