Role Of Caveolae Research Articles

Caveolae couple mechanical stress to integrin recycling and activation.

Cells are subjected to multiple mechanical inputs throughout their lives. Their ability to detect these environmental cues is called mechanosensing, a process in which integrins play an important role. During cellular mechanosensing, plasma membrane (PM) tension is adjusted to mechanical stress through the buffering action of caveolae; however, little is known about the role of caveolae in early integrin mechanosensing regulation. Here, we show that Cav1KO fibroblasts increase adhesion to FN-coated beads when pulled with magnetic tweezers, as compared to wild type fibroblasts. This phenotype is Rho-independent and mainly derived from increased active β1-integrin content on the surface of Cav1KO fibroblasts. Florescence recovery after photobleaching analysis and endocytosis/recycling assays revealed that active β1-integrin is mostly endocytosed through the clathrin independent carrier/glycosylphosphatidyl inositol (GPI)-enriched endocytic compartment pathway and is more rapidly recycled to the PM in Cav1KO fibroblasts, in a Rab4 and PM tension-dependent manner. Moreover, the threshold for PM tension-driven β1-integrin activation is lower in Cav1KO mouse embryonic fibroblasts (MEFs) than in wild type MEFs, through a mechanism dependent on talin activity. Our findings suggest that caveolae couple mechanical stress to integrin cycling and activation, thereby regulating the early steps of the cellular mechanosensing response.

Caveolae promote successful abscission by controlling intercellular bridge tension during cytokinesis.

During cytokinesis, the intercellular bridge (ICB) connecting the daughter cells experiences pulling forces, which delay abscission by preventing the assembly of the ESCRT scission machinery. Abscission is thus triggered by tension release, but how ICB tension is controlled is unknown. Here, we report that caveolae, which are known to regulate membrane tension upon mechanical stress in interphase cells, are located at the midbody, at the abscission site, and at the ICB/cell interface in dividing cells. Functionally, the loss of caveolae delays ESCRT-III recruitment during cytokinesis and impairs abscission. This is the consequence of a twofold increase of ICB tension measured by laser ablation, associated with a local increase in myosin II activity at the ICB/cell interface. We thus propose that caveolae buffer membrane tension and limit contractibility at the ICB to promote ESCRT-III assembly and cytokinetic abscission. Together, this work reveals an unexpected connection between caveolae and the ESCRT machinery and the first role of caveolae in cell division.

Membrane tension buffering by caveolae: a role in cancer?

Caveolae are bulb-like invaginations made up of two essential structural proteins, caveolin-1 and cavins, which are abundantly present at the plasma membrane of vertebrate cells. Since their discovery more than 60years ago, the function of caveolae has been mired in controversy. The last decade has seen the characterization of new caveolae components and regulators together with the discovery of additional cellular functions that have shed new light on these enigmatic structures. Early on, caveolae and/or caveolin-1 have been involved in the regulation of several parameters associated with cancer progression such as cell migration, metastasis, angiogenesis, or cell growth. These studies have revealed that caveolin-1 and more recently cavin-1 have a dual role with either a negative or a positive effect on most of these parameters. The recent discovery that caveolae can act as mechanosensors has sparked an array of new studies that have addressed the mechanobiology of caveolae in various cellular functions. This review summarizes the current knowledge on caveolae and their role in cancer development through their activity in membrane tension buffering. We propose that the role of caveolae in cancer has to be revisited through their response to the mechanical forces encountered by cancer cells during tumor mass development.

Obligatory roles of caveolae in excitation-transcription coupling in vascular smooth muscle cells.

Obligatory roles of caveolae in excitation-transcription coupling in vascular smooth muscle cells.

Caveolae: Structure, Function, and Relationship to Disease.

The plasma membrane of eukaryotic cells is not a simple sheet of lipids and proteins but is differentiated into subdomains with crucial functions. Caveolae, small pits in the plasma membrane, are the most abundant surface subdomains of many mammalian cells. The cellular functions of caveolae have long remained obscure, but a new molecular understanding of caveola formation has led to insights into their workings. Caveolae are formed by the coordinated action of a number of lipid-interacting proteins to produce a microdomain with a specific structure and lipid composition. Caveolae can bud from the plasma membrane to form an endocytic vesicle or can flatten into the membrane to help cells withstand mechanical stress. The role of caveolae as mechanoprotective and signal transduction elements is reviewed in the context of disease conditions associated with caveola dysfunction.

A Deeper Look into the Cellular Caves: Caveolins, Cavins and Popdc Proteins in Cardioprotection

Cardioprotection is a promising novel therapeutic approach for the treatment ofischemic heart disease (IHD). Various cardioprotective methods such as ischemic,anesthetic and G-protein-coupled-receptor (GPCR) based preconditioning have beenshown to be reliant on the presence of unique regions in the sarcolemma termed caveolae.Caveolae compartmentalize and concentrate various classes of signaling moleculesinvolved in stress-resistance, including important mediators of cardioprotection such asreceptor tyrosine kinases, GPCRs and their subunits. The unique morphology ofcaveolae arises from the expression of its coat proteins belonging to those of caveolin,cavin and Popeye domain-containing (Popdc) family of proteins. As outlined in thisreview, although contributions of caveolins (especially Caveolin-3) in cardioprotectionare relatively well-characterized, recent studies indicate that members of the cavins andthe Popdc family of proteins are also crucial for sarcolemmal caveolae formation, animportant determinant of ischemia-reperfusion (I-R) injury. In this article, we discussthe evidence for the involvement of caveolins, cavins and Popdc family of proteins incardioprotective signaling and the essential role of caveolae in age-related reduction ofcardioprotective signaling. Age-related changes in sarcolemmal makeup as evidencedby down-regulation of caveolins in several types of tissues is linked to decreased stress-resistance, and may help partially explain the refractoriness to protective stimuliin the aging heart. Hence, a greater understanding of the role of caveolae and its coatproteins as briefly outlined here may help facilitate the development of cardioprotectivestrategies as despite the decades of research, currently there are no effective treatmentsfor limiting I-R injury. Since many of the existing experimental cardioprotectiveinterventions such as the clinically feasible post-conditioning method is reliant oncaveolae, methods that enhance or restore caveolae in the aged heart may be a viabletherapeutic strategy for the treatment ischemic heart disease.

Abstract A18: Epigenetic profiling uncovers the suppressive role of caveolae in Ewing sarcoma

Abstract Ewing sarcoma (ES) is the second most common bone tumor in childhood. ES harbors a characteristic gene translocation that gives rise to a fusion protein, most commonly EWS/FLI1 (EF). Caveolin-1 (CAV1) is a direct target of EF, it is overexpressed in ES and has an oncogenic role. CAV1 and the Polymerase I and transcript release factor (PTRF) interact at the plasma membrane and are essential for caveolae formation. The methylome analysis of ES samples and cell lines revealed a hypermethylation in the N-shore islands of the PTRF promoter compared to normal cells. We hypothesize that, as ES cells have very few caveolae and do not express PTRF, the oncogenic role of CAV1 in ES would be driven by the impossibility of being recruited at caveolae. Epigenetic silencing of PTRF was confirmed by bisulfite genomic sequencing on ES cells and human samples. We verified that ES cells do not express PTRF by western blot. Demethylating agent 5-aza (decitabine) treatment of A673 cells resulted in re-expression of PTRF and enhancement of caveolae formation as shown by electron microscopy. Immunofluorescent imaging in TC252 cells stably transfected with PTRF showed co-localization with CAV1 at the plasma membrane. Immunoprecipitation assays also confirmed their interaction. PTRF transfection in TC252 cells promoted an increase in cell death up to 50% in a caspase-3 dependent way. Furthermore, PTRF-expressing xenografts had a lower capacity to form tumors compared to controls. CAV1-PTRF pro-apoptotic interaction was verified also in EW7 cells. These results pointed that CAV1-PTRF interaction and caveolae formation promote cell death in ES cells. The presence of caveolae has been related with stress and p53 activation, due to the MDM2 binding to CAV1, that causes the release and activation of p53. To elucidate the role of p53 in the PTRF-mediated cell death, PTRF-transfected TC252 cells were treated with a p53 siRNA and cell death was significantly reduced. Our results suggest that PTRF acts as a tumor suppressor in ES. PTRF re-expression enhances caveolae formation in ES cells, thus modulating CAV1 localization that results in p53-mediated cell death. Citation Format: Juan Huertas-Martínez, Frank Court, Santiago Rello-Varona, David Herrero Martin, Olga Almacellas, Miguel Sáinz-Jaspeado, Silvia Garcia-Monclús, Laura Lagares-Tena, Raqeul Buj, Lourdes Hontecillas-Prieto, Silvia Mateo-Lozano, Ana Sastre, Daniel Azorín, Jaune Mora, Josep Roma, Sebastian Moran, Soledad Gallego, Miguel Angel Peinado, Xavier Garcia del Muro, Javier Alonso, Enrique de Alava, Dave Monk, Manel Esterller, Oscar M Tirado. Epigenetic profiling uncovers the suppressive role of caveolae in Ewing sarcoma. [abstract]. In: Proceedings of the AACR Special Conference on Advances in Pediatric Cancer Research: From Mechanisms and Models to Treatment and Survivorship; 2015 Nov 9-12; Fort Lauderdale, FL. Philadelphia (PA): AACR; Cancer Res 2016;76(5 Suppl):Abstract nr A18.

Caveolae Restrict Tiger Frog Virus Release in HepG2 cells and Caveolae-Associated Proteins Incorporated into Virus Particles.

Caveolae are flask-shaped invaginations of the plasma membrane. Caveolae play important roles in the process of viruses entry into host cells, but the roles of caveolae at the late stage of virus infection were not completely understood. Tiger frog virus (TFV) has been isolated from the diseased tadpoles of the frog, Rana tigrina rugulosa, and causes high mortality of tiger frog tadpoles cultured in Southern China. In the present study, the roles of caveolae at the late stage of TFV infection were investigated. We showed that TFV virions were localized with the caveolae at the late stage of infection in HepG2 cells. Disruption of caveolae by methyl-β-cyclodextrin/nystatin or knockdown of caveolin-1 significantly increase the release of TFV. Moreover, the interaction between caveolin-1 and TFV major capsid protein was detected by co-immunoprecipitation. Those results suggested that caveolae restricted TFV release from the HepG2 cells. Caveolae-associated proteins (caveolin-1, caveolin-2, cavin-1, and cavin-2) were selectively incorporated into TFV virions. Different combinations of proteolytic and/or detergent treatments with virions showed that caveolae-associated proteins were located in viral capsid of TFV virons. Taken together, caveolae might be a restriction factor that affects virus release and caveolae-associated proteins were incorporated in TFV virions.

Caveolae regulate vasoconstriction of conduit arteries to angiotensin II in hindlimb unweighted rats.

Weightlessness induces the functional remodelling of arteries, but the changes to angiotensin II (Ang II)-elicited vasoconstriction and the underlying mechanism have never been reported. Caveolae are invaginations of the cell membrane crucial for the contraction of vascular smooth muscle cells, so we investigated the adaptation of Ang II-elicited vasoconstriction to simulated weightlessness and the role of caveolae in it. The 4 week hindlimb unweighted (HU) rat was used to simulate the effects of weightlessness. Ang II-elicited vasoconstriction was measured by isometric force recording. The morphology of caveolae was examined by transmission electron microscope. The binding of the angiotensin II type 1 receptor (AT1 ) and caveolin-1 (cav-1) was examined by coimmunoprecipitation and Western blot. We found that the maximal developing force (E(max)) of Ang II-elicited vasoconstriction was decreased in abdominal aorta by 30.6%, unchanged in thoracic aorta and increased in carotid artery by 17.9% after HU, while EC50 of the response was increased in all three arteries (P < 0.05). AT1 desensitization upon activation was significantly reduced by HU in all three arteries, as was the number of caveolae (P < 0.05). Furthermore, Ang II promoted the binding of AT1 and cav-1 significantly in control but not HU arteries. Both the number of caveolae and the binding of AT1 and cav-1 in HU arteries were restored by cholesterol pretreatment which also reinstated the change in EC50 as well as the level of AT1 desensitization. These results indicate that modified caveolae in vascular smooth muscle cells could interfere with the binding of AT1 and cav-1 mediating the adaptation of Ang II-elicited vasoconstriction to HU.

Caveolae are involved in stretch-induced Ca2+ signaling in pulmonary hypertension

Introduction Vascular smooth muscle cells are submitted to stretch forces exerted by the blood pressure. Pulmonary arteries can transduce a mechanical stimulus of stretch into a biological response of contraction, a mechanism called myogenic tone, which involves plasma membrane Ca 2+ stretch-activated channels (SAC). As membrane plasticity and shape are important for the SAC activity, we investigate the involvement of caveolae in the Ca 2+ and contraction response to stretch of pulmonary arterial smooth muscle cells (PA-SMC). Methods Isometric contractions were performed in pulmonary arterial vessels from normoxic rats (Nx rats) and rats with a pulmonary hypertension induced by a chronic hypoxia of 3 weeks (CH rats). Inward currents from SAC were recorded on freshly isolated PA-SMC after a negative pressure applied by a patch-clamp pipette and Ca 2+ variations were simultaneously recorded with the fluorescent probe indo-1. Sarcoplasmic reticulum Ca 2+ was measured by a confocal microscope with the fluo-5N probe. Finally, a pharmacological approach using methyl-β-cyclodextrin (MβCD, a caveolae disrupter) coupled with different immunolabelings of caveolin-1 and sarcoplasmic Ca 2+ stores were used to investigate the role of caveolae. Results We show that caveolae are present and caveolin-1 expressed in PA-SMC from both normal and pulmonary hypertensive rats. Isolated PA-SMC and pulmonary arteries exhibit a higher SAC activity, Ca 2+ response and contraction to stretch in CH rats than in Nx rats. These responses are reduced by MβCD only in CH rats. In the absence of extracellular calcium, a stretch induces a Ca 2+ and contraction response only in CH rats but not in Nx rats. This phenomenon involves a Ca 2+ release from the sarcoplasmic reticulum and is fully inhibited by MβCD. Conclusion Caveolae are important for stretch-induced calcium response in CH rats via a new subcellular organization between caveolae and intracellular calcium stores.

Signaling Epicenters: The Role of Caveolae and Caveolins in Volatile Anesthetic Induced Cardiac Protection

Caveolae are flask-like invaginations of the cell surface that have been identified as signaling epicenters. Within these microdomains, caveolins are structural proteins of caveolae, which are able to interact with numerous signaling molecules affecting temporal and spatial dimensions required in cardiac protection. This complex moiety is essential to the mechanisms involved in volatile anesthetics. In this review we will outline a general overview of caveolae and caveolins and their role in protective signaling with a focus on the effects of volatile anesthetics. These recent developments have allowed us to better understand the mechanistic effect of volatile anesthetics and their potential in cardiac protection.

Caveolin contributes to the modulation of basal and β-adrenoceptor stimulated function of the adult rat ventricular myocyte by simvastatin: a novel pleiotropic effect.

The number of people taking statins is increasing across the globe, highlighting the importance of fully understanding statins' effects on the cardiovascular system. The beneficial impact of statins extends well beyond regression of atherosclerosis to include direct effects on tissues of the cardiovascular system (‘pleiotropic effects’). Pleiotropic effects on the cardiac myocyte are often overlooked. Here we consider the contribution of the caveolin protein, whose expression and cellular distribution is dependent on cholesterol, to statin effects on the cardiac myocyte. Caveolin is a structural and regulatory component of caveolae, and is a key regulator of cardiac contractile function and adrenergic responsiveness. We employed an experimental model in which inhibition of myocyte HMG CoA reductase could be studied in the absence of paracrine influences from non-myocyte cells. Adult rat ventricular myocytes were treated with 10 µM simvastatin for 2 days. Simvastatin treatment reduced myocyte cholesterol, caveolin 3 and caveolar density. Negative inotropic and positive lusitropic effects (with corresponding changes in [Ca2+]i) were seen in statin-treated cells. Simvastatin significantly potentiated the inotropic response to β2-, but not β1-, adrenoceptor stimulation. Under conditions of β2-adrenoceptor stimulation, phosphorylation of phospholamban at Ser16 and troponin I at Ser23/24 was enhanced with statin treatment. Simvastatin increased NO production without significant effects on eNOS expression or phosphorylation (Ser1177), consistent with the reduced expression of caveolin 3, its constitutive inhibitor. In conclusion, statin treatment can reduce caveolin 3 expression, with functional consequences consistent with the known role of caveolae in the cardiac cell. These data are likely to be of significance, particularly during the early phases of statin treatment, and in patients with heart failure who have altered β-adrenoceptor signalling. In addition, as caveolin is ubiquitously expressed and has myriad tissue-specific functions, the impact of statin-dependent changes in caveolin is likely to have many other functional sequelae.

IGF-IR internalizes with CAVEOLIN-1 and PTRF/CAVIN in HACAT cells

Background: Insulin-like growth factor-I receptor (IGF-IR) is a tyrosine kinase receptor (RTK) associated with caveolae, invaginations of the plasma membrane that regulate vesicular transport, endocytosis and intracellular signaling. IGF-IR internalization represents a key mechanism of down-modulation of receptors number on plasma membrane. IGF-IR interacts directly with Caveolin-1 (Cav-1), the most relevant protein of caveolae. Recently it has been demonstrated that the Polymerase I and Transcript Release Factor I (PTRF/Cavin) is required for caveolae biogenesis and function. The role of Cav-1 and PTRF/Cavin in IGF-IR internalization is still to be clarified. Methodology/Principal Findings: We have investigated the interaction of IGF-IR with Cav-1 and PTRF/Cavin in the presence of IGF1in human Hacat cells. We show that IGF-IR internalization triggers Cav-1 and PTRF/Cavin translocation from plasma membrane to cytosol and increases IGF-IR interaction with these proteins. In fact, Cav-1 and PTRF/Cavin coimmunoprecipitate with IGF-IR during receptor internalization. We found a different time course of co-immunoprecipitation between IGF-IR and Cav-1 compared to IGF-IR and PTRF/Cavin. Cav-1 and PTRF/Cavin silencing by siRNA differently affect surface IGF-IR levels following IGF1 treatment: Cav-1 and PTRF/Cavin silencing significantly affect IGF-IR rate of internalization, while PTRF/Cavin silencing also decreases IGF-IR plasma membrane recovery. Since Cav-1 phosphorylation could have a role in IGF-IR internalization, the mutant Cav-1Y14F lacking Tyr14 was transfected. Cav-1Y14F transfected cells showed a reduced internalization of IGF-IR compared with cells expressing wild type Cav-1. Receptor internalization was not impaired by Clathrin silencing. These findings support a critical role of caveolae in IGF-IR intracellular traveling. Conclusions/Significance: These data indicate that Caveolae play a role in IGF-IR internalization. Based on these findings, Cav-1 and PTRF/Cavin could represent two relevant and distinct targets to modulate IGF-IR function.

Role of caveolae in shear stress-mediated endothelium-dependent dilation in coronary arteries

Caveolae are membrane microdomains where important signalling pathways are assembled and molecular effects transduced. In this study, we hypothesized that shear stress-mediated vasodilation (SSD) of mouse small coronary arteries (MCA) is caveolae-dependent. MCA (80-150 μm) isolated from wild-type (WT) and caveolin-1 null (Cav-1(-/-)) mice were subjected to physiological levels of shear stress (1-25 dynes/cm(2)) with and without pre-incubation of inhibitors of nitric oxide synthase (L-NAME), cyclooxygenase (indomethacin, INDO), or cytochrome P450 epoxygenase (SKF 525A). SSD was endothelium-dependent in WT and Cav-1(-/-) coronaries but that in Cav-1(-/-) was significantly diminished compared with WT. Pre-incubation with L-NAME, INDO, or SKF 525A significantly reduced SSD in WT but not in Cav-1(-/-) mice. Vessels from the soluble epoxide hydrolase null (Ephx2(-/-)) mice showed enhanced SSD, which was further augmented by the presence of arachidonic acid. In donor-detector-coupled vessel experiments, Cav-1(-/-) donor vessels produced diminished dilation in WT endothelium-denuded detector vessels compared with WT donor vessels. Shear stress elicited a robust intracellular Ca(2+) increase in vascular endothelial cells isolated from WT but not those from Cav-1(-/-) mice. Integrity of caveolae is critical for endothelium-dependent SSD in MCA. Cav-1(-/-) endothelium is deficient in shear stress-mediated generation of vasodilators including NO, prostaglandins, and epoxyeicosatrienoic acids. Caveolae plays a critical role in endothelial signal transduction from shear stress to vasodilator production and release.

The role of caveolae in regulating calcitonin receptor-like receptor subcellular distribution in vascular smooth muscle cells

To determine whether caveolae and caveolin-1 affect the distribution of calcitonin receptor-like receptors (CLR) in vascular smooth muscle cell (VSMC) membranes, we have used VSMCs cell line A10. We found that calcitonin gene-related peptide (CGRP) reduced CLR protein in the VSMC membrane in a time-dependent manner, which was dramatically decreased after 4 h CGRP treatment, and remained at a low level after 16 h. CGRP8-37 or β-cyclodextrin (β-CD) blocked this effect, without changing the total levels of CLR protein and mRNA in the cells. Co-immunoprecipitation experiments showed that CLR bound to caveolin-1 in cell membrane fractions. Confocal laser microscopic studies confirmed this co-localization relationship at the cell plasma membrane. Thus, our data indicate that the structural integrity of caveolae plays an important role in regulating subcellular distribution of CLR.

Inhibitory Effects of CGRP on Vascular Smooth Muscle Cell Proliferation: Role of Caveolae/caveolin-1/ERK 1/2 Signal Pathway

Caveolae and caveolin-1 participate in the transportation of cholesterol and cell signal transduction.Our previous studies showed that the inhibitory effect of calcitonin gene-related peptide(CGRP) on the vascular smooth muscle cells(VSMCs) was related to decreasing the activity of extracellular signal-regulated kinase(ERK) 1/2 and increasing the expression of caveolin-1.In the present study,we investigated the role of caveolae and caveolin-1 in proliferation of VSMCs and whether there are interaction between the caveolin-1 and ERK 1/2 in the inhibitory effect of CGRP signal pathway.VSMCs were prepared from thoracic aorta of male Sprague-Dawley rat by the classic explants method,the passage 3 ~ 10 VSMCs were used for the present study.10% fetal bovine serum(FBS) was employed as a stimulus for the proliferation of VSMCs.β-Cyclodextrin or filipin was used to deplete cholesterol in the caveolae.Proliferation of VSMCs was estimated by methylthiazoletrazolium(MTT) assay and Flow Cytometry.Western blotting and co-immunoprecipitation were used to determine interaction of p-ERK 1/2 or caveolin-1.Results showed that CGRP significantly inhibited VSMC proliferation and down-regulated phosphorylation of ERK 1/2.Incubation of VSMCs with β-cyclodextrin or filipin promoted cells proliferation,up-regulated phosphorylation of ERK 1/2,attenuated the inhibitory action of CGRP on VSMC proliferation and decreased caveolin-1 expression.Pretreatment with CGRP increased the direct binding of cavolin-1 with phosphorylated(p-) ERK 1/2 but not non-phosphorylated ERK 1/2 in the presence of 10%FBS.Our results revealed that caveolae and caveolin-1 may contribute to the inhibitory effect of CGRP on the VSMC proliferation,and the mechanism may be related to the deceased nuclei translocation of p-ERK 1/2 because of the increased binding of caveolin-1 with p-ERK 1/2.

Cav1 Suppresses Tumor Growth and Metastasis in a Murine Model of Cutaneous SCC through Modulation of MAPK/AP-1 Activation

Caveolin-1 (Cav1) is a scaffolding protein that serves to regulate the activity of several signaling molecules. Its loss has been implicated in the pathogenesis of several types of cancer, but its role in the development and progression of cutaneous squamous cell carcinoma (cSCC) remains largely unexplored. Herein, we use the keratinocyte cell line PAM212, a murine model of cSCC, to determine the function of Cav1 in skin tumor biology. We first show that Cav1 overexpression decreases cell and tumor growth, whereas Cav1 knockdown increases these attributes in PAM212 cells. In addition, Cav1 knockdown increases the invasive ability and incidence of spontaneous lymph node metastasis. Finally, we demonstrate that Cav1 knockdown increases extracellular signaling-related kinase 1/2 mitogen-activated protein kinase/activator protein-1 pathway activation. We attribute the growth and invasive advantage conferred by Cav1 knockdown to increased expression of activator protein-1 transcriptional targets, including cyclin D1 and keratin 18, which show inverse expression in PAM212 based on the expression level of Cav1. In summary, we demonstrate that loss of Cav1 affects several characteristics associated with aggressive human skin tumors and that this protein may be an important modulator of tumor growth and invasion in cSCC.

Characterization of the Molecular Architecture of Human Caveolin-3 and Interaction with the Skeletal Muscle Ryanodine Receptor

Caveolin-3 facilitates both caveolae formation and a range of cell signaling pathways, including Ca(2+) homeostasis. Caveolin-3 forms a disc-shaped nonamer that binds the Ca(2+)-release channel, RyR1. Multiple caveolin-3 nonamers bind to a single RyR1 homotetramer. First three-dimensional structural insights into caveolin-3 assembly, interactions with RyR1 suggest a novel role in muscle contraction and/or for channel localization within the membrane. Caveolin-3 (cav-3), an integral membrane protein, is a building block of caveolae as well as a regulator of a number of physiological processes by facilitating the formation of multiprotein signaling complexes. We report that the expression of cav-3 in insect (Sf9) cells induces caveola formation, comparable in size with those observed in native tissue. We have also purified the recombinant cav-3 determining that it forms an oligomer of ∼220 kDa. We present the first three-dimensional structure for cav-3 (using transmission electron microscopy and single particle analysis methods) and show that nine cav-3 monomers assemble to form a complex that is toroidal in shape, ~16.5 nm in diameter and ~ 5.5 nm in height. Labeling experiments and reconstitution of the purified cav-3 into liposomes have allowed a proposal for the orientation of the protein with respect to the membrane. We have identified multiple caveolin-binding motifs within the ryanodine receptor (RyR1) sequence employing a bioinformatic analysis. We have then shown experimentally that there is a direct interaction between recombinant cav-3 nonamers and purified RyR1 homotetramers that would imply that at least one of the predicted cav-3-binding sites is exposed within the fully assembled RyR1 structure. The cav-3 three-dimensional model provides new insights as to how a cav-3 oligomer can bind multiple partners in close proximity to form signaling complexes. Furthermore, a direct interaction with RyR1 suggests a possible role for cav-3 as a modifier of muscle excitation-contraction coupling and/or for localization of the receptor to regions of the sarcoplasmic reticulum.

Oligomers of the ATPase EHD2 confine caveolae to the plasma membrane through association with actin

Caveolae are specialized domains present in the plasma membrane (PM) of most mammalian cell types. They function in signalling, membrane regulation, and endocytosis. We found that the Eps-15 homology domain-containing protein 2 (EHD2, an ATPase) associated with the static population of PM caveolae. Recruitment to the PM involved ATP binding, interaction with anionic lipids, and oligomerization into large complexes (60-75S) via interaction of the EH domains with intrinsic NPF/KPF motifs. Hydrolysis of ATP was essential for binding of EHD2 complexes to caveolae. EHD2 was found to undergo dynamic exchange at caveolae, a process that depended on a functional ATPase cycle. Depletion of EHD2 by siRNA or expression of a dominant-negative mutant dramatically increased the fraction of mobile caveolar vesicles coming from the PM. Overexpression of EHD2, in turn, caused confinement of cholera toxin B in caveolae. The confining role of EHD2 relied on its capacity to link caveolae to actin filaments. Thus, EHD2 likely plays a key role in adjusting the balance between PM functions of stationary caveolae and the role of caveolae as vesicular carriers.

Accumulated caveolae constitute subcellular compartments for glial calcium signaling in lanceolate sensory endings innervating rat vibrissae

The terminal Schwann cells that accompany lanceolate sensory endings in the rat vibrissal follicle are known to display the small plasma membrane invaginations termed caveolae, which concentrate Ca(2+) signaling molecules. We have previously shown that these cells generate Ca(2+) signals at the lamellar processes covering the receptor axons through activation of the metabotropic purinoceptor P2Y(2). To investigate the roles of caveolae in the spatiotemporal organization of Ca(2+) signals, terminal Schwann cells were observed by immunohistochemistry for the caveola protein caveolin-1, and by transmission and scanning electron microscopy. In addition, immunohistochemical detection of P2Y(2) and its coupling partner G(q/11) along with confocal image analysis of the purinergically induced glial Ca(2+) responses was performed in isolated tissue preparations either treated or untreated with the caveolae eliminator methyl-β-cyclodextrin. Results showed the Schwann lamellae to be characterized by the presence of dense caveolae accompanying a fine tubular network of the endoplasmic reticulum Ca(2+) store and by intense expression of the signaling molecules P2Y(2) and G(q/11). Loss of caveolae diffusely redistributed these molecules throughout the entire cell and impaired the lamellar Ca(2+) signals, both in chronological priority (preceding the global cell response) and in spatial integrity (involving the entire length of the processes). To our knowledge, this is the first report of a subcellular accumulation of caveolae underlying compartmentalized glial Ca(2+) signals that can couple with local effects on the accompanying axon terminals.