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.     

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.     

DNA‐Based Nanopore Sensing

Nanopore sensing is an attractive, label‐free approach that can measure single molecules. Although initially proposed for rapid and low‐cost DNA sequencing, nanopore sensors have been successfully employed in the detection of a wide variety of substrates. Early successes were mostly achieved based on two main strategies by 1) creating sensing elements inside the nanopore through protein mutation and chemical modification or 2) using molecular adapters to enhance analyte recognition. Over the past five years, DNA molecules started to be used as probes for sensing rather than substrates for sequencing. In this Minireview, we highlight the recent research efforts of nanopore sensing based on DNA‐mediated characteristic current events. As nanopore sensing is becoming increasingly important in biochemical and biophysical studies, DNA‐based sensing may find wider applications in investigating DNA‐involving biological processes.     

DNA‐Cleavage by Fullerene‐Based Synzymes

Efficient cleaving of DNA oligonucleotides by a water‐soluble fullerene main‐chain polymer is demonstrated following a facile routine of monitoring the reaction by UV‐vis spectroscopy and separating the cleaved fractions by membrane filtration. A small quantity of the fullerene derivative could cleave a large excess of the oligonucleotide under ambient light conditions, leading to cleaved DNA in quantitative yields.