Tug-of-War in a Double-Nanopore System

Abstract

We simulate a tug-of-war (TOW) scenario for a model double-stranded DNA threading through a double nanopore (DNP) system. The DNA, simultaneously captured at both pores is subject to two equal and opposite forces -fL= fR (TOW), where fL and fR are the forces applied to the left and the right pore respectively. Even though the net force on the DNA polymer fLR=fL+ fR=0, the mean first passage time (MFPT) τ depends on the magnitude of the TOW forces | fL | = |fR | = fLR. We qualitatively explain this dependence of τ on fLR from the known results for the single-pore translocation of a triblock copolymer. We demonstrate that the time of flight (TOF) of a monomer with index m ( τLR(m) ) from one pore to the other exhibits quasi-periodic structure commensurate with the distance between the pores dLR. Finally, we study the case fLR=fL+ fR 0, and qualitatively reproduce the experimental result of the dependence of the MFPT on fLR. For a moderate bias, the MFPT for the DNP system for a chain length N follows the same scaling ansatz as that of for the single nanopore, τ = ( AN1+ + ηporeN ) ( fLR)-1, where ηpore is the pore friction, which enables us to estimate τ for a long chain. Our Brownian dynamics simulation studies provide fundamental insights and valuable information about the details of the translocation speed obtained from τLR(m) , and accuracy of the translation of the data obtained in the time-domain to units of genomic distances.