Quantification of protein delivery in live cells using fluorescence correlation spectroscopy.

Fluorescence correlation spectroscopy (FCS) is a quantitative single-molecule method that measures the concentration and rate of diffusion of fluorophore-tagged molecules, both large and small, in vitro and within live cells, and even within discrete cellular compartments. FCS is exceptionally well-suited to directly quantify the efficiency of intracellular protein delivery-specifically, how well different "cell-penetrating" proteins and peptides guide proteinaceous materials into the cytosol and nuclei of live mammalian cells. This article provides an overview of the procedures necessary to execute robust FCS experiments and evaluate endosomal escape efficiencies: preparation of fluorophore-tagged proteins, incubation with mammalian cells and preparation of FCS samples, setup and execution of an FCS experiment, and a detailed discussion of and custom MATLAB® script for analyzing the resulting autocorrelation curves in the context of appropriate diffusion models.

Single-shot super-resolution total internal reflection fluorescence microscopy.

We combined instant structured illumination microscopy (iSIM) with total internal reflection fluorescence microscopy (TIRFM) in an approach referred to as instant TIRF-SIM, thereby improving the lateral spatial resolution of TIRFM to 115 ± 13 nm without compromising speed, and enabling imaging frame rates up to 100 Hz over hundreds of time points. We applied instant TIRF-SIM to multiple live samples and achieved rapid, high-contrast super-resolution imaging close to the coverslip surface.

Regulation of insulin exocytosis by calcium-dependent protein kinase C in beta cells.

The control of insulin release from pancreatic beta cells helps ensure proper blood glucose level, which is critical for human health. Protein kinase C has been shown to be one key control mechanism for this process. After glucose stimulation, calcium influx into beta cells triggers exocytosis of insulin-containing dense-core granules and activates protein kinase C via calcium-dependent phospholipase C-mediated generation of diacylglycerol.

Two-Color Total Internal Reflection Fluorescence Microscopy of Exocytosis in Endocrine Cells.

We describe a comprehensive method for imaging and analysis of local protein dynamics at single sites of exocytosis in living cultured endocrine cells. This method is well suited to quantitatively map the complex dynamics of individual molecules at single sites of vesicle fusion in live cells.

Imaging the recruitment and loss of proteins and lipids at single sites of calcium-triggered exocytosis.

How and when the dozens of molecules that control exocytosis assemble in living cells to regulate the fusion of a vesicle with the plasma membrane is unknown. Here we image with two-color total internal reflection fluorescence microscopy the local changes of 27 proteins at single dense-core vesicles undergoing calcium-triggered fusion. We identify two broad dynamic behaviors of exocytic molecules.

Precise quantification of cellular uptake of cell-penetrating peptides using fluorescence-activated cell sorting and fluorescence correlation spectroscopy.

Cell-penetrating peptides (CPPs) have emerged as a potentially powerful tool for drug delivery due to their ability to efficiently transport a whole host of biologically active cargoes into cells. Although concerted efforts have shed some light on the cellular internalization pathways of CPPs, quantification of CPP uptake has proved problematic. Here we describe an experimental approach that combines two powerful biophysical techniques, fluorescence-activated cell sorting (FACS) and fluorescence correlation spectroscopy (FCS), to directly, accurately and precisely measure the cellular uptake of fluorescently-labeled molecules.

RAG and HMGB1 create a large bend in the 23RSS in the V(D)J recombination synaptic complexes.

During V(D)J recombination, recombination activating gene proteins RAG1 and RAG2 generate DNA double strand breaks within a paired complex (PC) containing two complementary recombination signal sequences (RSSs), the 12RSS and 23RSS, which differ in the length of the spacer separating heptamer and nonamer elements. Despite the central role of the PC in V(D)J recombination, little is understood about its structure. Here, we use fluorescence resonance energy transfer to investigate the architecture of the 23RSS in the PC.

The conformational ensembles of α-synuclein and tau: combining single-molecule FRET and simulations.

Intrinsically disordered proteins (IDPs) are increasingly recognized for their important roles in a range of biological contexts, both in normal physiological function and in a variety of devastating human diseases. However, their structural characterization by traditional biophysical methods, for the purposes of understanding their function and dysfunction, has proved challenging. Here, we investigate the model IDPs α-Synuclein (αS) and tau, that are involved in major neurodegenerative conditions including Parkinson's and Alzheimer's diseases, using excluded volume Monte Carlo simulations constrained by pairwise distance distributions from single-molecule fluorescence measurements.

Function and dysfunction of α-synuclein: probing conformational changes and aggregation by single molecule fluorescence.

The aggregation and deposition of the neuronal protein α-synuclein in the substantia nigra region of the brain is a key pathological feature of Parkinson's disease. α-Synuclein assembles from a monomeric state in solution, which lacks stable secondary and tertiary contacts, into highly structured fibrillar aggregates through a pathway which involves the population of multiple oligomeric species over a range of time scales. These features make α-synuclein well suited for study with single-molecule techniques, which are particularly useful for characterizing dynamic, heterogeneous samples.

N-Terminal acetylation is critical for forming α-helical oligomer of α-synuclein.

The aggregation of the protein α-synuclein (AS) is critical to the pathogenesis of Parkinson's disease. Although generally described as an unstructured monomer, recent evidence suggests that the native form of AS may be an α-helical tetramer which resists aggregation. Here, we show that N-terminal acetylation in combination with a mild purification protocol results in an oligomeric form of AS with partial α-helical structure.

Allostery in a disordered protein: oxidative modifications to α-synuclein act distally to regulate membrane binding.

Both oxidative stress and aggregation of the protein α-synuclein (aS) have been implicated as key factors in the etiology of Parkinson's disease. Specifically, oxidative modifications to aS disrupt its binding to lipid membranes, an interaction considered critical to its native function. Here we seek to provide a mechanistic explanation for this phenomenon by investigating the effects of oxidative nitration of tyrosine residues on the structure of aS and its interaction with lipid membranes.

Single molecule characterization of α-synuclein in aggregation-prone states.

α-Synuclein (αS) is an intrinsically disordered protein whose aggregation into ordered, fibrillar structures underlies the pathogenesis of Parkinson's disease. A full understanding of the factors that cause its conversion from soluble protein to insoluble aggregate requires characterization of the conformations of the monomer protein under conditions that favor aggregation. Here we use single molecule Förster resonance energy transfer to probe the structure of several aggregation-prone states of αS.

Single-molecule fluorescence spectroscopy using phospholipid bilayer nanodiscs.

Nanodiscs are a new class of model membranes that are being used to solubilize and study a range of integral membrane proteins and membrane-associated proteins. Unlike other model membranes, the Nanodisc bilayer is bounded by a scaffold protein coat that confers enhanced stability and a narrow particle size distribution. The bilayer diameter can be precisely controlled by changing the diameter of the protein coat.

Alpha-synuclein binds large unilamellar vesicles as an extended helix.

Interactions between the synaptic protein alpha-Synuclein and cellular membranes may be relevant both to its native function as well as its role in Parkinson's disease. We use single molecule Forster resonance energy transfer to probe the structure of alpha-Synuclein bound to detergent micelles and lipid vesicles. We find evidence that it forms a bent-helix when bound to highly curved detergent micelles, whereas it binds more physiological 100 nm diameter lipid vesicles as an elongated helix.

The formation of amyloid fibrils from proteins in the lysozyme family.

Amyloid fibrils are highly ordered protein assemblies known to contribute to the pathology of a variety of genetic and aging-associated diseases. More recently, these fibrils have been shown to be useful as structural scaffolds in both natural biological systems and nanotechnology applications. The intense interest in amyloid fibrils has led to the investigation of well-characterized proteins, such as hen egg white lysozyme (HEWL), as model systems to examine structural and mechanistic principles that may be generally applicable to all amyloid fibrils.