Specific and Direct Amplified Detection of MicroRNA with MicroRNA:Argonaute‐2 Cleavage (miRACle) Beacons

MicroRNA detection is a valuable method for determining cell identity. Molecular beacons are elegant sensors that can transform intracellular microRNA concentration into a fluorescence intensity. While target binding enhances beacon fluorescence, the degree of enhancement is insufficient for demanding applications. The addition of specialty nucleases can enable target recycling and signal amplification, but this process complicates the assay. We have developed and characterized a class of beacons that are susceptible to the endogenous nuclease Argonaute‐2 (Ago2). After purification of the complex by co‐immunoprecipitation, microRNA:Ago2 cleavage (miRACle) beacons undergo site‐ and sequence‐specific cleavage, and show a 13‐fold fluorescence enhancement over traditional beacons. The system can be adapted to any microRNA sequence, and can cleave nuclease‐resistant, non‐RNA bases, potentially allowing miRACle beacons to be designed for cells without interference from non‐specific nucleases.     

Logic‐Gate‐Actuated DNA‐Controlled Receptor Assembly for the Programmable Modulation of Cellular Signal Transduction

Programming cells to sense multiple inputs and activate cellular signal transduction cascades is of great interest. Although this goal has been achieved through the engineering of genetic circuits using synthetic biology tools, a nongenetic and generic approach remains highly demanded. Herein, we present an aptamer‐controlled logic receptor assembly for modulating cellular signal transduction. Aptamers were engineered as “robotic arms” to capture target receptors (c‐Met and CD71) and a DNA logic assembly functioned as a computer processor to handle multiple inputs. As a result, the DNA assembly brings c‐Met and CD71 into close proximity, thus interfering with the ligand–receptor interactions of c‐Met and inhibiting its functions. Using this principle, a set of logic gates was created that respond to DNA strands or light irradiation, modulating the c‐Met/HGF signal pathways. This simple modular design provides a robust chemical tool for modulating cellular signal transduction.     

Molecular Engineering of DNA: Molecular Beacons

Molecular beacons (MBs) are specifically designed DNA hairpin structures that are widely used as fluorescent probes. Applications of MBs range from genetic screening, biosensor development, biochip construction, and the detection of single‐nucleotide polymorphisms to mRNA monitoring in living cells. The inherent signal‐transduction mechanism of MBs enables the analysis of target oligonucleotides without the separation of unbound probes. The MB stem–loop structure holds the fluorescence‐donor and fluorescence‐acceptor moieties in close proximity to one another, which results in resonant energy transfer. A spontaneous conformation change occurs upon hybridization to separate the two moieties and restore the fluorescence of the donor. Recent research has focused on the improvement of probe composition, intracellular gene quantitation, protein–DNA interaction studies, and protein recognition.     

DNA‐Nanotechnologie

For the past two decades the extraordinary molecular recognition properties of DNA molecules have been used for the creation of artificial molecular structures. Following the initial production of simple molecular objects and lattices, with the recent invention of the DNA origami technique the complexity of these structures has considerably increased. Now the construction of almost arbitrary molecular nanostructures from DNA in two and even three dimensions is feasible – and first concrete applications in biomedicine and nanotechnology are in reach. In addition to static molecular structures, also dynamical systems such as molecular machines, molecular motors, and molecular computers can be realized. The combination of these functions within integrated systems currently leads to the development of first molecular “robots” and assembly lines for nanotechnology.     

Fuel‐Responsive Allosteric DNA‐Based Aptamers for the Transient Release of ATP and Cocaine

We show herein that allostery offers a key strategy for the design of out‐of‐equilibrium systems by engineering allosteric DNA‐based nanodevices for the transient loading and release of small organic molecules. To demonstrate the generality of our approach, we used two model DNA‐based aptamers that bind ATP and cocaine through a target‐induced conformational change. We re‐engineered these aptamers so that their affinity towards their specific target is controlled by a DNA sequence acting as an allosteric inhibitor. The use of an enzyme that specifically cleaves the inhibitor only when it is bound to the aptamer generates a transient allosteric control that leads to the release of ATP or cocaine from the aptamers. Our approach confirms that the programmability and predictability of nucleic acids make synthetic DNA/RNA the perfect candidate material to re‐engineer synthetic receptors that can undergo chemical fuel‐triggered release of small‐molecule cargoes and to rationally design non‐equilibrium systems.     

DNA‐Forensik

Forensics deals with the scientific methods to gather information at a crime scene for solving criminal actions. DNA forensics uses genetic material for these purposes. DNA fingerprinting is established as an important method for police detective work since the end of the 1980s. Currently, DNA forensics faces completely new possibilities through the application of more efficient high‐throughput sequencing methods, summarized as Next Generation Sequencing (NGS). Using NGS it could be possible to predict numerous externally visible characteristics including the complete facial shape of an unknown perpetrator. This article aims at presenting practices of forensic DNA analyses used to date and extending the picture for future possibilities and challenges.