DNA lattice growth with single, double, and triple double-crossover boundaries by stepwise self-assembly

• Published in: Nanotechnology Vol. 34; no. 24; pp. 245603 - 245614
• Main Authors: Raza, Muhammad Tayyab, Tandon, Anshula, Park, Suyoun, Lee, Sungjin, Nguyen, Thi Bich Ngoc, Vu, Thi Hong Nhung, Park, Sung Ha
• Format: Journal Article
• Language: English
• Published: England IOP Publishing 11.06.2023
• Subjects: atomic force microscopy; boundary; DNA; DNA - chemistry; lattice growth; Microscopy, Atomic Force; Nanostructures - chemistry; Nanotechnology - methods; Nucleic Acid Conformation; stepwise annealing; boundary; lattice growth; stepwise annealing; atomic force microscopy; DNA
• ISSN: 0957-4484; 1361-6528
• DOI: 10.1088/1361-6528/acc1ed

Construction of various nanostructures with nanometre-scale precision through various DNA building blocks depends upon self-assembly, base-pair complementarity and sequence programmability. During annealing, unit tiles are formed by the complementarity of base pairs in each strand. Enhancement of growth of target lattices is expected if seed lattices (i.e. boundaries for growth of target lattices) are initially present in a test tube during annealing. Although most processes for annealing DNA nanostructures adopt a one-step high temperature method, multi-step annealing provides certain advantages such as reusability of unit tiles and tuneability of lattice formation. We can construct target lattices effectively (through multi-step annealing) and efficiently (via boundaries) by multi-step annealing and combining boundaries. Here, we construct efficient boundaries made of single, double, and triple double-crossover DNA tiles for growth of DNA lattices. Two unit double-crossover DNA tile-based lattices and copy-logic implemented algorithmic lattices were introduced to test the growth of target lattices on boundaries. We used multi-step annealing to tune the formation of DNA crystals during fabrication of DNA crystals comprised of boundaries and target lattices. The formation of target DNA lattices was visualized using atomic force microscopy (AFM). The borders between boundaries and lattices in a single crystal were clearly differentiable from AFM images. Our method provides way to construct various types of lattices in a single crystal, which might generate various patterns and enhance the information capacity in a given crystal.