Bioengineering of Genes and DNA
Since Watson and Crick published their initial studies detailing the double helix structure of DNA in the early 1960s, what we know about genetics and the nucleic acids underlying them has grown enormously. Consequently, what bioengineering can do with DNA and genes continually expands.
One fascinating bioengineering field that emerged in the past decade was DNA origami, which uses the well-established binding across DNA elements to create three-dimensional structures out of linear DNA sequences. Recent work has utilized this feature of DNA construction to make machines, rather than just parts, out of DNA.
Yonggang Ke, Ph.D., of Georgia Tech/Emory’s Department of Biomedical Engineering, constructed machines made of DNA that consist of arrays of units that can “switch” between “settings” by changing shape. A change in shape of one unit of an array can cause the other units in the array to shift; these changes are stimulated by inserting a previously deleted strand of DNA into the array. Although it has been known for some time that DNA could be used to store and transmit information, Dr. Ke’s research team proved for the first time that these arrays could be shaped physically into machines in the shapes of rectangles and tubes.
While we learn more about how to make DNA-based devices, we are also creating new technologies to manipulate DNA more rapidly. Scientists at Rutgers and Harvard developed a process whereby thousands of genes could be cloned at one time to create enormous libraries of proteins. To achieve this goal, the authors used a technology called LASSO (long-adapter single-strand oligonucleotide) probes, which they have already used to clone a library using a human microbiome sample.
Instead of the traditional process of cloning one gene at a time, the team led by Professor Biju Parekkadan, Ph.D. at Rutgers, invented a technology to clone hundred of genes simultaneously. These cloned DNA segments are much longer than the length of DNA cloned with standard techniques, allowing us to test the functional significance of these much longer DNA segments. The technology could impact a number of scientific fields because we will finally learn how long stretches of protein function — some parts may degrade other proteins, while other parts will interact and modify other proteins (e.g., phosphorylation, a key process in epigenetics). These new discoveries can be key for discovering new ways to engineer proteins and to manufacture new drugs that mimic the function of nature’s DNA products.
Using Sweat as a Biosensor
While the field learns more about the molecular-level control of DNA, we are also taking advantage of new micro- and nanoscale manufacturing processes to capture diagnostic information from easily accessible body fluids. Many clinical diagnostics use chemical measurements from blood to diagnose a disease or to take corrective action. This is not an ideal procedure because it requires either the collection of blood at a laboratory or the repeated collection of small blood volumes through a pinprick. Either one hurts.
Bioengineers at the University of Texas at Dallas developed a wearable diagnostic device to detect cortisol, glucose, and IL-6 in body sweat, eliminating any painful needle sticks. Its transmissions vary, but if optimized, the device could replace the painful and inconvenient practice of sticking one’s finger to obtain a drop of blood for glucose testing, which many patients with diabetes must do several times per day. Although insulin pumps have been available for some time, these are invasive devices that must be worn at all times.