Clathrin function in yeast endocytosis

The process of endocytosis is a complex series of events involving the coordinated activity of many proteins. In animal cells, clathrin plays a vital role in the invagination of the plasma membrane leading to formation of vesicles during endocytosis. The study of endocytosis in yeast cells has been hindered by a debate about the role of clathrin in early internalization steps. This review summarizes the evidence for and against clathrin's involvement in internalization from the yeast plasma membrane.     

Membrane Mechanics of Endocytosis in Cells with Turgor

Endocytosis is an essential process by which cells internalize a piece of plasma membrane and material from the outside. In cells with turgor, pressure opposes membrane deformations, and increases the amount of force that has to be generated by the endocytic machinery. To determine this force, and calculate the shape of the membrane, we used physical theory to model an elastic surface under pressure. Accurate fits of experimental profiles are obtained assuming that the coated membrane is highly rigid and preferentially curved at the endocytic site. The forces required from the actin machinery peaks at the onset of deformation, indicating that once invagination has been initiated, endocytosis is unlikely to stall before completion. Coat proteins do not lower the initiation force but may affect the process by the curvature they induce. In the presence of isotropic curvature inducers, pulling the tip of the invagination can trigger the formation of a neck at the base of the invagination. Hence direct neck constriction by actin may not be required, while its pulling role is essential. Finally, the theory shows that anisotropic curvature effectors stabilize membrane invaginations, and the loss of crescent-shaped BAR domain proteins such as Rvs167 could therefore trigger membrane scission.     

Membrane Expansion Increases Endocytosis Rate during Mitosis

Mitosis in mammalian cells is accompanied by a dramatic inhibition of endocytosis. We have found that the addition of amphyphilic compounds to metaphase cells increases the endocytosis rate even to interphase levels. Detergents and solvents all increased endocytosis rate, and the extent of increase was in direct proportion to the concentration added. Although the compounds could produce a variety of different effects, we have found a strong correlation with a physical alteration in the membrane tension as measured by the laser tweezers. Plasma membrane tethers formed by latex beads pull back on the beads with a force that was related to the in-plane bilayer tension and membrane– cytoskeletal adhesion. We found that as cells enter mitosis, the membrane tension rises as the endocytosis rate decreases; and as cells exited mitosis, the endocytosis rate increased as the membrane tension decreased. The addition of amphyphilic compounds decreased membrane tension and increased the endocytosis rate. With the detergent, deoxycholate, the endocytosis rate was restored to interphase levels when the membrane tension was restored to interphase levels. Although biochemical factors are clearly involved in the alterations in mitosis, we suggest that endocytosis is blocked primarily by the increase in apparent plasma membrane tension. Higher tensions inhibit both the binding of the endocytic complex to the membrane and mechanical deformation of the membrane during invagination. We suggest that membrane tension is an important regulator of the endocytosis rate and alteration of tension is sufficient to modify endocytosis rates during mitosis. Further, we postulate that the rise in membrane tension causes cell rounding and the inhibition of motility, characteristic of mitosis.     

Editorial

Stimulated secretion in endocrine cells and neuronal synapses causes a rise in endocytosis rates to recover the added membrane. The endocytic process involves the mechanical deformation of the membrane to produce an invagination. Studies of osmotic swelling effects on endocytosis indicate that the increased surface tension is tightly correlated to a significant decrease of endocytosis. When rat basophilic leukemia (RBL) cells are stimulated to secrete, there is a dramatic drop in the membrane tension and only small changes in membrane bending stiffness. Neither the shape change that normally accompanies secretion nor the binding of ligand without secretion causes a drop in tension. Further, tension decreases within 6 s, preceding shape change and measurable changes in endocytosis. After secretion stops, tension recovers. On the basis of these results we suggest that the physical parameter of membrane tension is a major regulator of endocytic rate in RBL cells. Low tensions would stimulate endocytosis and high tensions would stall the endocytic machinery.     

Cytosol- and clathrin-dependent stimulation of endocytosis in vitro by purified adaptors

Using stage-specific assays for receptor-mediated endocytosis of transferrin (Tfn) into perforated A431 cells we show that purified adaptors stimulate coated pit assembly and ligand sequestration into deeply invaginated coated pits. Late events in endocytosis involving membrane fission and coated vesicle budding which lead to the internalization of Tfn are unaffected. AP2, plasma membrane adaptors, are active at physiological concentrations, whereas AP1, Golgi adaptors, are inactive. Adaptor-dependent stimulation of Tfn sequestration requires cytosolic clathrin, but is unaffected by clathrin purified from coated vesicles suggesting that soluble and assembled clathrin pools are functionally distinct. In addition to adaptors and cytosolic clathrin other, as yet unidentified, cytosolic factors are also required for efficient coated pit invagination. These results provide new insight into the mechanisms and regulation of coated pit assembly and invagination.     

The phosphoinositide phosphatase Sjl2 is recruited to cortical actin patches in the control of vesicle formation and fission during endocytosis

The Saccharomyces cerevisiae synaptojanin-like proteins (Sjl1, Sjl2, and Sjl3) are phosphoinositide (PI) phosphatases that regulate PI metabolism in the control of actin organization and membrane trafficking. However, the primary sites of action for each of the yeast synaptojanin-like proteins remain unclear. In this study, we show that Sjl2 is localized to cortical actin patches, sites of endocytosis. Cortical recruitment of Sjl2 requires the actin patch component Abp1. Consistent with this, the SH3 domain-containing protein Abp1 physically associates with Sjl2 through its proline-rich domain. Furthermore, abp1Delta mutations confer defects resembling loss of SJL2; sjl1Delta abp1Delta double-mutant cells exhibit invaginated plasma membranes and impaired endocytosis, findings similar to those for sjl1Delta sjl2Delta mutant cells. Thus, Abp1 acts as an adaptor protein in the localization or concentration of Sjl2 during late stages of endocytic vesicle formation. Overexpression of the Hip1-related protein Sla2 delayed the formation of extended plasma membrane invaginations in sjl2ts cells, indicating that Sla2 may become limiting or misregulated in cells with impaired PI phosphatase activity. Consistent with this, the cortical actin patch protein Sla2 is mislocalized in sjl1Delta sjl2Delta mutant cells. Together, our studies suggest that PI metabolism by the synaptojanin-like proteins coordinately directs actin dynamics and membrane invagination, in part by regulation of Sla2.     

Extraction of cholesterol with methyl-beta-cyclodextrin perturbs formation of clathrin-coated endocytic vesicles

The importance of cholesterol for endocytosis has been investigated in HEp-2 and other cell lines by using methyl-beta-cyclodextrin (MbetaCD) to selectively extract cholesterol from the plasma membrane. MbetaCD treatment strongly inhibited endocytosis of transferrin and EGF, whereas endocytosis of ricin was less affected. The inhibition of transferrin endocytosis was completely reversible. On removal of MbetaCD it was restored by continued incubation of the cells even in serum-free medium. The recovery in serum-free medium was inhibited by addition of lovastatin, which prevents cholesterol synthesis, but endocytosis recovered when a water-soluble form of cholesterol was added together with lovastatin. Electron microscopical studies of MbetaCD-treated HEp-2 cells revealed that typical invaginated caveolae were no longer present. Moreover, the invagination of clathrin-coated pits was strongly inhibited, resulting in accumulation of shallow coated pits. Quantitative immunogold labeling showed that transferrin receptors were concentrated in coated pits to the same degree (approximately sevenfold) after MbetaCD treatment as in control cells. Our results therefore indicate that although clathrin-independent (and caveolae-independent) endocytosis still operates after removal of cholesterol, cholesterol is essential for the formation of clathrin-coated endocytic vesicles.     

Role of turgor pressure in endocytosis in fission yeast

Yeast and other walled cells possess high internal turgor pressure that allows them to grow and survive in the environment. This turgor pressure, however, may oppose the invagination of the plasma membrane needed for endocytosis. Here we study the effects of turgor pressure on endocytosis in the fission yeast Schizosaccharomyces pombe by time-lapse imaging of individual endocytic sites. Decreasing effective turgor pressure by addition of sorbitol to the media significantly accelerates early steps in the endocytic process before actin assembly and membrane ingression but does not affect the velocity or depth of ingression of the endocytic pit in wild-type cells. Sorbitol also rescues endocytic ingression defects of certain endocytic mutants and of cells treated with a low dose of the actin inhibitor latrunculin A. Endocytosis proceeds after removal of the cell wall, suggesting that the cell wall does not contribute mechanically to this process. These studies suggest that endocytosis is governed by a mechanical balance between local actin-dependent inward forces and opposing forces from high internal turgor pressure on the plasma membrane.     

Phosphoinositides regulate clathrin-dependent endocytosis at the tip of pollen tubes in Arabidopsis and tobacco

Using the tip-growing pollen tube of Arabidopsis thaliana and Nicotiana tabacum as a model to investigate endocytosis mechanisms, we show that phosphatidylinositol-4-phosphate 5-kinase 6 (PIP5K6) regulates clathrin-dependent endocytosis in pollen tubes. Green fluorescent protein-tagged PIP5K6 was preferentially localized to the subapical plasma membrane (PM) in pollen tubes where it apparently converts phosphatidylinositol 4-phosphate (PI4P) to phosphatidylinositol 4,5-bisphosphate [PI(4,5)P(2)]. RNA interference-induced suppression of PIP5K6 expression impaired tip growth and inhibited clathrin-dependent endocytosis in pollen tubes. By contrast, PIP5K6 overexpression induced massive aggregation of the PM in pollen tube tips. This PM abnormality was apparently due to excessive clathrin-dependent membrane invagination because this defect was suppressed by the expression of a dominant-negative mutant of clathrin heavy chain. These results support a role for PI(4,5)P(2) in promoting early stages of clathrin-dependent endocytosis (i.e., membrane invagination). Interestingly, the PIP5K6 overexpression-induced PM abnormality was partially suppressed not only by the overexpression of PLC2, which breaks down PI(4,5)P(2), but also by that of PI4Kβ1, which increases the pool of PI4P. Based on these observations, we propose that a proper balance between PI4P and PI(4,5)P(2) is required for clathrin-dependent endocytosis in the tip of pollen tubes.     

Coupling between clathrin-coated-pit invagination, cortactin recruitment, and membrane scission observed in live cells

During clathrin-mediated endocytosis, membrane scission marks the isolation of a cargo-laden clathrin-coated pit (CCP) from the cell exterior. Here we used live-cell imaging of a pH-sensitive cargo to visualize the formation of clathrin-coated vesicles (CCVs) at single CCPs with a time resolution of seconds. We show that CCPs are highly dynamic and can produce multiple vesicles in succession. Using alternating evanescent field and epifluorescence illumination, we show that CCP invagination and scission are tightly coupled, with scission coinciding with maximal displacement of CCPs from the plasma membrane and with peak recruitment of cortactin-DsRed, a dynamin and F-actin binding protein. Finally, perturbing actin polymerization with latrunculin-B drastically reduces the efficiency of membrane scission and affects many aspects of CCP dynamics. We propose that CCP invagination, actin polymerization, and CCV formation are highly coordinated for efficient endocytosis.     

The large GTPase dynamin2: a new player in connexin 43 gap junction endocytosis, recycling and degradation

Connexins (Cx) are key regulators of cell proliferation, differentiation and apoptosis. Cx trafficking and endocytosis need interactions with a large number of signaling and scaffolding proteins. We demonstrate herein that Cx43-GFP gap junction plaque endocytosis was blocked in cells transfected by the dominant-negative form of dynamin2 (Dyn2K44A) and by dynasore, an inhibitor of dynamin GTPase activity, which reduced the association between dynamin2 and Cx43. Our data also reveal that recruitment of the GTPase at the plasma membrane and its activation by c-Src are key events for Cx43 internalization. In addition they show that dynamin2 participated in internalization and degradation of the gap junction plaque but also in recycling of Cx43 to the plasma membrane through respectively Rab5/Rab7 and Rab11 pathways. These results demonstrate for the first time that dynamin2 is a new Cx partner and report an innovating mechanistic model by which dynamin2 may control Cx43 gap junction plaque invagination, endocytosis, recycling and degradation. These processes are magnified in response to carcinogen exposure underlining their potential importance during carcinogenesis.     

Effects of chloroquine on the feeding mechanism of the intraerythrocytic human malarial parasite Plasmodium falciparum

Ultrastructural investigations of P. falciparum cultivated in vitro in human erythrocytes revealed new features of the feeding mechanism of the parasite. Mature trophozoites and schizonts take up a portion of the host cytosol by endocytosis which is restricted to cytostomes and which involves the invagination of both parasitophorous and parasite membranes. The resulting endocytic vesicles, surrounded by two concentric membranes, migrate towards the central food vacuole membrane. The external membrane of the endocytic vesicles apposes that of the food vacuole, leading to the internalization of vesicles bounded by a single membrane into the vacuole space where they are rapidly degraded. We conclude from this sequence of events that endocytic vesicles fuse with the food vacuole. Treatment of infected cells with therapeutic concentrations of chloroquine inhibited the last step of the feeding process, i.e. vacuolar degradation. This was manifested by the accumulation within the vacuolar space of intact vesicles bounded by single membranes. The implications of these findings for the antimalarial activity of chloroquine are discussed.     

Plasma Membrane Reshaping during Endocytosis Is Revealed by Time-Resolved Electron Tomography

Endocytosis, like many dynamic cellular processes, requires precise temporal and spatial orchestration of complex protein machinery to mediate membrane budding. To understand how this machinery works, we directly correlated fluorescence microscopy of key protein pairs with electron tomography. We systematically located 211 endocytic intermediates, assigned each to a specific time window in endocytosis, and reconstructed their ultrastructure in 3D. The resulting virtual ultrastructural movie defines the protein-mediated membrane shape changes during endocytosis in budding yeast. It reveals that clathrin is recruited to flat membranes and does not initiate curvature. Instead, membrane invagination begins upon actin network assembly followed by amphiphysin binding to parallel membrane segments, which promotes elongation of the invagination into a tubule. Scission occurs on average 9?s after initial bending when invaginations are ～100?nm deep, releasing nonspherical vesicles with 6,400?nm(2) mean surface area. Direct correlation of protein dynamics with ultrastructure provides a quantitative 4D resource.     

沉默FNBP1表达诱导7703细胞形态重塑

FNBP1在真核细胞中广泛表达,能通过诱导细胞膜管状化、内陷或变形及后续膜曲率依赖性肌动蛋白聚合过程,参与细胞内吞和运动;还可参与端粒维持及FasL与溶酶体结合过程的调控。研究发现,在肝癌细胞7703中,利用RNA干扰（RNA interference technology,RNAi）技术使内源FNBPI基因表达沉默以后,7703细胞形态发生重塑,由上皮样转变为树状分枝的纤维状,表明FNBP1在细胞形态维持过程中亦具有不可或缺的潜在作用;通过对已知FNBP1蛋白相互作用情况的分析推断,FNBP1可能是通过对肌动蛋白骨架动态组装过程的分子调控参与7703细胞形态的控制。     

Requirements of drug-induced endocytosis by intact human erythrocytes.

Study of drug-induced endocytosis in intact human erythrocytes continues to provide an opportunity for correlating membrane functions such as invagination and fusion with erythrocytic energetics and other determinants of plasma membrane function like Ca++. The studies reported indicate that high concentrations of vinblastine and chlorpromazine can produce endocytic vacuoles, albeit in reduced amounts, even in severely ATP depleted erythrocytes. In contrast, primaquine-induced endocytosis seems definitely dependent upon persistence of erythrocytic ATP stores. The ionophore mediated entry of Ca++ into erythrocytes potentiates primaquine endocytosis, inhibits vinblastine endocytosis, and has no regular effect on chlorpromazine endocytosis. Sodium lactate enhances primaquine endocytosis, probably by causing an increase in the entry of primaquine into erythrocytes. Cytochalasin B neither enhances nor inhibits erythrocytic endocytosis, thereby suggesting that microfibrils or analogues of microfibrils in erythrocytes are not involved in endocytosis. Cyclic nucleotide inhibition of endocytosis is confined to a very high concentration range of nucleotides in the medium. Primaquine and chlorpromazine endocytosis are inhibited by cyclic nucleotides as is vinblastine endocytosis.     

A modular design for the clathrin- and actin-mediated endocytosis machinery

Endocytosis depends on an extensive network of interacting proteins that execute a series of distinct subprocesses. Previously, we used live-cell imaging of six budding-yeast proteins to define a pathway for association of receptors, adaptors, and actin during endocytic internalization. Here, we analyzed the effects of 61 deletion mutants on the dynamics of this pathway, revealing functions for 15 proteins, and we analyzed the dynamics of 8 of these proteins. Our studies provide evidence for four protein modules that cooperate to drive coat formation, membrane invagination, actin-meshwork assembly, and vesicle scission during clathrin/actin-mediated endocytosis. We found that clathrin facilitates the initiation of endocytic-site assembly but is not needed for membrane invagination or vesicle formation. Finally, we present evidence that the actin-meshwork assembly that drives membrane invagination is nucleated proximally to the plasma membrane, opposite to the orientation observed for previously studied actin-assembly-driven motility processes.     

Glucose transport into human erythrocytes treated with phospholipase A2 or C

Phospholipase A2 induced crenation of human erythrocytes and decreased glucose transport activity (influx rate) by 40% when 51% of phosphatidylcholine (PC) in the membrane was hydrolyzed. On the other hand, phospholipase C induced invagination of the cells and negligibly affected the glucose transport in the case of 21% hydrolysis of the PC. By altering the pH of the medium for suspending cells treated with phospholipase A2 from 7.4 to 6.0, cell shape was changed from clear crenation to slight invagination, but glucose transport activity was not affected. Cells that were treated with phospholipase A2 and then washed with albumin to remove free fatty acids produced in the cell membrane showed an almost normal cell shape and slightly higher glucose transport activity than did untreated cells. The ratios of beta-D-glucose transport rate to alpha-D-glucose transport rate in untreated cells, cells treated with phospholipase A2 and cells treated with phospholipase C were 1.13, 1.04, and 1.20, respectively. These results demonstrate that the drastic morphological change (invagination or crenation) induced by the treatment with phospholipases bears no clear relationship to the activity of glucose transport and suggest that the increase in the volume of the outer half of the lipid bilayer might reduce the rate of glucose transport across the human erythrocyte membrane and change the anomeric preference of glucose transport.     

Dynamics of yeast Myosin I: evidence for a possible role in scission of endocytic vesicles

Cortical actin patches are dynamic structures required for endocytosis in yeast. Recent studies have shown that components of cortical patches localize to the plasma membrane in a precisely orchestrated manner, and their movements at and away from the plasma membrane may define the endocytic membrane invagination and vesicle scission events, respectively. Here, through live-cell imaging, we analyze the dynamics of the highly conserved class I unconventional myosin, Myo5, which also localizes to cortical patches and is known to be involved in endocytosis and actin nucleation. Myo5 exhibits a pattern of dynamic localization different from all cortical patch components analyzed to date. Myo5 associates with cortical patches only transiently and remains stationary during its brief cortical lifespan. The peak of Myo5 association with cortical patches immediately precedes the fast movement of Arp2/3 complex-associated structures away from the plasma membrane, thus correlating precisely with the proposed vesicle scission event. To further test the role of Myo5, we generated a temperature-sensitive mutant myo5 allele. In the myo5 mutant cells, Myo5 exhibits a significantly extended cortical lifespan as a result of a general impairment of Myo5 function, and Arp2 patches exhibit an extended slow-movement phase prior to the fast movement toward the cell interior. The myo5 mutant cells are defective in fluid-phase endocytosis and exhibit an increased number of invaginations on the membrane. Based on these results, we hypothesize that the myosin I motor protein facilitates the membrane fusion/vesicle scission event of endocytosis.     

Endophilin-1: a multifunctional protein

Endophilin-1, a cytoplasmic Src homology 3 (SH3) domain-containing protein, localises in brain presynaptic nerve termini. Endophilin dimerises through its N-terminus, and participates at multiple stages in clathrin-coated endocytosis, from early membrane invagination to synaptic vesicle uncoating. Both its C-terminal SH3 domain and N-terminus are required for endocytosis. Through its SH3 domain, endophilin bound to proline-rich domains (PRDs) in other endocytic proteins, including synaptojanin and dynamin. The N-terminal region possesses unique functions affecting lipid membrane curvature, through lysophosphatidic acid acyl transferase (LPAAT) activity and direct binding and tubulating activity. In addition to synaptic vesicle formation, endophilin-1 complexes with signalling molecules, including cell surface receptors, metalloprotease disintegrins and germinal centre kinase-like kinase (GLK). Therefore, endophilin-1 may serve to couple vesicle biogenesis with intracellular signalling cascades.     

A novel dynamin-associating molecule, formin-binding protein 17, induces tubular membrane invaginations and participates in endocytosis

Dynamin associates with a variety of SH3 domain-containing molecules via a C-terminal proline-rich motif and takes part, with them, in endocytic processes. Here, we have investigated a new dynamin-associating molecule, formin-binding protein 17 (FBP17), involved in deforming the plasma membrane and in endocytosis. FBP17 formed tubular invaginations originating from the plasma membrane. Its N-terminal Fer/CIP4 homology domain, a coiled-coil domain, and a proline-rich motif were required for tubular invagination and self-assembly, by which tubular invagination might be induced. Using anti-FBP17 antibody, we detected positive immunoreactions in the testis that were restricted to the germ cells. We also detected FBP17 in the brain by immunoblotting and in situ hybridization. When COS cells expressing enhanced green fluorescent protein-tagged FBP17 were incubated with fluorescently labeled transferrin, epidermal growth factor, and cholera toxin, these molecules co-localized with FBP17-induced tubular invaginations, suggesting that FBP17 is involved in dynamin-mediated endocytosis in both a clathrin-dependent and -independent manner. These observations therefore indicate that FBP17 interacts with dynamin and regulates endocytosis by forming vesicotubular structures.