Paranemic cohesion of topologically-closed DNA molecules

Xiaoping Zhang; Hao Yan; Zhiyong Shen; Nadrian C. Seeman

doi:10.1021/ja026973b

Paranemic cohesion of topologically-closed DNA molecules

Xiaoping Zhang, Hao Yan, Zhiyong Shen, Nadrian C. Seeman

Research output: Contribution to journal › Article › peer-review

79 Scopus citations

Abstract

Specific cohesion of DNA molecules is key to the success of work in biotechnology, DNA nanotechnology and DNA-based computation. The most common form of intermolecular cohesion between double helices is by sticky ends, but sticky ends generated by naturally occurring restriction enzymes may often be too short to bind large constructs together. An alternative form of binding is available through the paranemic crossover (PX) motif. Each of the two components of a PX motif can be a DNA dumbbell or other topologically closed species. Alternate half-turns of the dumbbell are paired intramolecularly. The intervening half-turns are paired with those of the opposite component. We demonstrate the efficacy of PX cohesion by showing that it can result in the 1:1 binding of two triangle motifs, each containing nearly 500 nucleotides. The cohesion goes to completion, demonstrating an alternative to binding nucleic acid molecules through sticky ends.

Original language	English (US)
Pages (from-to)	12940-12941
Number of pages	2
Journal	Journal of the American Chemical Society
Volume	124
Issue number	44
DOIs	https://doi.org/10.1021/ja026973b
State	Published - Nov 6 2002
Externally published	Yes

ASJC Scopus subject areas

Catalysis
General Chemistry
Biochemistry
Colloid and Surface Chemistry

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10.1021/ja026973b

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abstract = "Specific cohesion of DNA molecules is key to the success of work in biotechnology, DNA nanotechnology and DNA-based computation. The most common form of intermolecular cohesion between double helices is by sticky ends, but sticky ends generated by naturally occurring restriction enzymes may often be too short to bind large constructs together. An alternative form of binding is available through the paranemic crossover (PX) motif. Each of the two components of a PX motif can be a DNA dumbbell or other topologically closed species. Alternate half-turns of the dumbbell are paired intramolecularly. The intervening half-turns are paired with those of the opposite component. We demonstrate the efficacy of PX cohesion by showing that it can result in the 1:1 binding of two triangle motifs, each containing nearly 500 nucleotides. The cohesion goes to completion, demonstrating an alternative to binding nucleic acid molecules through sticky ends.",

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T1 - Paranemic cohesion of topologically-closed DNA molecules

AU - Zhang, Xiaoping

AU - Yan, Hao

AU - Shen, Zhiyong

AU - Seeman, Nadrian C.

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Y1 - 2002/11/6

N2 - Specific cohesion of DNA molecules is key to the success of work in biotechnology, DNA nanotechnology and DNA-based computation. The most common form of intermolecular cohesion between double helices is by sticky ends, but sticky ends generated by naturally occurring restriction enzymes may often be too short to bind large constructs together. An alternative form of binding is available through the paranemic crossover (PX) motif. Each of the two components of a PX motif can be a DNA dumbbell or other topologically closed species. Alternate half-turns of the dumbbell are paired intramolecularly. The intervening half-turns are paired with those of the opposite component. We demonstrate the efficacy of PX cohesion by showing that it can result in the 1:1 binding of two triangle motifs, each containing nearly 500 nucleotides. The cohesion goes to completion, demonstrating an alternative to binding nucleic acid molecules through sticky ends.

AB - Specific cohesion of DNA molecules is key to the success of work in biotechnology, DNA nanotechnology and DNA-based computation. The most common form of intermolecular cohesion between double helices is by sticky ends, but sticky ends generated by naturally occurring restriction enzymes may often be too short to bind large constructs together. An alternative form of binding is available through the paranemic crossover (PX) motif. Each of the two components of a PX motif can be a DNA dumbbell or other topologically closed species. Alternate half-turns of the dumbbell are paired intramolecularly. The intervening half-turns are paired with those of the opposite component. We demonstrate the efficacy of PX cohesion by showing that it can result in the 1:1 binding of two triangle motifs, each containing nearly 500 nucleotides. The cohesion goes to completion, demonstrating an alternative to binding nucleic acid molecules through sticky ends.

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Paranemic cohesion of topologically-closed DNA molecules

Abstract

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