Summary
Double-stranded DNA viruses package their genomes into pre-assembled capsids using virally-encoded ASCE ATPase ring motors. We present the first atomic-resolution crystal structure of a multimeric ring form of a viral dsDNA packaging motor and characterize its atomic-level dynamics via long timescale molecular dynamics simulations. Based on the results, we deduce an overall packaging mechanism that is driven by helical-to-planar transitions of the ring motor. These transitions are coordinated by inter-subunit interactions that regulate catalytic and force-generating events. Stepwise ATP binding to individual subunits increase their affinity for the helical DNA phosphate backbone, resulting in distortion away from the planar ring towards a helical configuration, inducing mechanical strain. Subsequent sequential hydrolysis events alleviate the accumulated mechanical strain, allowing a stepwise return of the motor to the planar conformation, translocating DNA in the process. This type of helical-to-planar mechanism could serve as a general framework for ring ATPases that exhibit burst-dwell dynamics.
Competing Interest Statement
The authors have declared no competing interest.
Footnotes
↵‡ Co-first authorship
Cartoon/schematic figure revised. Author affiliations updated. Discussion section updated to explain proposed mechanism more clearly.