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Fatty acids (FAs) are essential nutrients, but how they are transported into cells remains unclear. Here, we show that FAs trigger caveolae-dependent CD36 internalization, which in turn delivers FAs into adipocytes. During the process, binding of FAs to CD36 activates its downstream kinase LYN, which phosphorylates DHHC5, the palmitoyl acyltransferase of CD36, at Tyr91 and inactivates it. CD36 then gets depalmitoylated by APT1 and recruits another tyrosine kinase SYK to phosphorylate JNK and VAVs to initiate endocytic uptake of FAs. Blocking CD36 internalization by inhibiting APT1, LYN or SYK abolishes CD36-dependent FA uptake. Restricting CD36 at either palmitoylated or depalmitoylated state eliminates its FA uptake activity, indicating an essential role of dynamic palmitoylation of CD36. Furthermore, blocking endocytosis by targeting LYN or SYK inhibits CD36-dependent lipid droplet growth in adipocytes and high-fat-diet induced weight gain in mice. Our study has uncovered a dynamic palmitoylation-regulated endocytic pathway to take up FAs. The mechanistic details of fatty acid uptake into cells remains poorly understood. Here, the authors identify CD36 internalization via cavaeolae and demonstrate dynamic palmitoylationof CD36 is required for endocytic uptake of fatty acids.

Medulloblastoma is the most common malignant paediatric brain tumour, with ~30% mediated by Sonic hedgehog signalling. Vismodegib-mediated inhibition of the Sonic hedgehog effector Smoothened inhibits tumour growth but causes growth plate fusion at effective doses. Here, we report a nanotherapeutic approach targeting endothelial tumour vasculature to enhance blood–brain barrier crossing. We use fucoidan-based nanocarriers targeting endothelial P-selectin to induce caveolin-1-dependent transcytosis and thus nanocarrier transport into the brain tumour microenvironment in a selective and active manner, the efficiency of which is increased by radiation treatment. In a Sonic hedgehog medulloblastoma animal model, fucoidan-based nanoparticles encapsulating vismodegib exhibit a striking efficacy and marked reduced bone toxicity and drug exposure to healthy brain tissue. Overall, these findings demonstrate a potent strategy for targeted intracranial pharmacodelivery that overcomes the restrictive blood–brain barrier to achieve enhanced tumour-selective penetration and has therapeutic implications for diseases within the central nervous system.Targeting of tumour vasculature endothelial P-selectin promotes caveolin-1-mediated transcytosis for enhanced blood–brain barrier crossing of therapeutic nanoparticles against medulloblastoma.

Key Points Caveolae, submicroscopic pits of the plasma membrane, consist of caveolin membrane proteins and cytoplasmic cavin proteins. Caveolae can bud from the plasma membrane, fuse with early endosomes and recycle back to the cell surface, or they can be turned over via a ubiquitylation-dependent mechanism and targeted to multivesicular bodies. Mutations in caveolins and cavins have been linked to diverse disease states, including cancer, lipodystrophy, cardiomyopathy and muscular dystrophies. The various diseases linked to caveolae dysfunction suggest a crucial cellular role in lipid regulation, membrane organization and in cell protection against physical stress. Flattening of caveolae in response to plasma membrane forces may provide a reservoir of membrane and activate signalling pathways through caveolins and cavins. Caveola dysfunction can influence a range of signalling pathways and lipid regulatory processes with widespread effects on cell function. Caveolae in the plasma membrane mediate signalling control and the response to membrane stress. The roles of caveolins and cavins hold the key to caveola structure and function, and their dysfunction is linked to several human diseases. Caveolae are submicroscopic, plasma membrane pits that are abundant in many mammalian cell types. The past few years have seen a quantum leap in our understanding of the formation, dynamics and functions of these enigmatic structures. Caveolae have now emerged as vital plasma membrane sensors that can respond to plasma membrane stresses and remodel the extracellular environment. Caveolae at the plasma membrane can be removed by endocytosis to regulate their surface density or can be disassembled and their structural components degraded. Coat proteins, called cavins, work together with caveolins to regulate the formation of caveolae but also have the potential to dynamically transmit signals that originate in caveolae to various cellular destinations. The importance of caveolae as protective elements in the plasma membrane, and as membrane organizers and sensors, is highlighted by links between caveolae dysfunction and human diseases, including muscular dystrophies and cancer.

Human epidermal growth factor receptor 2 (HER2) gene amplification and/or protein overexpression in tumors is a prerequisite for initiation of trastuzumab therapy. Although HER2 is a cell membrane receptor, differential rates of endocytosis and recycling engender a dynamic surface pool of HER2. Since trastuzumab must bind to the extracellular domain of HER2, a depressed HER2 surface pool hinders binding. Using in vivo biological models and cultures of fresh human tumors, we find that the caveolin-1 (CAV1) protein is involved in HER2 cell membrane dynamics within the context of receptor endocytosis. The translational significance of this finding is highlighted by our observation that temporal CAV1 depletion with lovastatin increases HER2 half-life and availability at the cell membrane resulting in improved trastuzumab binding and therapy against HER2-positive tumors. These data show the important role that CAV1 plays in the effectiveness of trastuzumab to target HER2-positive tumors. Trastuzumab binding to tumor cells depends on the availability of HER2 at the cell membrane. Here the authors show that caveolin-1 (CAV1) regulates HER2 density at the cell membranes and that CAV1 gene knockdown or protein depletion via the cholesterol modulator lovastatin, increases trastuzumab binding and anti-tumor activity.

The lipid content of the plasma membrane is dynamically regulated to maintain cellular homeostasis, but the molecular links between membrane stress and sphingolipid synthesis have remained elusive. Walther, Loewith and colleagues report that membrane stretching causes redistribution of Slm proteins, which then promote sphingolipid synthesis through activation of the TORC2–Ypk signalling pathway. The plasma membrane delimits the cell, and its integrity is essential for cell survival. Lipids and proteins form domains of distinct composition within the plasma membrane. How changes in plasma membrane composition are perceived, and how the abundance of lipids in the plasma membrane is regulated to balance changing needs remains largely unknown. Here, we show that the Slm1/2 paralogues and the target of rapamycin kinase complex 2 (TORC2) play a central role in this regulation. Membrane stress, induced by either inhibition of sphingolipid metabolism or by mechanically stretching the plasma membrane, redistributes Slm proteins between distinct plasma membrane domains. This increases Slm protein association with and activation of TORC2, which is restricted to the domain known as the membrane compartment containing TORC2 (MCT; ref.  1 ). As TORC2 regulates sphingolipid metabolism 2 , our discoveries reveal a homeostasis mechanism in which TORC2 responds to plasma membrane stress to mediate compensatory changes in cellular lipid synthesis and hence modulates the composition of the plasma membrane. The components of this pathway and their involvement in signalling after membrane stretch are evolutionarily conserved.

The large GTPase dynamin has a crucial role in endocytosis, working at the neck of clathrin-coated pits to drive vesicular scission. Until recently, dynamin was believed to regulate endocytosis through caveolae in a similar fashion. However, recent work calls for a serious reassessment of the role of dynamin in endocytosis by caveolae.Robert Parton and colleagues discuss novel evidence on the role of dynamin in caveolar endocytosis, which calls into question established models of dynamin-mediated fission.

Caveolae are small coated plasma membrane invaginations with diverse functions. Caveolae undergo curvature changes. Yet, it is unclear which proteins regulate this process. To address this gap, we develop a correlative stimulated emission depletion (STED) fluorescence and platinum replica electron microscopy imaging (CLEM) method to image proteins at single caveolae. Caveolins and cavins are found at all caveolae, independent of curvature. EHD2 is detected at both low and highly curved caveolae. Pacsin2 associates with low curved caveolae and EHBP1 with mostly highly curved caveolae. Dynamin is absent from caveolae. Cells lacking dynamin show no substantial changes to caveolae, suggesting that dynamin is not directly involved in caveolae curvature. We propose a model where caveolins, cavins, and EHD2 assemble as a cohesive structural unit regulated by intermittent associations with pacsin2 and EHBP1. These coats can flatten and curve to enable lipid traffic, signaling, and changes to the surface area of the cell. Caveolae can bend and flatten, but how this is regulated is not well understood. Authors use correlative super-resolution light and electron microscopy to map the key proteins that mediate curvature of the caveolar coat.

Caveolin-3 is the major structural protein of caveolae in muscle. Mutations in the CAV3 gene cause different types of myopathies with altered membrane integrity and repair, expression of muscle proteins, and regulation of signaling pathways. We show here that myotubes from patients bearing the CAV3 P28L and R26Q mutations present a dramatic decrease of caveolae at the plasma membrane, resulting in abnormal response to mechanical stress. Mutant myotubes are unable to buffer the increase in membrane tension induced by mechanical stress. This results in impaired regulation of the IL6/STAT3 signaling pathway leading to its constitutive hyperactivation and increased expression of muscle genes. These defects are fully reversed by reassembling functional caveolae through expression of caveolin-3. Our study reveals that under mechanical stress the regulation of mechanoprotection by caveolae is directly coupled with the regulation of IL6/STAT3 signaling in muscle cells and that this regulation is absent in Cav3-associated dystrophic patients. Caveolae are mechanosensors and mutations of their coat proteins are implicated in muscle disorders, but molecular mechanisms are unclear. Here, the authors show that caveolae can regulate IL6/STAT3 signaling in muscle cells under stress, and that dystrophy related Cav3 mutant myotubes have reduced caveolae and upregulated IL6 signaling.

The recent discovery of the flat, disc-like structure of caveolin oligomers, predicted to be embedded in one membrane leaflet, has challenged earlier models of membrane curvature generation by caveolins during caveola biogenesis. Here, we provide a mechanism for this phenomenon. We propose that the central factor behind the membrane shaping by caveolin discs is a difference in interaction energies of the membrane leaflets with each other and with the hydrophobic faces of the caveolin discs. We demonstrate, through computational analysis, that the caveolin disc embedding induces elastic stresses of tilt and splay in the membrane leaflets, which, in turn, drive membrane kinking along the disc boundaries. The predicted resulting membrane shapes have an overall curved and faceted appearance in agreement with observations. Our model also provides a mechanistic understanding of the role of the negative intrinsic curvatures of lipids such as cholesterol and diacylglycerols, in caveola assembly. The physical mechanism generating membrane curvature by disc-shaped caveolin complexes is not fully understood. Here, the authors use mathematical modelling to propose a mechanism based on a differential contact energy between the discs and the membrane leaflets.

Caveolae are spherically shaped nanodomains of the plasma membrane, generated by cooperative assembly of caveolin and cavin proteins. Cavins are cytosolic peripheral membrane proteins with negatively charged intrinsically disordered regions that flank positively charged α-helical regions. Here, we show that the three disordered domains of Cavin1 are essential for caveola formation and dynamic trafficking of caveolae. Electrostatic interactions between disordered regions and α-helical regions promote liquid-liquid phase separation behaviour of Cavin1 in vitro, assembly of Cavin1 oligomers in solution, generation of membrane curvature, association with caveolin-1, and Cavin1 recruitment to caveolae in cells. Removal of the first disordered region causes irreversible gel formation in vitro and results in aberrant caveola trafficking through the endosomal system. We propose a model for caveola assembly whereby fuzzy electrostatic interactions between Cavin1 and caveolin-1 proteins, combined with membrane lipid interactions, are required to generate membrane curvature and a metastable caveola coat. Caveolae are spherical nanodomains of the plasma membrane generated by assembly of caveolin and cavin proteins. Here, the authors show that fuzzy electrostatic interactions between caveolin-1 and Cavin1 proteins, combined with membrane lipid interactions, are required to generate membrane curvature and a metastable caveola coat.