Passivating blunt-ended helices to control monodispersity and multi-subunit assembly of DNA origami structures

Abstract: DNA origami facilitates the synthesis of bespoke nanoscale structures suitable for a wide range of applications. Effective design requires prevention of uncontrolled aggregation, while still permitting directed assembly of multi-subunit superstructures. Uncontrolled aggregation can be caused by base-stacking interactions between arrays of blunt-ended helices on different structures, which are routinely passivated by incorporating disordered regions as either scaffold loops or poly-nucleotide brushes (usually p… Show more

“…DNA origami "brick" 1 was designed as a 48 helix bundle in the shape of a rectangular prism, measuring 46×24×16 nm by TEM class averaging (Figure S4). [25] Conferring pH-responsiveness to our subunits, 48 singlestranded poly(A) single strands protrude from each helix terminus on either end of the prism (A x -1, where A = poly(A) and x = number of nucleobases per single strand overhang, Figure 1A). At pH < 4, poly(A) DNA strands form self-complementary homoduplexes as a result of hydrogen bonding between protonated adenine residues and the phosphate DNA backbone.…”

Light‐Activated Assembly of DNA Origami into Dissipative Fibrils

“…DNA origami "brick" 1 was designed as a 48 helix bundle in the shape of a rectangular prism, measuring 46×24×16 nm by TEM class averaging (Figure S4). [25] Conferring pH-responsiveness to our subunits, 48 singlestranded poly(A) single strands protrude from each helix terminus on either end of the prism (A x -1, where A = poly(A) and x = number of nucleobases per single strand overhang, Figure 1A). At pH < 4, poly(A) DNA strands form self-complementary homoduplexes as a result of hydrogen bonding between protonated adenine residues and the phosphate DNA backbone.…”

Light‐Activated Assembly of DNA Origami into Dissipative Fibrils

Light‐Activated Assembly of DNA Origami into Dissipative Fibrils