Heterogeneity of cell membrane structure studied by single molecule tracking.

Heterogeneity in cell membrane structure, typified by microdomains with different biophysical and biochemical properties, is thought to impact on a variety of cell functions. Integral membrane proteins act as nanometre-sized probes of the lipid environment and their thermally-driven movements can be used to report local variations in membrane properties. In the current study, we have used total internal reflection fluorescence microscopy (TIRFM) combined with super-resolution tracking of multiple individual molecules, in order to create high-resolution maps of local membrane viscosity. We used a quadrat sampling method and show how statistical tests for membrane heterogeneity can be conducted by analysing the paths of many molecules that pass through the same unit area of membrane. We describe experiments performed on cultured primary cells, stable cell lines and ex vivo tissue slices using a variety of membrane proteins, under different imaging conditions. In some cell types, we find no evidence for heterogeneity in mobility across the plasma membrane, but in others we find statistically significant differences with some regions of membrane showing significantly higher viscosity than others.

Th1, Th17, and Th1Th17 Lymphocytes during Tuberculosis: Th1 Lymphocytes Predominate and Appear as Low-Differentiated CXCR3+CCR6+ Cells in the Blood and Highly Differentiated CXCR3+/-CCR6- Cells in the Lungs.

Th1 lymphocytes are considered the main mediators of protection against tuberculosis (TB); however, their phenotypic characteristics and relationship with Th17 and Th1Th17 populations during TB are poorly understood. We have analyzed Th1, Th17, and Th1Th17 lymphocytes in the blood and pulmonary lesions of TB patients. The populations were identified based on the production of IFN-γ and/or IL-17 and the coexpression of CXCR3 (X3) and CCR6 (R6). In the blood, IL-17+ and IFN-γ+IL-17+ lymphocytes were barely detectable (median, <0.01% of CD4+ lymphocytes), whereas IFN-γ+ lymphocytes predominated (median, 0.45%). Most IFN-γ+ lymphocytes (52%) were X3+R6+, suggesting their "nonclassical" (ex-Th17) nature. In the lungs, IL-17+ and IFN-γ+IL-17+ lymphocytes were more frequent (0.3%, p < 0.005), yet IFN-γ+ cells predominated (11%). Phenotypically, lung CD4+ cells were X3+/loR6- The degree of differentiation of blood effector CD4+ lymphocytes (evaluated based on CD62L/CD27/CD28 coexpression) increased as follows: X3+R6+ < X3+R6- < X3-R6-, with X3-R6- cells being largely terminally differentiated CD62L-CD27-CD28- cells. Lung CD4+ lymphocytes were highly differentiated, recalling blood X3+/-R6- populations. Following in vitro stimulation with anti-CD3/anti-CD28 Abs, X3+R6+CD4+ lymphocytes converted into X3+R6- and X3-R6- cells. The results demonstrate that, during active TB, Th1 lymphocytes predominate in blood and lungs, document differences in X3/R6 expression by blood and lung CD4+ cells, and link the pattern of X3/R6 expression with the degree of cell differentiation. These findings add to the understanding of immune mechanisms operating during TB and are relevant for the development of better strategies to control it.

A Combination of Diffusion and Active Translocation Localizes Myosin 10 to the Filopodial Tip.

Myosin 10 is an actin-based molecular motor that localizes to the tips of filopodia in mammalian cells. To understand how it is targeted to this distinct region of the cell, we have used total internal reflection fluorescence microscopy to study the movement of individual full-length and truncated GFP-tagged molecules. Truncation mutants lacking the motor region failed to localize to filopodial tips but still bound transiently at the plasma membrane. Deletion of the single α-helical and anti-parallel coiled-coil forming regions, which lie between the motor and pleckstrin homology domains, reduced the instantaneous velocity of intrafilopodial movement but did not affect the number of substrate adherent filopodia. Deletion of the anti-parallel coiled-coil forming region, but not the EKR-rich region of the single α-helical domain, restored intrafilopodial trafficking, suggesting this region is important in determining myosin 10 motility. We propose a model by which myosin 10 rapidly targets to the filopodial tip via a sequential reduction in dimensionality. Molecules first undergo rapid diffusion within the three-dimensional volume of the cell body. They then exhibit periods of slower two-dimensional diffusion in the plane of the plasma membrane. Finally, they move in a unidimensional, highly directed manner along the polarized actin filament bundle within the filopodium becoming confined to a single point at the tip. Here we have observed directly each phase of the trafficking process using single molecule fluorescence imaging of live cells and have quantified our observations using single particle tracking, autocorrelation analysis, and kymographs.

Abundance, distribution, mobility and oligomeric state of M2 muscarinic acetylcholine receptors in live cardiac muscle.

M2 muscarinic acetylcholine receptors modulate cardiac rhythm via regulation of the inward potassium current. To increase our understanding of M2 receptor physiology we used Total Internal Reflection Fluorescence Microscopy to visualize individual receptors at the plasma membrane of transformed CHO(M2) cells, a cardiac cell line (HL-1), primary cardiomyocytes and tissue slices from pre- and post-natal mice. Receptor expression levels between individual cells in dissociated cardiomyocytes and heart slices were highly variable and only 10% of murine cardiomyocytes expressed muscarinic receptors. M2 receptors were evenly distributed across individual cells and their density in freshly isolated embryonic cardiomyocytes was ~1µm(-2), increasing at birth (to ~3µm(-2)) and decreasing back to ~1µm(-2) after birth. M2 receptors were primarily monomeric but formed reversible dimers. They diffused freely at the plasma membrane, moving approximately 4-times faster in heart slices than in cultured cardiomyocytes. Knowledge of receptor density and mobility has allowed receptor collision rate to be modeled by Monte Carlo simulations. Our estimated encounter rate of 5-10 collisions per second, may explain the latency between acetylcholine application and GIRK channel opening.

A method for imaging single molecules at the plasma membrane of live cells within tissue slices.

Recent advances in light microscopy allow individual biological macromolecules to be visualized in the plasma membrane and cytosol of live cells with nanometer precision and ∼10-ms time resolution. This allows new discoveries to be made because the location and kinetics of molecular interactions can be directly observed in situ without the inherent averaging of bulk measurements. To date, the majority of single-molecule imaging studies have been performed in either unicellular organisms or cultured, and often chemically fixed, mammalian cell lines. However, primary cell cultures and cell lines derived from multi-cellular organisms might exhibit different properties from cells in their native tissue environment, in particular regarding the structure and organization of the plasma membrane. Here, we describe a simple approach to image, localize, and track single fluorescently tagged membrane proteins in freshly prepared live tissue slices and demonstrate how this method can give information about the movement and localization of a G protein-coupled receptor in cardiac tissue slices. In principle, this experimental approach can be used to image the dynamics of single molecules at the plasma membrane of many different soft tissue samples and may be combined with other experimental techniques.

Imaging individual myosin molecules within living cells.

Myosins are mechano-enzymes that convert the chemical energy of ATP hydrolysis into mechanical work. They are involved in diverse biological functions including muscle contraction, cell migration, cell division, hearing, and vision. All myosins have an N-terminal globular domain, or "head" that binds actin, hydrolyses ATP, and produces force and movement. The C-terminal "tail" region is highly divergent amongst myosin types, and this part of the molecule is responsible for determining the cellular role of each myosin. Many myosins bind to cell membranes. Their membrane-binding domains vary, specifying which lipid each myosin binds to. To directly observe the movement and localisation of individual myosins within the living cell, we have developed methods to visualise single fluorescently labelled molecules, track them in space and time, and gather a sufficient number of individual observations so that we can draw statistically valid conclusions about their biochemical and biophysical behaviour. Specifically, we can use this approach to determine the affinity of the myosin for different binding partners, and the nature of the movements that the myosins undergo, whether they cluster into larger molecular complexes and so forth. Here, we describe methods to visualise individual myosins as they move around inside live mammalian cells, using myosin-10 and myosin-6 as examples for this type of approach.