Neurotransmitter release is mediated by proteins that drive synaptic vesicle fusion with the presynaptic plasma membrane. While soluble N-ethylmaleimide sensitive factor attachment protein receptors (SNAREs) form the core of the fusion apparatus, additional proteins play key roles in the fusion pathway. Here, we report that the C-terminal amphipathic helix of the mammalian accessory protein, complexin (Cpx), exerts profound effects on membranes, including the formation of pores and the efficient budding and fission of vesicles. Using nanodisc-black lipid membrane electrophysiology, we demonstrate that the membrane remodeling activity of Cpx modulates the structure and stability of recombinant exocytic fusion pores. Cpx had particularly strong effects on pores formed by small numbers of SNAREs. Under these conditions, Cpx increased the current through individual pores 3.5-fold, and increased the open time fraction from roughly 0.1 to 1.0. We propose that the membrane sculpting activity of Cpx contributes to the phospholipid rearrangements that underlie fusion by stabilizing highly curved membrane fusion intermediates.

The last three decades have brought a revolution in fluorescence microscopy. The development of new microscopes, fluorescent labels and analysis techniques has pushed the frontiers of biological imaging forward, moving from fixed to live cells, from diffraction-limited to super-resolution imaging and from simple cell culture systems to experiments in vivo. The large and ever-evolving collection of tools can be daunting for biologists, who must invest substantial time and effort in adopting new technologies to answer their specific questions. This is particularly relevant when working with small-molecule fluorescent labels, where users must navigate the jargon, idiosyncrasies and caveats of chemistry. Here, we present an overview of chemical dyes used in biology and provide frank advice from a chemist's perspective.

Understanding live-cell behavior in part requires high precision mapping of molecular species in 3-D dynamic environments. Approaches like single-molecule localization microscopy (SMLM) offer high promise for challenges posed by molecular cartography. Effectively, the precision of these approaches is dependent on the how many photons / second a fluorescent marker is capable of emitting. For this reason, many SRLM experiments are typically done using fluorescent organic dyes (such as Alexa Fluors) in reducing chemical environments which cause some organic dyes to stochastically cycle through dark states, allowing single-molecule localization (e.g. (d)STORM). The need to couple these dyes to antibodies and the harsh reducing conditions makes their application to live cell work problematic. To overcome these limitations, we made use of modifications to Janelia Fluor-based dyes which make them spontaneously cycle through dark states (blink) under physiological imaging conditions. The dyes are spectrally compatible with photo-activatable fluorescent proteins such as mEos and allow for simultaneous 2-color superresolution microscopy. When conjugated to a HaloTag, these artificial dyes can bind genetically encodable targets in live samples, allowing subsequent measurement in a live-cell environment. To correct for nanoscale chromatic aberrations we developed a new machine-learning based approach with reconstruction errors below achievable localization precisions. We show that these methods allow the reconstruction of live synapse surfaces and a variety of the associated molecular machineries with up to 50 nm accuracy in 3 dimensions.