Weixiang Jin scite author profile

Membrane bound cell signaling is modulated by the membrane ultra-structure, which itself may be affected by signaling. However, measuring the interaction of membrane proteins with membrane structures in intact cells in real-time poses considerable challenges. In this paper we present a non-destructive fluorescence method that quantifies these interactions in single cells, and is able to monitor the same cell continuously to observe small changes. This approach combines total internal fluorescence microscopy with fluorescence correlation spectroscopy to measure the protein’s diffusion and molecular concentration in different sized areas simultaneously. It correctly differentiates proteins interacting with membrane fences from proteins interacting with cholesterol-stabilized domains, or lipid rafts. This method detects small perturbations of the membrane ultra-structure or of a protein’s tendency to dimerize. Through continuous monitoring of single cells, we demonstrate how dimerization of GPI-anchored proteins increases their association with the structural domains. Using a dual-color approach we study the effect of dimerization of one GPI-anchored protein on another type of GPI-anchored protein expressed in the same cell. Scans over the cell surface reveal a correlation between cholesterol stabilized domains and membrane cytoskeleton.

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Membrane nanodomains homeostasis during propofol anesthesia as function of dosage and temperature

Jin

Zucker

Pralle

2021

Biochimica et Biophysica Acta (BBA) - Biomembranes

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Some anesthetics bind and potentiate g-aminobutyric-acid-type receptors, but no universal mechanism for general anesthesia is known. Furthermore, often encountered complications such as anesthesia induced amnesia are not understood. General anesthetics are hydrophobic molecules easily dissolving into lipid bilayers. Recently, it was shown that general anesthetics perturb phase separation in vesicles extracted from fixed cells. Unclear is whether under physiological conditions general anesthetics induce perturbation of the lipid bilayer, and whether this contributes to the transient loss of consciousness or anesthesia side effects. Here we show that propofol perturbs lipid nanodomains in the outer and inner leaflet of the plasma membrane in intact cells, affecting membrane nanodomains in a concentration dependent manner: 1 μM to 5 μM propofol destabilize nanodomains; however, propofol concentrations higher than 5 μM stabilize nanodomains with time. Stabilization occurs only at physiological temperature and in intact cells. This process requires ARP2/3 mediated actin nucleation and Myosin II activity. The rate of nanodomain stabilization is potentiated by GABA receptor activity. Our results show that active nanodomain homeostasis counteracts the initial disruption causing large changes in cortical actin. Significance Statement General anesthesia is a routine medical procedure with few complications, yet a small number of patients experience side-effects that persist for weeks and months. Very young children are at risk for effects on brain development. Elderly patients often exhibit subsequent amnesia. Here, we show that the general anesthetic propofol perturbs the ultrastructure of the lipid bilayer of the cell membrane in intact cells. Initially propofol destabilized lipid nanodomains. However, with increasing incubation time and propofol concentration, the effect is reversed and nanodomains are further stabilized. We show that this stabilization is caused by the activation of the actin cortex under the membrane. These perturbations of membrane bilayer and cortical actin may explain how propofol affects neuronal plasticity at synapses.

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Quantifying spatial and temporal variations of the cell membrane ultra-structure by bimFCS

Jin

Simsek

Pralle

2018

Methods

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It has been long recognized that the cell membrane is heterogeneous on scales ranging from a couple of molecules to micrometers in size and hence diffusion of receptors is length scale dependent. This heterogeneity modulates many cell-membrane-associated processes requiring transient spatiotemporal separation of components. The transient increase in local concentration of interacting signal components enables robust signaling in an otherwise thermally noisy system. Understanding how lipids and proteins self-organize and interact with the cell cortex requires quantifying the motion of the components. Multi-length scale diffusion measurements by single particle tracking, fluorescence correlation spectroscopy (FCS) or related techniques are able to identify components being transiently trapped in nanodomains, from freely moving one and from ones with reduced long-scale diffusion due to interaction with the cell cortex. One particular implementation of multi-length scale diffusion measurements is the combination of FCS with a spatially resolved detector, such as a camera and two-dimensional extended excitation profile. The main advantages of this approach are that all length scales are interrogated simultaneously, uniquely permits quantifying changes to the membrane structure caused by extrenal or internal perturbations. Here, we review how combining total internal reflection microscopy (TIRF) with FC resolves the membrane organization in living cells. We show how to implement the method, which requires only a few seconds of data acquisition to quantify membrane nanodomains, or the spacing of membrane fences caused by the actin cortex. The choice of diffusing fluorescent probe determines which membrane heterogeneity is detected. We review the instrument, sample preparation, experimental and computational requirements to perform such measurements, and discuss the potential and limitations. The discussion includes examples of spatial and temporal comparisons of the membrane structure in response to perturbations demonstrating the complex cell physiology.

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Influence of Calcium Concentration on Lipid Domains in the Inner and Outer Leaflets of the Plasma Membrane

Jin

Huang

Pralle

2013

Biophysical Journal

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Giant unilamellar vesicles (GUVs) containing two coexisting liquid phases are widely used to study lateral heterogeneity of membrane components. Previously, we reported a novel technique for depositing lipid bilayers onto agarose cushions that conserves many properties of phase separated domains in vesicles, including transition temperatures and macroscopic circular domains. In this poster, we describe our efforts to further characterize and refine these supported membranes. For example, we find that agarose supported membranes with a continuous liquid-disordered phase are more easily assembled compared to membranes with a continuous liquid-ordered phase. We also find that larger and more mobile domains are found after extended equilibration times when membranes are supported on lower melting temperature agarose compared to higher melting temperature agarose. Also, we have quantified the dynamics of domain coarsening in membranes at multiple compositions and temperatures.

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Transient Effect of Calcium Influx on PIP2 Clusters and Cholesterol-Stabilized Nano-Domains in the Inner Plasma Membrane Leaflet of Intact Cells

Jin

Huang

Pralle

2014

Biophysical Journal

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associated with severe pathologies such as the neonatal respiratory distress syndrome (NRDS) or Acute RDS in adults. Treatment of babies suffering or at risk of NRDS consists in an intratraqueal application of a dense aqueous suspension of exogenous surfactant. Widespread application of exogenous surfactant therapies in adults is still under development, in part due to limited availability of clinical surfactant and because it is an invasive therapy which requires the intubation of the patient. The fact that surfactant must be stored at 4 C to preserve its functional properties, causes some difficulties during transport and storage, mainly in developing countries where these therapies are strongly needed to treat premature newborns. In this context, lyophilisation is contemplated as a way to keep surfactant properties. This work assesses the effect of lyophilization and later reconstitution on the interfacial properties of the lateral structure of porcine native lung surfactant films.

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Weixiang Jin

Effect of Receptor Dimerization on Membrane Lipid Raft Structure Continuously Quantified on Single Cells by Camera Based Fluorescence Correlation Spectroscopy

Membrane nanodomains homeostasis during propofol anesthesia as function of dosage and temperature

Quantifying spatial and temporal variations of the cell membrane ultra-structure by bimFCS

Influence of Calcium Concentration on Lipid Domains in the Inner and Outer Leaflets of the Plasma Membrane

Transient Effect of Calcium Influx on PIP2 Clusters and Cholesterol-Stabilized Nano-Domains in the Inner Plasma Membrane Leaflet of Intact Cells

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