Building and Using a Two-Photon Fluorescence Cross-Correlation Spectroscopy Setup Including Fluorescence Lifetime Analysis.

Fluorescence Cross-Correlation Spectroscopy (FCCS) is a well-established and useful tool in physics and chemistry. Furthermore, due to its hybrid character of being a bulk assay at a single molecular level, it found many applications in biophysics and molecular biochemistry. Examples may be investigating kinetics and dynamics of chemical and biochemical reactions such as protein-ligand-, protein-protein-binding, fast conformational changes, and intracellular transportation. Also, it was utilized to characterize larger structures such as lipid vesicles and multi-protein complexes. A two-photon excitation source makes FCCS relatively easy-to-use and easy-to-maintain. Combining this technique with fluorescence lifetime analysis results in a versatile biophysical tool that can be used to solve many biological problems, as even small changes in the local environment, like pH or salt concentration, can be monitored if appropriate fluorophores are used. An example of its use for membrane docking and fusion assays is described in Chap. 13 . In this chapter, we want to give the reader a simple, detailed step-by-step guide of how to set up such a tool.

Fluorescence Lifetime and Cross-correlation Spectroscopy for Observing Membrane Fusion of Liposome Models Containing Synaptic Proteins.

Watching events of membrane fusion in real time and distinguishing between intermediate steps of these events is useful for mechanistic insights but at the same time a challenging task. In this chapter, we describe how to use fluorescence cross-correlation spectroscopy and Förster-resonance energy transfer to resolve the tethering and fusion of membranes by SNARE proteins (syntaxin-1, SNAP-25, and synaptobrevin-2) as an example. The given protocols can easily be adapted to other membrane proteins to investigate their ability to tether or even fuse vesicular membrane.

Selected tools to visualize membrane interactions.

In the past decade, we developed various fluorescence-based methods for monitoring membrane fusion, membrane docking, distances between membranes, and membrane curvature. These tools were mainly developed using liposomes as model systems, which allows for the dissection of specific interactions mediated by, for example, fusion proteins. Here, we provide an overview of these methods, including two-photon fluorescence cross-correlation spectroscopy and intramembrane Förster energy transfer, with asymmetric labelling of inner and outer membrane leaflets and the calibrated use of transmembrane energy transfer to determine membrane distances below 10 nm. We discuss their application range and their limitations using examples from our work on protein-mediated vesicle docking and fusion.

PNA Hybrid Sequences as Recognition Units in SNARE-Protein-Mimicking Peptides.

Membrane fusion is an essential process in nature and is often accomplished by the specific interaction of SNARE proteins. SNARE model systems, in which SNARE domains are replaced by small artificial units, represent valuable tools to study membrane fusion in vitro. The synthesis and analysis is presented of SNARE model peptides that exhibit a recognition motif composed of two different types of peptide nucleic acid (PNA) sequences. This novel recognition unit is designed to mimic the SNARE zippering mechanism that initiates SNARE-mediated fusion. It contains N-(2-aminoethyl)glycine-PNA (aeg-PNA) and alanyl-PNA, which both recognize the respective complementary strand but differ in duplex topology and duplex formation kinetics. The duplex formation of PNA hybrid oligomers as well as the fusogenicity of the model peptides in lipid-mixing assays were characterized and the peptides were found to induce liposome fusion. As an unexpected discovery, peptides with a recognition unit containing only five aeg-PNA nucleo amino acids were sufficient and most efficient to induce liposome fusion.