Force spectroscopy with electromagnetic tweezers

TL;DR

This paper introduces a low-cost, electromagnetic tweezer device for force spectroscopy on single molecules, offering rapid force modulation and accessibility for educational and research purposes.

Contribution

The paper presents a novel, affordable electromagnetic tweezer design that enables precise manipulation of DNA-tethered beads, improving force control and accessibility over traditional magnetic tweezers.

Findings

Capable of applying forces up to 20 pN on DNA-tethered beads.

Allows fast force modulation without vibrations.

Accessible design suitable for educational settings.

Abstract

Force spectroscopy using magnetic tweezers (MT) is a powerful method to probe the physical characteristics of single polymers. Typically, molecules are functionalized for specific attachment to a glass surface at one end and a micron-scale paramagnetic beads at the other. By applying an external magnetic field, multiple molecules can be stretched and twisted simultaneously without exposure to potentially damaging radiation. The majority of MT utilize moving permanent magnets to produce the forces on the beads (and the molecule under test). However, translating and rotating the permanent magnets may require expensive precision actuators, limits the rate at which force is changed, and may induce vibrations that disturb tether dynamics. Alternatively, the magnetic field can be produced through an electromagnet which allows much faster force modulation and eliminates motor-associated vibration. Here, we describe a low-cost quadrapolar electromagnetic tweezer design capable of manipulating DNA-tethered MyOne paramagnetic beads with forces of up to 20 pN. The solid-state nature of the generated B-field modulated along two axes is convenient for accessing the range of forces and torques relevant for studying the activity of DNA motor enzymes like polymerases and helicases. Our design specifically leverages technology available at an increasing number university maker spaces and student-run machine shops. Thus, our design is not only applicable to a wide range biophysical research questions, but also an accessible tool for undergraduate education.