A DNA origami-based device for investigating DNA bending proteins by transmission electron microscopy

The DNA origami technique offers precise positioning of nanoscale objects with high accuracy. This has facilitated the development of DNA origami-based functional nanomechanical devices that enable the investigation of DNA-protein interactions at the single particle level. Herein, we used the DNA origami technique to fabricate a nanoscale device for studying DNA bending proteins. For a proof of concept, we used TATA-box binding protein (TBP) to evaluate our approach. Upon binding to the TATA box, TBP causes a bend to DNA of similar to 90 degrees. Our device translates this bending into an angular change that is readily observable with a conventional transmission electron microscope (TEM). Furthermore, we investigated the roles of transcription factor II A (TF(II)A) and transcription factor II B (TF(II)B). Our results indicate that TF(II)A introduces additional bending, whereas TF(II)B does not significantly alter the TBP-DNA structure. Our approach can be readily adopted to a wide range of DNA-bending proteins and will aid the development of DNA-origami-based devices tailored for the investigation of DNA-protein interactions.

Automated summary

The DNA origami technique allows precise positioning of nanoscale objects, facilitating the development of functional nanomechanical devices for investigating DNA-protein interactions. In this study, a nanoscale device was fabricated using the DNA origami technique to study DNA bending proteins. The bending of DNA caused by the TATA-box binding protein (TBP) was observed using a transmission electron microscope, and the roles of transcription factor II A (TF(II)A) and transcription factor II B (TF(II)B) were investigated.