Intramolecular photostabilization via triple-state quenching was recently revived as a tool to impart synthetic organic fluorophores with ‘self-healing’ properties. To date, utilization of such fluorophore derivatives is rare due to their elaborate multi-step synthesis. Here we present a general strategy to covalently link a synthetic organic fluorophore simultaneously to a photostabilizer and biomolecular target via unnatural amino acids. The modular approach uses commercially available starting materials and simple chemical transformations. The resulting photostabilizer–dye conjugates are based on rhodamines, carbopyronines and cyanines with excellent photophysical properties, that is, high photostability and minimal signal fluctuations. Their versatile use is demonstrated by single-step labelling of DNA, antibodies and proteins, as well as applications in single-molecule and super-resolution fluorescence microscopy. We are convinced that the presented scaffolding strategy and the improved characteristics of the conjugates in applications will trigger the broader use of intramolecular photostabilization and help to emerge this approach as a new gold standard.
Human immunodeficiency virus type 1 (HIV-1) assembles as immature particles, which require the proteolytic cleavage of structural polyprotein Gag and the clustering of envelope glycoprotein Env for infectivity. The details of mechanisms underlying Env clustering remain unknown. Here, we determine molecular dynamics of Env on the surface of individual HIV-1 particles using scanning fluorescence correlation spectroscopy on a super-resolution STED microscope. We find that Env undergoes a maturation-induced increase in mobility, highlighting diffusion as one cause for Env clustering. This mobility increase is dependent on Gag-interacting Env tail but not on changes in viral envelope lipid order. Diffusion of Env and other envelope incorporated proteins in mature HIV-1 is two orders of magnitude slower than in the plasma membrane, indicating that HIV-1 envelope is intrinsically a low mobility environment, mainly due to its general high lipid order. Our results provide insights into dynamic properties of proteins on the surface of individual virus particles.
The diffusion dynamics of lipids and GPI-anchored proteins is investigated using superresolution STED microscopy combined with single-molecule fluorescence correlation spectroscopy in the cellular membranes. The actin cytoskeleton is shown to play an essential role in the diffusion characteristics of molecules.
EDITORIAL SUMMARY This Protocol describes how to measure nanoscale diffusion dynamics of proteins and lipids in cell membranes using STED-FCS. The protocol contains procedures for calibration, performing point-and scanning-STED-FCS measurements, and data analysis.TWEET Measuring nanoscale diffusion dynamics in cell membranes using super-resolution STED-FCS. #superresolution COVER TEASER Nanoscale diffusion dynamics using STED-FCS Up to three primary research articles where the protocol has been used and/or developed:
Heterogeneous diffusion dynamics
of molecules play an important role in many cellular signaling events,
such as of lipids in plasma membrane bioactivity. However, these dynamics
can often only be visualized by single-molecule and super-resolution
optical microscopy techniques. Using fluorescence lifetime correlation
spectroscopy (FLCS, an extension of fluorescence correlation spectroscopy,
FCS) on a super-resolution stimulated emission depletion (STED) microscope,
we here extend previous observations of nanoscale lipid dynamics in
the plasma membrane of living mammalian cells. STED-FLCS allows an
improved determination of spatiotemporal heterogeneity in molecular
diffusion and interaction dynamics via a novel gated detection scheme,
as demonstrated by a comparison between STED-FLCS and previous conventional
STED-FCS recordings on fluorescent phosphoglycerolipid and sphingolipid
analogues in the plasma membrane of live mammalian cells. The STED-FLCS
data indicate that biophysical and biochemical parameters such as
the affinity for molecular complexes strongly change over space and
time within a few seconds. Drug treatment for cholesterol depletion
or actin cytoskeleton depolymerization not only results in the already
previously observed decreased affinity for molecular interactions
but also in a slight reduction of the spatiotemporal heterogeneity.
STED-FLCS specifically demonstrates a significant improvement over
previous gated STED-FCS experiments and with its improved spatial
and temporal resolution is a novel tool for investigating how heterogeneities
of the cellular plasma membrane may regulate biofunctionality.
In stimulated emission depletion (STED) microscopy, the spatial resolution scales as the inverse square root of the STED beam's intensity. However, to fully exploit the maximum effective resolution achievable for a given STED beam's intensity, several experimental precautions have to be considered. We focus our attention on the temporal alignment between the excitation and STED pulses and the polarization state of the STED beam. We present a simple theoretical framework that help to explain their influence on the performance of a STED microscope and we validate the results by imaging calibration and biological samples with a custom made STED architecture based on a supercontinuum laser source. We also highlight the advantages of using time gating detection in terms of temporal alignment.
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