Engineering and Modeling the Electrophoretic Trapping of a Single Protein Inside a Nanopore

The ability to confine and to study single molecules has enabled important advances in natural and applied sciences. Recently, we have shown that unlabeled proteins can be confined inside the biological nanopore Cytolysin A (ClyA) and conformational changes monitored by ionic current recordings. However, trapping small proteins remains a challenge. Here we describe a system where steric, electrostatic, electrophoretic, and electroosmotic forces are exploited to immobilize a small protein, dihydrofolate reductase (DHFR), inside ClyA. Assisted by electrostatic simulations, we show that the dwell time of DHFR inside ClyA can be increased by orders of magnitude (from milliseconds to seconds) by manipulation of the DHFR charge distribution. Further, we describe a physical model that includes a double energy barrier and the main electrophoretic components for trapping DHFR inside the nanopore. Simultaneous fits to the voltage dependence of the dwell times allowed retrieving direct estimates of the cis and trans translocation probabilities, the mean dwell time, and the force exerted by the electroosmotic flow on the protein (≅9 pN at -50 mV). The observed binding of NADPH to the trapped DHFR molecules suggested that the engineered proteins remained folded and functional inside ClyA. Contact-free confinement of single proteins inside nanopores can be employed for the manipulation and localized delivery of individual proteins and will have further applications in single-molecule analyte sensing and enzymology studies

Single-molecule studies with ClyA nanopores. Designing a new platform for biosensing and single-protein studies

nrpages: 252status: publishe

Single-Molecule Analyte Recognition with ClyA Nanopores Equipped with Internal Protein Adaptors

Nanopores have been used to detect molecules, to sequence DNA, or to investigate chemical reactions at the single-molecule level. Because they approach the absolute limit of sensor miniaturization, nanopores are amenable to parallelization and could be used in single-cell measurements. Here we show that single enzymes can be functionally and reversibly trapped inside the confined space of a ClyA nanopore. Remarkably, the binding of ligands to the internalized proteins is mirrored by specific changes to the nanopore conductance. Conveniently, the manipulation of the charge of the protein allowed increasing of the residence time of the protein inside the nanopore. Nanopores with internalized protein adaptors can be used to study proteins in real time or can be incorporated into inexpensive portable devices for the detection of analytes with high selectivity

Directional conformer exchange in dihydrofolate reductase revealed by single-molecule nanopore recordings

Conformational heterogeneity is emerging as a defining characteristic of enzyme function. However, understanding the role of protein conformations requires their thermodynamic and kinetic characterization at the single-molecule level, which remains extremely challenging. Here we report the ligand-induced conformational changes of dihydrofolate reductase (DHFR) by measuring the modulation of the nanopore currents. The long observation time of the electrical recordings enabled the detection of rare conformational transitions hidden in ensemble measurements. We show that DHFR exists in at least four ground-state configurations or conformers with different affinities for its ligands. Unliganded DHFR adopted low-affinity conformers, whereas the binding of substrates promoted the switch to the high-affinity conformer. Conversion between the conformers was accelerated by molecules that stabilized the transition state of DHFR, which suggests that the reaction lowers the energy barrier for conformer exchange and thus facilitates product release. This mechanism might be a general feature in enzymatic reactions affected by product inhibition or when the release of products is the rate-limiting step. [Figure not available: see fulltext.]

Tuning the size and properties of ClyA nanopores assisted by directed evolution

Nanopores have recently emerged as powerful tools in single-molecule investigations. Biological nanopores, however, have drawbacks, including a fixed size and limited stability in lipid bilayers. Inspired by the great success of directed evolution approaches in tailoring enzyme properties, in this work we evolved Cytolysin A from Salmonella typhi (ClyA) to a high level of soluble expression and desired electrical properties in lipid bilayers. Evolved ClyA nanopores remained open up to -150 mV applied potential, which allowed the detailed characterization of folded proteins by ionic current recordings. Remarkably, we also found that ClyA forms several nanopore species; among which we could isolate and characterize three nanopore types most likely corresponding to the 12mer, 13mer, and 14mer oligomeric forms of ClyA. Protein current blockades to the three ClyA nanopores showed that subnanometer variations in the diameter of nanopores greatly affect the recognition of analyte proteins

Nanopores with internal protein adaptors

The present invention relates to methods for detecting an analyte in a sample, comprising the steps of obtaining a nanopore sensor comprising a nanopore and a protein adaptor internalized in the lumen of the nanopore, adding a sample comprising an analyte to the cis side or the trans side of the nanopore, and measuring conductance across the nanopore, wherein a change in conductance after adding the sample indicates the analyte is present in the sample and has bound to the protein adaptor. The present invention equally relates to nanopore sensors comprising a nanopore and a protein adaptor internalized in the lumen of the nanopore. Herein the protein adaptor is a functional enzyme or ligand-binding protein