Large-Conductance Transmembrane Porin Made from DNA Origami

Göpfrich, Kerstin; Li, Chen Yu; Ricci, Maria Antonietta; Bhamidimarri, Satya Prathyusha; Yoo, Jejoong; Gyenes, Bertalan; Ohmann, Alexander; Winterhalter, Mathias; Aksimentiev, Aleksei; Keyser, Ulrich F.

doi:10.1021/acsnano.6b03759

Cited by 179 publications

(220 citation statements)

References 48 publications

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“…Therefore, there is unlikely to be significant ion ‘leakage' possible around the edges of the pore. It is interesting to compare this with a recent study of a large conductance DNA ‘porin'59 for which simulations suggest ca. 20% of the ionic current may flow around the outside of the channel.…”

Section: Resultsmentioning

confidence: 83%

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Stability and dynamics of membrane-spanning DNA nanopores

et al. 2017

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Recently developed DNA-based analogues of membrane proteins have advanced synthetic biology. A fundamental question is how hydrophilic nanostructures reside in the hydrophobic environment of the membrane. Here, we use multiscale molecular dynamics (MD) simulations to explore the structure, stability and dynamics of an archetypical DNA nanotube inserted via a ring of membrane anchors into a phospholipid bilayer. Coarse-grained MD reveals that the lipids reorganize locally to interact closely with the membrane-spanning section of the DNA tube. Steered simulations along the bilayer normal establish the metastable nature of the inserted pore, yielding a force profile with barriers for membrane exit due to the membrane anchors. Atomistic, equilibrium simulations at two salt concentrations confirm the close packing of lipid around of the stably inserted DNA pore and its cation selectivity, while revealing localized structural fluctuations. The wide-ranging and detailed insight informs the design of next-generation DNA pores for synthetic biology or biomedicine.

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Section: Resultsmentioning

confidence: 83%

“…This demonstration of modularity of pore function and membrane stability will guide design of next-generation DNA nanopores with tailored gating and ion selectivity properties. Such designs will benefit from our understanding of both simple DNA nanopores, as in the current study, and, for example, of more complex DNA origami `porins'59.…”

Section: Discussionmentioning

confidence: 99%

Stability and dynamics of membrane-spanning DNA nanopores

et al. 2017

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“…The calculations of local densities and ion fluxed were performed on a 50 × 50 × 76 cubic grid using a previously described method. 55,59,114 …”

Section: Methodsmentioning

confidence: 99%

Porphyrin-Assisted Docking of a Thermophage Portal Protein into Lipid Bilayers: Nanopore Engineering and Characterization

Cressiot¹,

Greive

et al. 2017

ACS Nano

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Nanopore-based sensors for nucleic acid sequencing and single-molecule detection typically employ pore-forming membrane proteins with hydrophobic external surfaces, suitable for insertion into a lipid bilayer. In contrast, hydrophilic pore-containing molecules, such as DNA origami, have been shown to require chemical modification to favor insertion into a lipid environment. In this work, we describe a strategy for inserting polar proteins with an inner pore into lipid membranes, focusing here on a circular 12-subunit assembly of the thermophage G20c portal protein. X-ray crystallography, electron microscopy, molecular dynamics, and thermal/chaotrope denaturation experiments all find the G20c portal protein to have a highly stable structure, favorable for nanopore sensing applications. Porphyrin conjugation to a cysteine mutant in the protein facilitates the protein’s insertion into lipid bilayers, allowing us to probe ion transport through the pore. Finally, we probed the portal interior size and shape using a series of cyclodextrins of varying sizes, revealing asymmetric transport that possibly originates from the portal’s DNA-ratchet function.

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“…(d–f) Reproduced from Gopfrich, K.; Li, C.-Y. ; Ricci, M.; Bhamidimarri, S. P.; Yoo, J.; Gyenes, B.; Ohmann, A.; Winterhalter, M.; Aksimentiev, A.; Keyser, U. F. ACS Nano 2016 10 , 8207–8214 (ref 85). Copyright 2016 American Chemical Society.…”

Section: Figurementioning

confidence: 99%