Spatiotemporal analysis of endocytosis and membrane distribution of fluorescent sterols in living cells

Distribution and dynamics of cholesterol in the plasma membrane as well as internalization pathways for sterol from the cell surface are of great cell biological interest. Here, UV-sensitive wide field microscopy of the intrinsically fluorescent sterols, dehydroergosterol (DHE) and cholestatrienol (CTL) combined with advanced image analysis were used to study spatiotemporal sterol distribution in living macrophages, adipocytes and fibroblasts. Sterol endocytosis was directly visualized by time-lapse imaging and noise-robust tracking revealing confined motion of DHE containing vesicles in close proximity to the cell membrane. Spatial surface intensity patterns of DHE as well as that of the lipid marker DiIC12 being assessed by statistical image analysis persisted over several minutes in cells having a constant overall curvature. Sites of sterol endocytosis appeared indistinguishable from other regions of the cell surface, and endocytosis contributed by 62% to total sterol uptake in J774 cells. DHE co-localized with fluorescent transferrin (Tf) in vesicles right after onset of endocytosis and in deepened surface patches of energy depleted cells. Surface caveolae labeled with GFP-tagged caveolin were not particularly enriched in DHE or CTL. Some sterol co-localized with internalized caveolin suggesting that caveolar endocytosis contributes to vesicular sterol uptake. These findings demonstrate that plasma membrane sterol is internalized by several endocytic pathways. Sterol endocytosis does not require formation of microscopically resolvable sterol clusters or enrichment of sterol in surface caveolae. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Plasma membrane sterol distribution resembles the surface topography of living cells

Cholesterol is an important constituent of cellular membranes. It has been suggested that cholesterol segregates into sterol-rich and -poor domains in the plasma membrane, although clear evidence for this is lacking. By fluorescence imaging of the natural sterol dehydroergosterol (DHE), the lateral sterol distribution has been visualized in living cells. The spatial labeling pattern of DHE coincided with surface structures such as ruffles, microvilli, and filopodia with correlation lengths in the range of 0.8-2.5 microm. DHE staining of branched tubules and of nanotubes connecting two cells was detected. Dynamics of DHE in folded and plane membrane regions was comparable as determined by fluorescence recovery after photobleaching. DHE colocalized with fluid membrane-preferring phospholipids in surface structures and at sites of cell attachment as well as in the cleavage furrow of dividing cells, but it was not particularly enriched in those regions. Fluorescent sterol showed homogeneous staining in membrane blebs induced by F-actin disruption. Cross-linking the ganglioside GM1--a putative raft marker--did not affect the cell surface distribution of DHE. The results suggest that spatial heterogeneities of plasma membrane staining of DHE resolvable by light microscopy reflect the cell surface topography but not phase-separated sterol domains in the bilayer plane.     

Rapid nonvesicular transport of sterol between the plasma membrane domains of polarized hepatic cells

We studied the transport of the fluorescent cholesterol analog dehydroergosterol (DHE) in polarized HepG2 human hepatoma cells. DHE delivered via methyl-beta-cyclodextrin was delivered to both the apical and basolateral membranes and became concentrated in the apical membrane within 1 min. Intracellular DHE was targeted mainly to vesicles of the subapical compartment or apical recycling compartment (SAC/ARC), where it colocalized with fluorescent transferrin and fluorescent analogs of phosphatidylcholine and sphingomyelin. In contrast, transport of DHE from the plasma membrane to the trans-Golgi network was found to be very low. Vesicles containing DHE traversed the cells in both directions, but vesicular export of DHE from the SAC/ARC to the plasma membrane domains was low. Disruption of the microtubule cytoskeleton disturbed vesicular transport of DHE but not its enrichment in the apical (canalicular) membrane. Transport of DHE to the canalicular membrane after photobleaching was very rapid (t(12) = 1.6 min) and was largely ATP-independent in contrast to enrichment of DHE in the SAC/ARC. Release of DHE from the canalicular membrane was also ATP-independent but slower than the enrichment of sterol in the biliary canaliculus (t(12) = 5.4 min). Canalicular DHE could completely redistribute to the basolateral plasma membrane but could not transfer from one cell to the other cell of an HepG2 couplet. We conclude that sterol shuttles rapidly among the plasma membrane domains and other membrane organelles and that this nonvesicular pathway includes fast transbilayer migration.     

Fluorescence and multiphoton imaging resolve unique structural forms of sterol in membranes of living cells

Although cholesterol is an essential component of mammalian membranes, resolution of cholesterol organization in membranes and organelles (i.e. lysosomes) of living cells is hampered by the paucity of nondestructive, nonperturbing methods providing real time structural information. Advantage was taken of the fact that the emission maxima of a naturally occurring fluorescent sterol (dehydroergosterol) were resolvable into two structural forms, monomeric (356 and 375 nm) and crystalline (403 and 426 nm). Model membranes (sterol:phospholipid ratios in the physiological range, e.g. 0.5-1.0), subcellular membrane fractions (plasma membranes, lysosomal membranes, microsomes, and mitochondrial membranes), and lipid rafts/caveolae (plasma membrane cholesterol-rich microdomain purified by a nondetergent method) contained primarily monomeric sterol and only small quantities (i.e. 1-5%) of the crystalline form. In contrast, the majority of sterol in isolated lysosomes was crystalline. However, addition of sterol carrier protein-2 in vitro significantly reduced the proportion of crystalline dehydroergosterol in the isolated lysosomes. Multiphoton laser scanning microscopy (MPLSM) of living L-cell fibroblasts cultured with dehydroergosterol for the first time provided real time images showing the presence of monomeric sterol in plasma membranes, as well as other intracellular membrane structures of living cells. Furthermore, MPLSM confirmed that crystalline sterol colocalized in highest amounts with LysoTracker Green, a lysosomal marker dye. Although crystalline sterol was also detected in the cytoplasm, the extralysosomal crystalline sterol did not colocalize with BODIPY FL C(5)-ceramide, a Golgi marker, and crystals were not associated with the cell surface membrane. These noninvasive, nonperturbing methods demonstrated for the first time that multiple structural forms of sterol normally occurred within membranes, membrane microdomains (lipid rafts/caveolae), and intracellular organelles of living cells, both in vitro and visualized in real time by MPLSM.     

Structure and cholesterol dynamics of caveolae/raft and nonraft plasma membrane domains

Despite recognition that the plasma membrane (PM) is comprised of lipid raft domains that are key organizing sites of multiple signaling pathways and other cell functions, limited information is available regarding the structure and function in sterol dynamics of these microdomains. To begin to resolve these issues, MDCK membranes were subfractionated by three different techniques to produce (i) detergent-resistant membranes (DRM) and detergent-soluble membranes (DSM), (ii) nondetergent caveolae/rafts (NDCR), and (iii) nondetergent, affinity-purified caveolae/rafts (ACR) and noncaveolae/nonrafts (NR). ACR exhibited the least cross contamination with other PM domains or intracellular membranes, in marked contrast to DRM that contained the highest level of cross contaminants. Spectral properties of dehydroergosterol (DHE), a naturally occurring fluorescent sterol, showed that ACR, NDCR, and NR did not contain crystalline sterol, consistent with the lack of crystalline sterol in PM of intact cells. In contrast, DRM contained significant levels of crystalline sterol. Fluorescence polarization of membrane probes showed that ACR were the least fluid and had the highest transbilayer fluidity gradient, the most liquid ordered phase, and the sterol dynamics most responsive to sterol carrier protein-2 (SCP-2). In contrast, DRM had structural properties similar to those of NR, anomalous (very fast) spontaneous sterol dynamics, and sterol dynamics that were unresponsive to SCP-2. Differences between the structural and functional properties of DRM and those of the nondetergent preparations (ACR and NDCR) were not due to the presence of detergent. A nondetergent, affinity-purified (ACR) lipid domain fraction isolated from MDCK cells for the first time revealed unique structural (noncrystalline sterol, liquid-ordered, high transbilayer fluidity gradient) and functional (cholesterol dynamics) properties of lipid rafts as compared to nonrafts (NR). In summary, this study showed membrane microdomains (rafts/caveolae) isolated by three different methodologies have unique structural, functional, and organizational characteristics.     

Quantitative assessment of sterol traffic in living cells by dual labeling with dehydroergosterol and BODIPY-cholesterol

Cholesterol with BODIPY at carbon-24 of the side chain (BCh2) has recently been introduced as new cholesterol probe with superior fluorescence properties. We compare BCh2 with the intrinsically fluorescent dehydroergosterol (DHE), a well-established marker for cholesterol, by introducing simultaneous imaging of both sterols in model membranes and living cells. BCh2 had a lower affinity than DHE for the biologically relevant liquid-ordered phase in model membranes. Still, DHE and BCh2 trafficked from the plasma membrane to the endocytic recycling compartment (ERC) of BHK cells with identical kinetics. This transport pathway was strongly reduced after energy depletion of cells or expression of the dominant-negative clathrin heavy chain. The partitioning into lipid droplets of BHK and HeLa cells was higher for BCh2 than for DHE. Within droplets, the photodegradation of BCh2 was enhanced and followed a stretched exponential decay, while the fluorescence lifetime of BCh2 was comparable in various cellular regions. Our results indicate that BCh2 is suitable for analyzing sterol uptake pathways and inter-organelle sterol flux in living cells. The BODIPY-moiety affects lipid phase preference of the sterol probe and causes some differential targeting of BCh2 and DHE in cells with high fat content.     

Fluorescent sterols as tools in membrane biophysics and cell biology

Cholesterol is an important constituent of cellular membranes playing a fundamental role in many biological processes. This sterol affects membrane permeability, lateral lipid organization, signal transduction and membrane trafficking. Intracellular sterol transport modes and pathways as well as the regulation of sterol metabolism and disposition in various tissues are areas of intense research. Progress is intimately linked to development and use of appropriate analogs, which closely mimic the properties of cholesterol while allowing to be detected by spectroscopic or microscopic methods. This review provides an overview of various fluorescent sterols used in membrane biophysics and cell biology including analogs of cholesterol and cholesteryl esters. Attention is paid to the natural fluorescent sterol dehydroergosterol (DHE). A survey of the many applications of DHE in biological research is presented. Special emphasis is on recent developments in fluorescence microscopy instrumentation to visualize DHE as an intrinsically fluorescent analog of cholesterol in living cells.     

Ergosterol is mainly located in the cytoplasmic leaflet of the yeast plasma membrane

Transbilayer lipid asymmetry is a fundamental characteristic of the eukaryotic cell plasma membrane (PM). While PM phospholipid asymmetry is well documented, the transbilayer distribution of PM sterols such as mammalian cholesterol and yeast ergosterol is not reliably known. We now report that sterols are asymmetrically distributed across the yeast PM, with the majority (~80%) located in the cytoplasmic leaflet. By exploiting the sterol‐auxotrophic hem1Δ yeast strain we obtained cells in which endogenous ergosterol was quantitatively replaced with dehydroergosterol (DHE), a closely related fluorescent sterol that functionally and accurately substitutes for ergosterol in vivo. Using fluorescence spectrophotometry and microscopy we found that <20% of DHE fluorescence was quenched when the DHE‐containing cells were exposed to membrane‐impermeant collisional quenchers (spin‐labeled phosphatidylcholine and trinitrobenzene sulfonic acid). Efficient quenching was seen only after the cells were disrupted by glass‐bead lysis or repeated freeze‐thaw to allow quenchers access to the cell interior. The extent of quenching was unaffected by treatments that deplete cellular ATP levels, collapse the PM electrochemical gradient or affect the actin cytoskeleton. However, alterations in PM phospholipid asymmetry in cells lacking phospholipid flippases resulted in a more symmetric transbilayer distribution of sterol. Similarly, an increase in the quenchable pool of DHE was observed when PM sphingolipid levels were reduced by treating cells with myriocin. We deduce that sterols comprise up to ~45% of all inner leaflet lipids in the PM, a result that necessitates revision of current models of the architecture of the PM lipid bilayer.      

Osh proteins regulate membrane sterol organization but are not required for sterol movement between the ER and PM

Sterol transport between the endoplasmic reticulum (ER) and plasma membrane (PM) occurs by an ATP-dependent, non-vesicular mechanism that is presumed to require sterol transport proteins (STPs). In Saccharomyces cerevisiae, homologs of the mammalian oxysterol-binding protein (Osh1-7) have been proposed to function as STPs. To evaluate this proposal we took two approaches. First we used dehydroergosterol (DHE) to visualize sterol movement in living cells by fluorescence microscopy. DHE was introduced into the PM under hypoxic conditions and observed to redistribute to lipid droplets on growing the cells aerobically. Redistribution required ATP and the sterol acyltransferase Are2, but did not require PM-derived transport vesicles. DHE redistribution occurred robustly in a conditional yeast mutant (oshΔ osh4-1(ts)) that lacks all functional Osh proteins at 37°C. In a second approach we used a pulse-chase protocol to analyze the movement of metabolically radiolabeled ergosterol from the ER to the PM. Arrival of radiolabeled ergosterol at the PM was assessed in isolated PM-enriched fractions as well as by extracting sterols from intact cells with methyl-β-cyclodextrin. These experiments revealed that whereas ergosterol is transported effectively from the ER to the PM in Osh-deficient cells, the rate at which it moves within the PM to equilibrate with the methyl-β-cyclodextrin extractable sterol pool is slowed. We conclude (i) that the role of Osh proteins in non-vesicular sterol transport between the PM, ER and lipid droplets is either minimal, or subsumed by other mechanisms and (ii) that Osh proteins regulate the organization of sterols at the PM.     

Fluorescent sterols monitor cell penetrating peptide Pep-1 mediated uptake and intracellular targeting of cargo protein in living cells

Although cell-penetrating peptides (CPP) facilitate endocytic uptake of proteins, little is known regarding the extent to which CPPs facilitate protein cargo exit from endocytic vesicles for targeting to other intracellular sites. Since the plasma membrane and less so intracellular membranes contain cholesterol, the fluorescent sterol analogues dansyl-cholestanol (DChol) and dehydroergosterol (DHE) were used to monitor the uptake and intracellular distribution of fluorescent-tagged acyl coenzyme A binding protein (ACBP) into COS-7 cells and rat hepatoma cells. Confocal microscopy colocalized DChol and Texas Red-ACBP (TR-ACBP) with markers for the major endocytosis pathways, especially fluorescent-labeled cholera toxin (marker of ganglioside GM1 in plasma membrane lipid rafts) and dextran (macropinocytosis marker), but less so with transferrin (clathrin-mediated endocytosis marker). These findings were confirmed by multiphoton laser scanning microscopy colocalization of TR-ACBP with DHE (naturally-fluorescent sterol) and by double immunofluorescence labeling of native endogenous ACBP. Serum greatly and Pep-1 further 2.4-fold facilitated uptake of TR-ACBP, but neither altered the relative proportion of TR-ACBP colocalized with membranes/organelles (nearly 80%) vs cytoplasm and/or nucleoplasm (20%). Interestingly, Pep-1 selectively increased TR-ACBP associated with mitochondria while concomitantly decreasing that in endoplasmic reticulum. In summary, fluorescent sterols (DChol, DHE) were useful markers for comparing the distributions of both transported and endogenous proteins. Pep-1 modestly enhanced the translocation and altered the intracellular targeting of exogenous-delivered (TR-ACBP) in living cells.     

Direct observation of rapid internalization and intracellular transport of sterol by macrophage foam cells

Transport of the fluorescent cholesterol analog dehydroergosterol (DHE) from the plasma membrane was studied in J774 macrophages (Mphis) with normal and elevated cholesterol content. Cells were labeled with DHE bound to methyl-beta-cyclodextrin. In J774, Mphis with normal cholesterol, intracellular DHE became enriched in recycling endosomes, but was not highly concentrated in the trans-Golgi network or late endosomes and lysosomes. After raising cellular cholesterol by incubation with acetylated low-density lipoprotein (AcLDL), DHE was transported to lipid droplets, and less sterol was found in recycling endosomes. Transport of DHE to droplets was very rapid (t1/2 = 1.5 min after photobleaching) and did not require metabolic energy. In cholesterol-loaded J774 Mphis, the initial fraction of DHE in the plasma membrane was reduced, and rapid DHE efflux from the plasma membrane to intracellular organelles was observed. This rapid sterol transport was not related to plasma membrane vesiculation, as DHE did not become enriched in endocytic vesicles formed after sphingomyelinase C treatment of cells. When cells were incubated with DHE ester incorporated into AcLDL, fluorescence of the sterol was first found in punctate endosomes. After a chase, this DHE colocalized with transferrin in a distribution similar to cells labeled with DHE delivered by methyl-beta-cyclodextrin. Our results indicate that elevation of sterol levels in Mphis enhances transport of sterol from the plasma membrane by a non-vesicular pathway.     

Role of sterol superlattice in free radical-induced sterol oxidation in lipid membranes

We developed a new fluorescence assay for sterol oxidation and used it to study the relationship between free radical-induced sterol oxidation and membrane sterol lateral organization. This assay used dehydroergosterol (DHE) as both a membrane probe and a membrane component. Sterol oxidation was induced by a free radical generator, AAPH (2,2'-azobis(2-amidinopropane)dihydrochloride). Using this new assay, we found that, in unilamellar vesicles composed of DHE and 1-palmitoyl-2-oleoyl-l-alpha-phosphatidylcholine (POPC), the initial rate of DHE oxidation induced by AAPH changed with membrane sterol content in an alternating manner, exhibiting a local maximum at 20.3, 22.2, 25.0, 32.3, and 40.0 mol % DHE. These mole fractions correspond to the critical sterol mole fractions C(r) predicted for maximal sterol superlattice formation. In three-component bilayers composed of POPC, cholesterol, and DHE (fixed at 1 and 5 mol %), the initial rate of AAPH-induced DHE oxidation exhibited a biphasic change whenever the total sterol mole fraction, irrespective of the DHE content, was near C(r), indicating that the correlation between sterol oxidation and sterol superlattice formation revealed in this study is not an artifact due to the use of the fluorescent cholesterol analogue DHE. The alternating variation of AAPH-induced sterol oxidation with sterol content also appeared in multicomponent unilamellar vesicles containing bovine brain sphingomyelins (bbSPM), POPC, and DHE. The present work and our previous study on cholesterol oxidase-induced sterol oxidation [Wang et al. (2004) Biochemistry 43, 2159-2166] suggest that sterol oxidation in general, either by reactive oxygen species or by enzymes, may be regulated by the extent of sterol superlattice in the membrane and thus regulated by the membrane sterol content in a fine-tuning manner.     

Arv1 Regulates PM and ER Membrane Structure and Homeostasis But is Dispensable for Intracellular Sterol Transport

The pan‐eukaryotic endoplasmic reticulum (ER) membrane protein Arv1 has been suggested to play a role in intracellular sterol transport. We tested this proposal by comparing sterol traffic in wild‐type and Arv1‐deficient Saccharomyces cerevisiae. We used fluorescence microscopy to track the retrograde movement of exogenously supplied dehydroergosterol (DHE) from the plasma membrane (PM) to the ER and lipid droplets and high performance liquid chromatography to quantify, in parallel, the transport‐coupled formation of DHE esters. Metabolic labeling and subcellular fractionation were used to assay anterograde transport of ergosterol from the ER to the PM. We report that sterol transport between the ER and PM is unaffected by Arv1 deficiency. Instead, our results indicate differences in ER morphology and the organization of the PM lipid bilayer between wild‐type and arv1Δ cells suggesting a distinct role for Arv1 in membrane homeostasis. In arv1Δ cells, specific defects affecting single C‐terminal transmembrane domain proteins suggest that Arv1 might regulate membrane insertion of tail‐anchored proteins involved in membrane homoeostasis .     

WIF-B cells: an in vitro model for studies of hepatocyte polarity

We have evaluated the utility of the hepatoma-derived hybrid cell line, WIF-B, for in vitro studies of polarized hepatocyte functions. The majority (> 70%) of cells in confluent culture formed closed spaces with adjacent cells. These bile canalicular-like spaces (BC) accumulated fluorescein, a property of bile canaliculi in vivo. By indirect immunofluorescence, six plasma membrane (PM) proteins showed polarized distributions similar to rat hepatocytes in situ. Four apical PM proteins were concentrated in the BC membrane of WIF-B cells. Microtubules radiated from the BC (apical) membrane, and actin and foci of gamma-tubulin were concentrated in this region. The tight junction- associated protein ZO-1 was present in belts marking the boundary between apical and basolateral PM domains. We explored the functional properties of this boundary in living cells using fluorescent membrane lipid analogs and soluble tracers. When cells were incubated at 4 degrees C with a fluorescent analog of sphingomyelin, only the basolateral PM was labeled. In contrast, when both PM domains were labeled by de novo synthesis of fluorescent sphingomyelin from ceramide, fluorescent lipid could only be removed from the basolateral domain. These data demonstrate the presence of a barrier to the lateral diffusion of lipids between the PM domains. However, small soluble FITC- dextrans (4,400 mol wt) were able to diffuse into BC, while larger FITC- dextrans were restricted to various degrees depending on their size and incubation temperature. At 4 degrees C, the surface labeling reagent sNHS-LC-biotin (557 mol wt) had access to the entire PM, but streptavidin (60,000 mol wt), which binds to biotinylated molecules, was restricted to only the basolateral domain. Such differential accessibility of well-characterized probes can be used to mark each membrane domain separately. These results show that WIF-B cells are a suitable model to study membrane trafficking and targeting in hepatocytes in vitro.     

The role of ABC proteins Aus1p and Pdr11p in the uptake of external sterols in yeast: dehydroergosterol fluorescence study

Uptake of external sterols in the yeast Saccharomyces cerevisiae is a multistep process limited to anaerobiosis or heme deficiency. It includes crossing the cell wall, insertion of sterol molecules into plasma membrane and their internalization and integration into intracellular membranes. We applied the fluorescent ergosterol analog dehydroergosterol (DHE) to monitor the initial steps of sterol uptake by three independent approaches: fluorescence spectroscopy, fluorescence microscopy and sterol quantification by HPLC. Using specific fluorescence characteristics of DHE we showed that the entry of sterol molecules into plasma membrane is not spontaneous but requires assistance of two ABC (ATP-binding cassette) pumps – Aus1p or Pdr11p. DHE taken up by uptake-competent hem1ΔAUS1PDR11 cells could be directly visualized by UV-sensitive wide field fluorescence microscopy. HPLC analysis of sterols revealed significant amounts of exogenous ergosterol and DHE (but not cholesterol) associated with uptake-deficient hem1Δaus1Δpdr11Δ cells. Fluorescent sterol associated with these cells did not show the characteristic emission spectrum of membrane-integrated DHE. The amount of cell-associated DHE was significantly reduced after enzymatic removal of the cell wall. Our results demonstrate that the yeast cell wall is actively involved in binding and uptake of ergosterol-like sterols.     

Elastic membrane heterogeneity of living cells revealed by stiff nanoscale membrane domains

Many approaches have been developed to characterize the heterogeneity of membranes in living cells. In this study, the elastic properties of specific membrane domains in living cells are characterized by atomic force microscopy. Our data reveal the existence of heterogeneous nanometric scale domains with specific biophysical properties. We focused on glycosylphosphatidylinositol (GPI)-anchored proteins, which play an important role in membrane trafficking and cell signaling under both physiological and pathological conditions and which are known to partition preferentially into cholesterol-rich microdomains. We demonstrate that these GPI-anchored proteins reside within domains that are stiffer than the surrounding membrane. In contrast, membrane domains containing the transferrin receptor, which does not associate with cholesterol-rich regions, manifest no such feature. The heightened stiffness of GPI domains is consistent with existing data relating to the specific condensation of lipids and the slow diffusion rates of lipids and proteins therein. Our quantitative data may forge the way to unveiling the links that exist between membrane stiffness, molecular diffusion, and signaling activation.     

Biotinylated theta-toxin derivative as a probe to examine intracellular cholesterol-rich domains in normal and Niemann-Pick type C1 cells

BCtheta is a proteolytically nicked and biotinylated derivative of a cholesterol binding protein perfringolysin O (theta-toxin), and has been used to detect cholesterol-rich domains at the plasma membrane (PM). Here we show that by modifying the cell fixation condition, BCtheta can also be used to detect cholesterol-rich domains intracellularly. When cells were processed for PM cholesterol staining, the difference in BCtheta signals between the CT43 (CT) cell, a mutant Chinese hamster ovary cell line lacking the Niemann-Pick type C1 (NPC1) protein, and its parental cell 25RA (RA) was minimal. However, when cells were fixed with 4% paraformaldehyde, they became permeable to BCtheta. Under this condition, BCtheta mainly stained cholesterol-rich domains inside the cells, with the signal being much stronger in CT cells than in RA cells. The sensitivity of BCtheta staining was superior to that of filipin staining. The staining of cholesterol-rich domain(s) inside RA cells was sensitive to beta-cyclodextrin treatment, while most of the staining inside CT cells was relatively resistant to cyclodextrin treatment. Clear differences in intracellular BCtheta staining were also seen between the normal and mutant NPC1 fibroblasts of human or mouse origin. Thus, BCtheta is a powerful tool for visually monitoring cholesterol-rich domains inside normal and NPC cells.     

Selective Visualization of Fluorescent Sterols in Caenorhabditis elegans by Bleach‐Rate‐Based Image Segmentation

The nematode Caenorhabditis elegans is a genetically tractable model organism to investigate sterol transport. In vivo imaging of the fluorescent sterol, dehydroergosterol (DHE), is challenged by C. elegans’ high autofluorescence in the same spectral region as emission of DHE. We present a method to detect DHE selectively, based on its rapid bleaching kinetics compared to cellular autofluorescence. Worms were repeatedly imaged on an ultraviolet‐sensitive wide field (UV‐WF) microscope, and bleaching kinetics of DHE were fitted on a pixel‐basis to mathematical models describing the intensity decay. Bleach‐rate constants were determined for DHE in vivo and confirmed in model membranes. Using this method, we could detect enrichment of DHE in specific tissues like the nerve ring, the spermateca and oocytes. We confirm these results in C. elegans gut‐granule‐loss (glo) mutants with reduced autofluorescence and compare our method with three‐photon excitation microscopy of sterol in selected tissues. Bleach‐rate‐based UV‐WF imaging is a useful tool for genetic screening experiments on sterol transport, as exemplified by RNA interference against the rme‐2 gene coding for the yolk receptor and for worm homologues of Niemann‐Pick C disease proteins. Our approach is generally useful for identifying fluorescent probes in the presence of high cellular autofluorescence.     

Membrane cholesterol dynamics: cholesterol domains and kinetic pools

Nonreceptor mediated cholesterol uptake and reverse cholesterol transport in cells occur through cellular membranes. Thus, elucidation of cholesterol dynamics in membranes is essential to understanding cellular cholesterol accumulation and loss. To this end, it has become increasingly evident that cholesterol is not randomly distributed in either model or biologic membranes. Instead, membrane cholesterol appears to be organized into structural and kinetic domains or pools. Cholesterol-rich and poor domains can even be observed histochemically and physically isolated from epithelial cell surface membranes. The physiologic importance of these domains is 2-fold: (i) Select membrane proteins (receptors, transporters, etc.) are localized in either cholesterol-rich or cholesterol-poor domains. Consequently, the structure and properties of the domains rather than of the bulk lipid may selectively affect the function of proteins residing therein. (ii) Kinetic evidence suggests that cholesterol transport through and between membranes may occur through specific domains or pools. Regulation of the size and properties of such domains may be controlling factors of cholesterol transport or accumulation in cells. Recent technologic advances in the use of fluorescent sterols have allowed examination of cholesterol domain structure in model and biologic membranes. These techniques have been applied to examine the role of high-density lipoprotein, cholesterol lowering drugs, and intracellular lipid transfer proteins in membrane sterol domain structure and sterol movement between membranes.     

BODIPY-cholesterol: a new tool to visualize sterol trafficking in living cells and organisms

Analysis of sterol distribution and transport in living cells has been hampered by the lack of bright, photostable fluorescent sterol derivatives that closely resemble cholesterol. In this study, we employed atomistic simulations and experiments to characterize a cholesterol compound with fluorescent boron dipyrromethene difluoride linked to sterol carbon-24 (BODIPY-cholesterol). This probe packed in the membrane and behaved similarly to cholesterol both in normal and in cholesterol-storage disease cells and with trace amounts allowed the visualization of sterol movement in living systems. Upon injection into the yolk sac, BODIPY-cholesterol did not disturb zebrafish development and was targeted to sterol-enriched brain regions in live fish. We conclude that this new probe closely mimics the membrane partitioning and trafficking of cholesterol and, because of its excellent fluorescent properties, enables the direct monitoring of sterol movement by time-lapse imaging using trace amounts of the probe. This is, to our knowledge, the first cholesterol probe that fulfills these prerequisites.