Laser-based temperature control to study the roles of entropy and enthalpy in polymer-nanopore interactions

Single-molecule approaches for probing the free energy of confinement for polymers in a nanopore environment are critical for the development of nanopore biosensors. We developed a laser-based nanopore heating approach to monitor the free energy profiles of such a single-molecule sensor. Using this approach, we measure the free energy profiles of two distinct polymers, polyethylene glycol and water-soluble peptides, as they interact with the nanopore sensor. Polyethylene glycol demonstrates a retention mechanism dominated by entropy with little sign of interaction with the pore, while peptides show an enthalpic mechanism, which can be attributed to physisorption to the nanopore (e.g., hydrogen bonding). To manipulate the energetics, we introduced thiolate-capped gold clusters [Au25(SG)18] into the pore, which increases the charge and leads to additional electrostatic interactions that help dissect the contribution that enthalpy and entropy make in this modified environment. These observations provide a benchmark for optimization of single-molecule nanopore sensors.

Recent advances in integrated solid-state nanopore sensors

The advent of single-molecule probing techniques has revolutionized the biomedical and life science fields and has spurred the development of a new class of labs-on-chip based on powerful biosensors. Nanopores...

Bottom-up fabrication of a multi-component nanopore sensor that unfolds, processes and recognizes single proteins

Transmembrane channels and pores have many biotechnological applications, notably in the single-molecule sequencing of DNA. Small synthetic nanopores have been designed using amphipathic peptides, or by assembling computationally designed transmembrane helices. The fabrication of more complex transmembrane devices has yet to be reported. In this work, we fabricated in two steps a multi-protein transmembrane device that addresses some of the main challenges in nanopore protein sequencing. In the first step, artificial nanopores are created from soluble proteins with toroid shapes. This design principle will allow fabricating a variety of nanopores for single-molecule analysis. In the second step one α-subuinit of the 20S proteasome from Thermoplasma acidophilum is genetically integrated into the artificial nanopore, and a 28-component nanopore-proteasome is co-assembled in E. coli cells. This multi-component molecular machine opens the door to two new approaches in protein sequencing, in which selected substrate proteins are unfolded, fed to into the proteasomal chamber and then identified by the nanopore sensor either as intact or fragmented polypeptides. The ability to integrate molecular devices directly onto a nanopore sensors allows creating next-generation protein sequencing devices, and will shed new lights on the fundamental processes of biological nanomachines.