31 research outputs found
Protons in small spaces:Discrete simulations of vesicle acidification
The lumenal pH of an organelle is one of its defining characteristics and central to its biological function. Experiments have elucidated many of the key pH regulatory elements and how they vary from compartment-to-compartment, and continuum mathematical models have played an important role in understanding how these elements (proton pumps, counter-ion fluxes, membrane potential, buffering capacity, etc.) work together to achieve specific pH setpoints. While continuum models have proven successful in describing ion regulation at the cellular length scale, it is unknown if they are valid at the subcellular level where volumes are small, ion numbers may fluctuate wildly, and biochemical heterogeneity is large. Here, we create a discrete, stochastic (DS) model of vesicular acidification to answer this question. We used this simplified model to analyze pH measurements of isolated vesicles containing single proton pumps and compared these results to solutions from a continuum, ordinary differential equations (ODE)-based model. Both models predict similar parameter estimates for the mean proton pumping rate, membrane permeability, etc., but, as expected, the ODE model fails to report on the fluctuations in the system. The stochastic model predicts that pH fluctuations decrease during acidification, but noise analysis of single-vesicle data confirms our finding that the experimental noise is dominated by the fluorescent dye, and it reveals no insight into the true noise in the proton fluctuations. Finally, we again use the reduced DS model explore the acidification of large, lysosome-like vesicles to determine how stochastic elements, such as variations in proton-pump copy number and cycling between on and off states, impact the pH setpoint and fluctuations around this setpoint
Probing Activation and Conformational Dynamics of the Vesicle-Reconstituted β<sub>2</sub> Adrenergic Receptor at the Single-Molecule Level
G-protein-coupled receptors (GPCRs) are structurally
flexible membrane
proteins that mediate a host of physiological responses to extracellular
ligands like hormones and neurotransmitters. Fine features of their
dynamic structural behavior are hypothesized to encode the functional
plasticity seen in GPCR activity, where ligands with different efficacies
can direct the same receptor toward different signaling phenotypes.
Although the number of GPCR crystal structures is increasing, the
receptors are characterized by complex and poorly understood conformational
landscapes. Therefore, we employed a fluorescence microscopy assay
to monitor conformational dynamics of single β2 adrenergic
receptors (β2ARs). To increase the biological relevance
of our findings, we decided not to reconstitute the receptor in detergent
micelles but rather lipid membranes as proteoliposomes. The conformational
dynamics were monitored by changes in the intensity of an environmentally
sensitive boron-dipyrromethene (BODIPY 493/503) fluorophore conjugated
to an endogenous cysteine (located at the cytoplasmic end of the sixth
transmembrane helix of the receptor). Using total internal reflection
fluorescence microscopy (TIRFM) and a single small unilamellar liposome
assay that we previously developed, we followed the real-time dynamic
properties of hundreds of single β2ARs reconstituted
in a native-like environmentlipid membranes. Our results showed
that β2AR-BODIPY fluctuates between several states
of different intensity on a time scale of seconds, compared to BODIPY-lipid
conjugates that show almost entirely stable fluorescence emission
in the absence and presence of the full agonist BI-167107. Agonist
stimulation changes the β2AR dynamics, increasing
the population of states with higher intensities and prolonging their
durations, consistent with bulk experiments. The transition density
plot demonstrates that β2AR-BODIPY, in the absence
of the full agonist, interconverts between states of low and moderate
intensity, while the full agonist renders transitions between moderate
and high-intensity states more probable. This redistribution is consistent
with a mechanism of conformational selection and is a promising first
step toward characterizing the conformational dynamics of GPCRs embedded
in a lipid bilayer
Nanoscale high-content analysis using compositional heterogeneities of single proteoliposomes
Proteoliposome reconstitution is a standard method to stabilize purified transmembrane proteins in membranes for structural and functional assays. Here we quantified intrareconstitution heterogeneities in single proteoliposomes using fluorescence microscopy. Our results suggest that compositional heterogeneities can severely skew ensemble-average proteoliposome measurements but also enable ultraminiaturized high-content screens. We took advantage of this screening capability to map the oligomerization energy of the β(2)-adrenergic receptor using ~10(9)-fold less protein than conventional assays