DNA 鈥榗ages鈥 may aid drug delivery
Nanoscale 鈥渃ages鈥 made from strands of DNA can encapsulate small-molecule drugs and release them in response to a specific stimulus, 不良研究所 researchers report in a new study.聽
The research, published online Sept. 1 in Nature Chemistry, marks a step toward the use of biological nanostructures to deliver drugs to diseased cells in patients. The findings could also open up new possibilities for designing DNA-based nanomaterials.
鈥淭his research is important for drug delivery, but also for fundamental structural biology and nanotechnology,鈥 says 不良研究所 Chemistry professor Hanadi Sleiman, who led the research team.
DNA carries the genetic information of all living organisms from one generation to the next. But strands of the material can also be used to build nanometre-scale structures. (A nanometre is one billionth of a metre 鈥 roughly one-100,000th the diameter of a human hair.)
In their experiments, the 不良研究所 researchers first created DNA cubes using short DNA strands, and modified them with lipid-like molecules. The lipids can act like sticky patches that come together and engage in a 鈥渉andshake鈥 inside the DNA cube, creating a core that can hold cargo such as drug molecules.
The 不良研究所 researchers also found that when the sticky patches were placed on one of the outside faces of the DNA cubes, two cubes could attach together. This new mode of assembly has similarities to the way that proteins fold into their functional structures, Sleiman notes.聽 鈥淚t opens up a range of new possibilities for designing DNA-based nanomaterials.鈥
Sleiman鈥檚 lab has previously demonstrated that gold nanoparticles can be loaded and released from DNA nanotubes, providing a preliminary proof of concept that drug delivery might be possible. But the new study marks the first time that small molecules -- which are considerably smaller than the gold nanoparticles -- have been manipulated in such a way using a DNA nanostructure, the researchers report.
DNA nanostructures have several potential advantages over the synthetic materials often used to deliver drugs within the body, says Thomas Edwardson, a 不良研究所 doctoral student and co-author of the new paper. 鈥淒NA structures can be built with great precision, they are biodegradable and their size, shape and properties can be easily tuned鈥.
The DNA cages can be made to release drugs in the presence of a specific nucleic acid sequence. 鈥淢any diseased cells, such as cancer cells, overexpress certain genes,鈥 Edwardson adds. 鈥淚n a future application, one can imagine a DNA cube that carries drug cargo to the diseased cell environment, which will trigger the release of the drug.鈥 The Sleiman group is now conducting cell and animal studies to assess the viability of this method on chronic lymphocytic leukemia (CLL) and prostate cancer, in collaboration with researchers at the Lady Davis Institute for Medical Research at Montreal鈥檚 Jewish General Hospital.
Funding for the Sleiman team鈥檚 research was provided by the Natural Sciences and Engineering Research Council of Canada (NSERC), a CIHR Drug Development Training Program scholarship to Mr. Edwardson, the Canada Foundation for Innovation (CFI), the Centre for Self- Assembled Chemical Structures (CSACS) and the Canadian Institute for Advanced Research (CIFAR).
Image:聽 A DNA cage (at left), with lipid-like molecules (in blue). The lipids come together聽 in a 鈥榟andshake鈥 within the cage (center image) to encapsulate small-molecule drugs (purple). The molecules are released (at right) in response to the presence of a specific nucleic acid.聽Credit: Thomas Edwardson, 不良研究所