Biophysics & Nanosciences­ „Physics of Life“

Single Molecule AFM Force Spectroscopy

PHYSICS OF MOLECULAR RECOGNITION

Contact: Dr. Volker Walhorn

The physical mechanisms of specific, non-covalent intermolecular binding is quantitatively investigated by single-molecule (dynamic) force spectroscopy with atomic force microscopy (AFM), optical tweezers (OT) and magnetic tweezers (MT). Here, specific molecular forces, elasticities, kinetic reaction rate constants (lifetimes) and the energy landscape of the molecular binding potential is measured by AFM at the single-molecule level in vitro on isolated but functional complexes. Nowadays, these specific interactions can be scrutinized in a quantitative manner at the sensitivity level on single-point mutations (nucleic acids, amino acids) allowing single-molecule affinity ranking in a broad affinity range of 0,1 mM-1 fM revealing distinct differences in the binding properties and mechanisms. Over the last years, special emphasis has been put on so-called molecular catch-bond systems that were observed when investigating the interplay of human sulfatates (Sulf1, Sulf2) with glycosaminoglycans (heparan sulfate, heparin, dermatan sulfate, ...) in cell signaling cascades. In addition, we recently explored the homophilic interaction mechanisms between desmosomal desmoglein-2 (DSG2) and mutations thereof that play an important role for the integrity of mechanically active cells like cardiomyocytes.

Tip and sample surface are both functionalized. In close proximity, individual molecular bonds are formed. When pulled apart, ruptures can be seen as a jumps in the force curve. The corresponding binding forces and lifetimes can be measured with high precision, giving insight in biological relevant binding and sensing processes and even protein folding.

Fluorescent labeled cell compartments help guide where to poke the cell - to measure the elasticity in regards to specific organelles that might be affected by genetic conditions.

Single Molecule Photonics

AFM-TIRF / SNOM

Contact: Dr. Volker Walhorn

Single molecules can nowadays be investigated by means of optical, mechanical and electrical methods. Single molecule fluorescence imaging and spectroscopy yield valuable and quantitative information about optical properties, spatial distribution and temporal dynamics of single molecules.
We have developped 1) scanning near-field optical microscopy (SNOM) for single molecule imaging and spectroscopy and 2) a small-cantilever based AFM combined with total internal reflection fluorescence (TIRF) microscopy for ultrasensitive LIF detection of individual fluorophores and simultaneous AFM control and manipulation at the molecular level.

Individual fluorescent markers can be localized in the AFM topography with super resolution precision - here shown in tobacco mosaic viruses.

Simulation of an electric field at a gold tip 5nm above an air-glass interface. The configuration is illuminated from below at an angle of 50°, so that an evanescent field is formed above the interface
 

Evanescent illumination causes several hundred-times higher field intensities at the cantilever apex as usual - also enhancing the radiative emission of fluorophor

Optical Tweezers

SINGLE MOLECULE BIOSENSOR & MANIPULATION

Contact: Prof. Dr. Dario Anselmetti

Micron-sized objects like beads, colloids or cells can be trapped, steered and manipulated by light and allow force experiments at the single molecule level with a force sensitivity level of 0.1 pN. We set up two high stability single-beam optical tweezers (OT) system on an inverted light microscope which allows analytical force spectroscopy, adhesion and elasticity experiments with single molecules or cells in an experimental force range of 0.1-900 pN.

Principle in the experiments with controlled DNA translocations through nanopores with optical tweezers.

Measuring the elasticity of a HEK-293 cell with two optically trapped polystyrene beads

Magnetic Tweezers

SINGLE MOLECULE MANIPULATION WITH MAGNETIC FIELDS

Contact: Prof. Dr. Dario Anselmetti

Magnetic microbeads can be manipulated and steered by external magnetic fields and allow stretching and overwinding experiments with single (DNA) molecules at a sensitivity level downto 0,001 pN. With our magnetic tweezers (MT) apparatus (PicoTwist, Lyon - France) we investigate and quantify the binding of proteins, fluorescent dyes and chemotherapeutic agents to DNA.

Magnetic beads are optically transparent. Their diffraction pattern is used to determine their vertical position and the length of the attached DNA stands