Water, proton, and urea transport in toad bladder endosomes that contain the vasopressin-sensitive water channel

Vasopressin (VP) increases the water permeability of the toad urinary bladder epithelium by inducing the cycling of vesicles containing water channels to and from the apical membrane of granular cells. In this study, we have measured several functional characteristics of the endosomal vesicles that participate in this biological response to hormonal stimulation. The water, proton, and urea permeabilities of endosomes labeled in the intact bladder with fluorescent fluid-phase markers were measured. The diameter of isolated endosomes labeled with horse-radish peroxidase was 90-120 nm. Osmotic water permeability (Pf) was measured by a stopped-flow fluorescence quenching assay (Shi, L.-B., and A. S. Verkman. 1989. J. Gen. Physiol. 94:1101-1115). The number of endosomes formed when bladders were labeled in the absence of a transepithelial osmotic gradient increased with serosal [VP] (0-50 mU/ml), and endosome Pf was very high and constant (0.08-0.10 cm/s, 18 degrees C). When bladders were labeled in the presence of serosal-to-mucosal osmotic gradient, the number of functional water channels per endosome decreased (at [VP] = 0.5 mU/ml, Pf = 0.09 cm/s, 0 osmotic gradient; Pf = 0.02 cm/s, 180 mosmol gradient). Passive proton permeability was measured from the rate of pH decrease in voltage-clamped endosomes in response to a 1 pH unit gradient (pHin = 7.5, pHout = 6.5). The proton permeability coefficient (PH) was 0.051 cm/s at 18 degrees C in endosomes containing the VP-sensitive water channel; PH was not different from that measured in vesicles not containing water channels. Measurement of urea transport by the fluorescence quenching assay gave a urea reflection coefficient of 0.97 and a permeability coefficient of less than 10(-6) cm/s. These results demonstrate: (a) VP-induced endosomes from toad urinary bladder have extremely high Pf. (b) In states of submaximal bladder Pf, the density of functional water channels in endosomes in constant in the absence of an osmotic gradient, but decreases in the presence of a serosal-to-mucosal gradient, suggesting that the gradient has a direct effect on the efficiency of packaging of water channels into endosomes. (c) The VP-sensitive water channel does not have a high proton permeability. (d) Endosomes that cycle the water channel do not contain urea transporters. These results establish a labeling procedure in which greater than 85% of labeled vesicles from toad urinary bladder are endosomes that contain the VP-sensitive water channel in a functional form.     

Botulinum Toxins Inhibit the Antidiuretic Hormone (ADH)-Stimulated Increase in Rabbit Cortical Collecting-Tubule Water Permeability

The mammalian renal collecting duct increases its water permeability in response to antidiuretic hormone (ADH). ADH causes cytoplasmic endosomes containing the water channel, aquaporin 2 (AQP2), to fuse with the apical membrane so that the water permeability of the tubule increases many times above baseline. SNARE proteins are involved in the docking and fusion of vesicles with the cell membrane in neuron synapses. Whether these proteins are involved in the fusion of vesicles to the cell membrane in other tissues is not entirely clear. In the present study, we examined the role of SNARE proteins in the insertion of water channels in the collecting-duct response to ADH by using botulinum toxins A, B and C. Toxins isolated from clostridium botulinum are specific proteases that cleave different SNARE proteins and inactivate them. Tubules were perfused in vitro with botulinum toxin in the perfusate (50 nM for A and B and 15 nM for C). ADH (200 pM) was then added to the bath after baseline measurements of osmotic water permeability (P_f) and the change in P_f was followed for one hour. Botulinum toxins significantly inhibited the maximum P_f by approximately 50%. Botulinum toxins A and C also decreased the rate of rise of P_f. Thus, SNARE proteins are involved in the insertion of the water channels in the collecting duct.     

Functional water channels and proton pumps are in separate populations of endocytic vesicles in toad bladder granular cells

Functional water channels are retrieved by endocytosis from the apical membrane of toad bladder granular cells in response to vasopressin [Shi, L.-B., & Verkman, A.S. (1989) J. Gen. Physiol. 94, 1101-1115]. To examine whether endocytic vesicles which contain the vasopressin-sensitive water channel fuse with acidic vesicles for entry into a lysosomal pathway, ATP-dependent acidification and osmotic water permeability were measured in endosomes from control bladders and bladders treated with vasopressin (VP) and/or phorbol myristate acetate (PMA). Endosomes were labeled with the fluid-phase markers 6-carboxyfluorescein or fluorescein-dextran. Osmotic water permeability (Pf) was measured by stopped-flow fluorescence quenching and proton ATPase activity by ATP-dependent, N-ethylmaleimide-inhibitable acidification. In a microsomal pellet, Pf was low (less than 0.002 cm/s, 20 degrees C) in labeled endocytic vesicles from control bladders but high (0.05-0.1 cm/s) in a subpopulation (50-70%) of vesicles from VP- and PMA-treated bladders. Following ATP addition, the average drop in pH was 0.1 (control), 0.3 (VP), and 0.2 (PMA) unit. Measurement of pH in individual endocytic vesicles by quantitative image analysis showed that less than 20% of vesicles from VP-treated bladders acidified by greater than 0.5 pH unit. To examine whether water channels and proton pumps were present in the same endocytic vesicles, the pH of endosomes with high and low water permeability was measured from the effect of ATP on the amplitude of the fluorescence quenching signal in response to an osmotic gradient.(ABSTRACT TRUNCATED AT 250 WORDS)     

Apical endosomes isolated from kidney collecting duct principal cells lack subunits of the proton pumping ATPase

Endocytic vesicles that are involved in the vasopressin-stimulated recycling of water channels to and from the apical membrane of kidney collecting duct principal cells were isolated from rat renal papilla by differential and Percoll density gradient centrifugation. Fluorescence quenching measurements showed that the isolated vesicles maintained a high, HgCl2-sensitive water permeability, consistent with the presence of vasopressin-sensitive water channels. They did not, however, exhibit ATP-dependent luminal acidification, nor any N-ethylmaleimide-sensitive ATPase activity, properties that are characteristic of most acidic endosomal compartments. Western blotting with specific antibodies showed that the 31- and 70-kD cytoplasmically oriented subunits of the vacuolar proton pump were not detectable in these apical endosomes from the papilla, whereas they were present in endosomes prepared in parallel from the cortex. In contrast, the 56-kD subunit of the proton pump was abundant in papillary endosomes, and was localized at the apical pole of principal cells by immunocytochemistry. Finally, an antibody that recognizes the 16-kD transmembrane subunit of oat tonoplast ATPase cross-reacted with a distinct 16-kD band in cortical endosomes, but no 16-kD band was detectable in endosomes from the papilla. This antibody also recognized a 16-kD band in affinity-purified H+ ATPase preparations from bovine kidney medulla. Therefore, early endosomes derived from the apical plasma membrane of collecting duct principal cells fail to acidify because they lack functionally important subunits of a vacuolar-type proton pumping ATPase, including the 16-kD transmembrane domain that serves as the proton-conducting channel, and the 70-kD cytoplasmic subunit that contains the ATPase catalytic site. This specialized, non-acidic early endosomal compartment appears to be involved primarily in the hormonally induced recycling of water channels to and from the apical plasma membrane of vasopressin-sensitive cells in the kidney collecting duct.     

Effect of Water Stress and Mercuric Chloride on the Translational Diffusion of Water in Maize Seedling Roots

Water diffusion in maize roots (Zea mays L., cv. Donskaya 1) was investigated with a pulsed gradient NMR using mercuric chloride as an inhibitor of water channels in cell membranes. A novel operation program was applied that allowed selective evaluation of fractional amounts of water transported through various pathways—the apoplastic, symplasmic, and transmembrane routes. The blockage of water channels with HgCl₂ reduced the rates of water diffusion by a factor of 1.5–2. This effect was reversible and was removed by the addition of -mercaptoethanol. The coefficient of water diffusion changed with time elapsed after the HgCl₂ treatment. The effect of water stress on the rates of water diffusion was similar to that of HgCl₂. Remarkably, the water-stressed roots of maize seedlings were insensitive to the inhibitor of water channels. The results are interpreted in terms of redistribution of water flows among various routes in plant tissues. Water stress and mercuric chloride treatments decelerate the transmembrane water transport and promote water flow along the apoplastic pathway. These responses might arise from the reversible regulation of water movement along various transport pathways.     

ADP ribosylation factor and a 14-kD polypeptide are associated with heparan sulfate-carrying post-trans-Golgi network secretory vesicles in rat hepatocytes

Constitutive secretory vesicles carrying heparan sulfate proteoglycan (HSPG) were identified in isolated rat hepatocytes by pulse-chase experiments with [35S]sulfate and purified by velocity-controlled sucrose gradient centrifugation followed by equilibrium density centrifugation in Nycodenz. Using this procedure, the vesicles were separated from plasma membranes, Golgi, trans-Golgi network (TGN), ER, endosomes, lysosomes, transcytotic vesicles, and mitochondria. The diameter of these vesicles was approximately 100-200 nm as determined by electron microscopy. A typical coat structure as described for intra- Golgi transport vesicles or clathrin-coated vesicles could not be seen, and the vesicles were not associated with the coat protein beta-COP. Furthermore, the vesicles appear to represent a low density compartment (1.05-1.06 g/ml). Other constitutively secreted proteins (rat serum albumin, apolipoprotein E, and fibrinogen) could not be detected in purified HSPG-carrying vesicles, but banded in the denser fractions of the Nycodenz gradient. Moreover, during pulse-chase labeling with [35S]methionine, labeled albumin did not appear in the post-TGN vesicle fraction carrying HSPGs. These findings indicate sorting of HSPGs and albumin into different types of constitutive secretory vesicles in hepatocytes. Two proteins were found to be tightly associated with the membranes of the HSPG carrying vesicles: a member of the ADP ribosylation factor family of small guanine nucleotide-binding proteins and an unknown 14-kD peripheral membrane protein (VAPP14). Concerning the secretory pathway, we conclude from these results that ADP ribosylation factor proteins are not only involved in vesicular transport from the ER via the Golgi to the TGN, but also in vesicular transport from the TGN to the plasma membrane.     

Endocytic vesicles from renal papilla which retrieve the vasopressin- sensitive water channel do not contain a functional H+ ATPase

The water permeability of the kidney collecting duct epithelium is regulated by vasopressin (VP)-induced recycling of water channels between an intracellular vesicular compartment and the plasma membrane of principal cells. To test whether the water channels pass through an acidic endosomal compartment during the endocytic portion of this pathway, we measured ATP-dependent acidification of FITC-dextran-labeled endosomes in isolated microsomal fractions from different regions of Brattleboro rat kidneys. Both VP-deficient controls and rat treated with exogenous VP were examined. ATP-dependent acidification was not detectable in endosomes containing water channels from distal papilla (osmotic water permeability Pf = 0.038 +/- 0.004 cm/s). In contrast, the addition of ATP resulted in a strong acidification of renal cortical endosomes (pHmin = 5.8, initial rate = 0.18-0.25 pH U/s). Acidification of cortical endosomes was reversed with nigericin and strongly inhibited by N-ethyl-maleimide. Passive proton permeability was similar and low in both cortical and papillary endosomes from rats treated or not treated with VP. The fraction of labeled endosomes present in microsomal preparations was determined by fluorescence imaging microscopy of microsomes nonspecifically bound to poly-l-lysine-coated coverslips and was 25% in cortical preparations compared to 14% (+VP) and 9% (-VP) in papillary preparations. The fraction of cortical endosomes was enriched 1.5-fold by immunoabsorption to coverslips coated with mAbs against the bovine vacuolar proton pump. In contrast, the fraction of papillary endosomes was depleted more than twofold by immunoabsorption to identical coverslips. Finally, sections of distal papilla stained with antibodies against the lysosomal glycoprotein LGP120 showed that most of the entrapped FITC-dextran did not colocalize with this lysosomal protein. These results demonstrate that vesicles which internalize water channels in kidney collecting duct principal cells lack functional proton pumps, and do not deliver the bulk of their FITC-dextran content to lysosomes. The data suggest that the principal cell contains a specialized nonacidic apical endocytic compartment which functions primarily to recycle membrane components, including water channels, to the plasma membrane.     

Isolation of Heavy Endosomes from Dog Proximal Tubules in Suspension

During the preparation of a suspension of dog kidney proximal tubules by collagenase treatment, an uptake of FITC-albumin was demonstrated. This process is attributed to the activation of receptor-mediated endocytosis leading to the appearance of FITC-albumin into intracellular vesicular structures. The isolation of brush border membrane vesicles (BBMV) from the dog kidney proximal tubules in suspension by the magnesium precipitation technique leads to the copurification of a large population of endosomes. These endosomes were separated from BBM vesicles by a technique involving wheat-germ agglutinin. The enrichment in BBM markers and in bafilomycin-sensitive ATPase activity was comparable in endosomes and BBM vesicles. However, the acridine orange acidification assay showed a V-type ATPase-dependent acidification in endosomes but not in BBMV, demonstrating a different orientation of the proton pumps in these structures. SDS-PAGE analysis also showed significant differences in protein pattern of vesicles and endosomes. The most notable difference was the presence of 42–44 kDa and 20–24 kDa proteins in BBMV and their complete absence in endosomes. Western blot analysis identified these proteins as actin and RhoA, among other small proteins, respectively. Western blot experiments also demonstrated a different distribution of β-COP, β-adaptin, and RhoGDI in vesicles and endosomes. The morphological aspect (electron microscopy) and sedimentation of endosomes in a 50% Percoll gradient identified these structures as ``heavy endosomes' (buoyant density D= 1.036 g/ml). Flow cytometry analysis of heavy endosomes purified from tubules isolated in presence of FITC-albumin showed the presence of FITC-albumin in up to 92% of these intracellular organelles. Western blot analysis using anti-FITC and anti-collagenase antibodies allowed quantification of the FITC-albumin and collagenase A in the purified endosomes. Our results indicate that heavy endosomes are formed during the preparation of the proximal tubules following activation of receptor-mediated endocytosis, probably by soluble proteins. The suspension of tubules thus offers a experimental tool to study the protein reabsorption and traffic of endosomal vesicles in the proximal tubules. Received: 13 July 1995/Revised: 8 May 1996     

Regulation of the formation and water permeability of endosomes from toad bladder granular cells

Osmotic water permeability (Pf) in toad bladder is regulated by the vasopressin (VP)-dependent movement of vesicles containing water channels between the cytoplasm and apical membrane of granular cells. Apical endosomes formed in the presence of serosal VP have the highest Pf of any biological or artificial membrane (Shi and Verkman. 1989. J. Gen. Physiol. 94:1101-1115). We examine here: (a) the influence of protein kinase A and C effectors on transepithelial Pf (Pfte) in intact bladders and on the number and Pf of labeled endosomes, and (b) whether endosome Pf can be modified physically or biochemically. In paired hemibladder studies, Pfte induced by maximal serosal VP (50 mU/ml, 0.03 cm/s) was not different than that induced by 8-Br-cAMP (1 mM), forskolin (50 microM), VP + 8-Br-cAMP, or VP + forskolin. Pf was measured in endosomes labeled in intact bladders with carboxyfluorescein by a stopped-flow, fluorescence-quenching assay using an isolated microsomal suspension; the number and Pf (0.08-0.11 cm/s, 18 degrees C) of labeled endosomes was not different in bladders treated with VP, forskolin, and 8-Br-cAMP. Protein kinase C activation by 1 microM mucosal phorbol myristate acetate (PMA) induced submaximal bladder Pfte (0.015 cm/s) and endosome Pf (0.022 cm/s) in the absence of VP, but had little effect on maximal Pfte and endosome Pf induced by VP. However, PMA increased by threefold the number of apical endosomes with high Pf formed in response to serosal VP. Pf of endosomes containing the VP-sensitive water channel decreased fourfold by increasing membrane fluidity with hexanol or chloroform (0-75 mM); Pf of phosphatidylcholine liposomes (0.002 cm/s) increased 2.5-fold under the same conditions. Endosome Pf was mildly pH dependent, strongly inhibited by HgCl2, but not significantly altered by GTP gamma S, Ca, ATP + protein kinase A, and phosphatase action. We conclude that: (a) water channels cycled in endocytic vesicles are functional and not subject to physiological regulation, (b) VP and forskolin do not have cAMP-independent cellular actions, (c) activation of protein kinase C stimulates trafficking of water channels, but does not increase the number of apical membrane water channels induced by maximal VP, and (d) water channel function is sensitive to membrane fluidity. By using VP and PMA together, large quantities of endosomes containing the VP-sensitive water channel are labeled with fluid-phase endocytic markers.     

Cellular distribution of the aquaporins: A family of water channel proteins

A group of transmembrane proteins that are related to the major intrinsic protein of lens fibers (MIP26) have been named aquaporins to reflect their role as water channels. These proteins are located at strategic membrane sites in a variety of epithelia, most of which have well-defined physiological functions in fluid absorption or secretion. However, some aquaporins have been localized in cell types where their role is at present unknown. Most of the aquaporins are delivered to the plasma membrane in a non-regulated (constitutive) fashion, but AQP2 enters the regulated exocytotic pathway and its membrane expression is controlled by the action of the antidiuretic hormone, vasopressin. These pathways of constitutive versus regulated delivery to the plasma membrane have been reconstituted in transfected LLC-PK₁ epithelial cells, indicating that the information encoded within the protein sequence is sufficient to allow sorting of newly synthesized protein into distinct intracellular vesicles. Finally, different members of the aquaporin family can be targeted to apical, basolateral or both apical and basolateral plasma membrane domains of polarized epithelial cells. This implies that signals for the polarized targeting of these proteins also is located in non-homologous regions of these similar proteins. Thus, future investigations on the aquaporin family of proteins will provide important information not only on the physiology of membrane transport processes in many cell types, but also on the targeting and trafficking signals that allow proteins to enter distinct intracellular vesicular pathways in epithelial cells. In the case of AQP2, the availability of the transfected cell culture system will allow the intracellular signaling pathway, and the accessory molecules that are involved in this pathway, to be dissected and identified.     

Newly synthesized and recycling pools of the apical protein gp135 do not occupy the same compartments

Polarized epithelial cells sort newly synthesized and recycling plasma membrane proteins into distinct trafficking pathways directed to either the apical or basolateral membrane domains. While the trans‐Golgi network is a well‐established site of protein sorting, increasing evidence indicates a key role for endosomes in the initial trafficking of newly synthesized proteins. Both basolateral and apical proteins have been shown to traverse endosomes en route to the plasma membrane. In particular, apical proteins traffic through either subapical early or recycling endosomes. Here we use the SNAP tag system to analyze the trafficking of the apical protein gp135, also known as podocalyxin. We show that newly synthesized gp135 traverses the apical recycling endosome, but not the apical early endosomes (AEEs). In contrast, post‐endocytic gp135 is delivered to the AEE before recycling back to the apical membrane. The pathways pursued by the newly synthesized and recycling gp135 populations do not detectably intersect, demonstrating that the biosynthetic and post‐endocytic pools of this protein are subjected to distinct sorting processes.      

Water transport in maize roots under the influence of mercuric chloride and water stress: a role of water channels

The influence of inhibitor of water channels, HgCl₂, on water diffusion in maize (Zea mays L.) seedling roots was investigated with the pulsed nuclear magnetic resonance (NMR) method. Blocking of water channels decreased the water permeability of cell membranes by 1.5 – 2 times. This effect of HgCl₂ was exhibited only in the roots of seedlings grown in a nutrient solution containing Ca²⁺ and was reversed with Hg-scavenging agent β-mercaptoethanol. Subsequent incubation of Ca²⁺-deficient roots in the nutrient solution with Ca²⁺ recovered the sensitivity to HgCl₂. The water stress decreased water diffusion rates similarly to HgCl₂ and the effects of water stress and HgCl₂ were not additive. The obtained data demonstrate the possibilities of the pulsed NMR method for study of the transmembrane water exchange in vivo in connection with water channel functioning.     

HgCl2-induced alteration of actin filaments in cultured primary rat proximal tubule epithelial cells labelled with fluorescein phalloidin

When proximal tubule epithelial cells are exposed to HgCl₂, cytoplasmic blebs are formed. These represent on early, potentially reversible response to injury. These blebs are accompanied by reorganization of cytoskeletal proteins, and pre-sumably by alternations in cytoskeletal-plasma membrane interactions. Ca²⁺-activated proteinases, such as calpain, are known to affect cytoskeletal proteins and to be involved in diverse cellular processes. However, the role of calpains in cytotoxicity d due to HgCl₂ is unknown. To determine the relationship between Factin, calpain, and HgCl₂ toxicity, cells were stained with fluorescein phalloidin before and after treatment with HgCl₂. Cells were grown on coverslips and exposed to HgCl₂ (10 or 25 M) in the presence or absence of the calpain inhibitor, leupeptin. Untreated cells were flat, polygonal, and contained many fluorescent-stained cables of actin filaments. Generally, cells exposed to HgCl₂ became pleomorphic and contracted as the blebs formed. These cells showed fewer actin cables and fluorescence was seen mostly as either compact areas of dense stain or as peripheral rings. In many cells, actin cables and filaments were completely absent. Disappearance of F-actin was initially seen by 2 min after exposure to HgCl₂. Thus, disruption of the actin cytoskeleton and blebbing were found to be early events in HgCl₂ toxicity. When leupeptin was used with HgCl₂ treatment, the actin staining appeared similar to that of untreated cells. These findings clearly illustrate that HgCl₂ injury to proximal tubule epithelial cells causes rearrangement and alteration of F-actin which may involve the activation of calpain.Abbreviations HgCl₂ mercuric chloride - PTE proximal tubule epithelium - [Ca²⁺]_i cytosolic ionized calcium - [Ca²⁺]_e extracellular calcium - PBS phosphate buffered saline Supported by Navy N00014-88-K-0427 & NIH DK15440. This is contribution No. 2905 from the Cellular Pathobiology Laboratory.     

Osmotic Water Permeability of Vacuolar and Plasma Membranes Isolated from Maize Roots

The method of stopped flow was used to follow the changes in light scattering by the vesicles of plasmalemma and tonoplast isolated from maize (Zea maysL.) roots and treated by osmotic pressure. In both membrane preparations, the rate of the process depended on the osmotic gradient and was described with the simple exponential function. The rate constants derived from these functions were the following: the coefficient of water permeability in the tonoplast (P= 165 ± 7 m/s) exceeded by an order of magnitude the corresponding index for plasmalemma (11 ± 2 m/s). The presence of HgCl₂(1.6 nmol/g membrane protein) decreased the tonoplast water permeability by 80%. Microviscosity studies of the hydrocarbon zone in the isolated membranes by using a fluorescent diphenylhexatriene probe demonstrated that the two membranes do not differ in the phase state of their lipid bilayer. The authors conclude that the observed difference in water permeability does not depend on the state of the lipid phase and probably reflects the dissimilar functional activity of plasmalemma and tonoplast aquaporins.     

Evidence for permanent water channels in the basolateral membrane of an ADH-sensitive epithelium

Summary The transepithelial water permeability in frog urinary bladder is believed to be essentially dependent on the ADH-regulated apical water permeability. To get a better understanding of the transmural water movement, the diffusional water permeability (P _d) of the basolateral membrane of urinary bladder was studied. Access to this post-luminal barrier was made possible by perforating the apical membrane with amphotericin B. The addition of this antibiotic increasedP _d from 1.12±0.10×10^–4 cm/sec (n=7) to 4.08±0.33×10^–4 cm/sec (n=7). The effect of mercuric sulfhydryl reagents, which are commonly used to characterize water channels, was tested on amphotericin B-treated bladders. HgCl₂ (10^–3 m) decreasedP _d by 52% andpara-chloromercuribenzoic acid (pCMB) (1.4×10^–4 m) by 34%. The activation energy for the diffusional water transport was found to increase from 4.52±0.23 kcal/mol (n=3), in the control situation, to 9.99±0.91 kcal/mol (n=4) in the presence of 1.4×10^–4 m pCMB. Our second approach was to measure the kinetics of water efflux, by stop-flow light scattering, on isolated epithelial cells from urinary bladders.pCMB (0.5 or 1.4×10^–4 m) was found to inhibit water exit by 91±2%. These data strongly support the existence of proteins responsible for water transport across the basolateral membrane, which are permanently present.     

Synaptophysin is sorted from endocytotic markers in neuroendocrine PC12 cells but not transfected fibroblasts

The targeting of synaptophysin, a major synaptic vesicle protein, in transfected nonneuronal cells has important implications for synaptic vesicle biogenesis, but has proved controversial. We have analyzed four transfected cell types by differential centrifugation and velocity gradient sedimentation to determine whether synaptophysin is targeted to endosomes or to synaptic vesicle-like structures. Synaptophysin was recovered only in vesicles that sedimented more rapidly than synaptic vesicles. The synaptophysin-containing vesicles were labeled if a surface-labeled cell was warmed to 37 degrees C, comigrated with transferrin receptor-containing vesicles on velocity and density gradients, and could be completely immunoadsorbed by anti-LDL receptor tail antibodies. These data demonstrate that synaptophysin was targeted to the early endocytotic pathway in the transfected cells and are inconsistent with the suggestion that synaptophysin expression induces a novel population of vesicles. Targeting of synaptophysin to early endosomes implicates their role in synaptic vesicle biogenesis.     

Membrane Organization and Dynamics in Cell Polarity

The establishment and maintenance of cell polarity is important to a wide range of biological processes ranging from chemotaxis to embryogenesis. An essential feature of cell polarity is the asymmetric organization of proteins and lipids in the plasma membrane. In this article, we discuss how polarity regulators such as small GTP-binding proteins and phospholipids spatially and kinetically control vesicular trafficking and membrane organization. Conversely, we discuss how membrane trafficking contributes to cell polarization through delivery of polarity determinants and regulators to the plasma membrane.Cell polarity is essential in most if not all eukaryotes for their development and physiological functions at the tissue and organism level. Although there are significant differences in gross morphology and function among various tissues and organisms, at the cellular level, the establishment and maintenance of cell polarity tend to follow common themes.A basic feature of cell polarity is the asymmetric organization of the plasma membrane (see McCaffrey and Macara 2009; Nelson 2009). This is mostly achieved through membrane trafficking along cytoskeleton tracks under the control of signaling molecules. In general, membrane trafficking occurs through sequential budding, transport, and fusion of vesicles from donor membranes to acceptor membranes (for recent reviews, see Bonifacino and Glick 2004; Cai et al. 2007). During budding, protein complexes interact with phospholipids to induce membrane curvature and generate vesicular carriers that capture different cargos from the donor compartments. After vesicles form, they are delivered to their acceptor compartments, most often along the cytoskeletons. Vesicle fusion at the acceptor membrane is mediated by the assembly of SNARE (soluble N-ethylmaleimide-sensitive fusion protein attachment protein receptors) complexes. Before membrane fusion, proteins or protein complexes tether the vesicles to the acceptor membranes and likely promote SNARE assembly. The Arf and Rab family of small GTPases are localized to different membrane compartments and regulate various stages of membrane trafficking.Polarized distribution of proteins at the plasma membrane often results from a balance of vesicle delivery and fusion with the plasma membrane (“exocytosis”), two-dimensional spread through the plasma membrane (“diffusion”), and internalization and membrane recycling (“endocytosis”). There are two main layers of regulation that control polarized protein transport and incorporation to the plasma membrane. The first involves sorting at the trans-Golgi network (TGN) and endosomal compartments, such as the recycling endosomes. Protein sorting involves recognition of sorting signals in the cargo proteins by the adaptor protein (AP) complexes. There are a number of different AP complexes, and each is localized to different membrane compartments and captures distinct sets of cargo proteins before targeting to their correct destination. Protein sorting before delivery to different domains of the plasma membrane has been best characterized in epithelial cells, which have distinctive basolateral and apical domains separated by junctional complexes. This layer of regulation has been discussed in a recent review (Mellman and Nelson 2008) and is further discussed by Nelson (Nelson 2009), so it will not be discussed further here. The second layer of regulation of membrane protein polarization is through the polarized tethering and docking of vesicles at specific domains of the plasma membrane (Fig. 1). Tethering proteins (i.e., the exocyst) target secretory vesicles to specific domains of the plasma membrane and SNARE assembly eventually drives membrane fusion. Proteins at the plasma membrane can be retrieved back into the cell via endocytosis. These proteins are internalized via clathrin-coated pits, and transported through different endosomal compartments either for degradation in the lysosomes or for recycling back to the plasma membrane. The endosomal compartment that mediates the transport of internalized plasma membrane proteins back to the cell surface is called the “recycling endosome.” Recycling endosomes are major sources of cargo destined to the plasma membrane for exocytosis in many types of cells.Open in a separate windowFigure 1.Membrane trafficking to the plasma membrane. Schematic of the endocytic and exocytic routes involving trans-Golgi network (TGN), endosomal compartments, and the plasma membrane. During exocytosis, cargo leaves the TGN or recycling endosomes in vesicular carriers to the plasma membrane. Once on the membrane, proteins can be internalized and transported to early endosomes, and then either travel through late endosomes to the lysosome to be degraded or return to the plasma membrane through the recycling endosomes. Early endosomes may serve as sorting stations for the next stages of cargo transport.Signaling molecules such as the Rho family of small GTPases spatially and kinetically regulate membrane trafficking during cell polarization (see McCaffrey and Macara 2009; Slaughter et al. 2009). Reversely, vesicular trafficking is required for the polarized deposition and accrual of these regulators. In the first part of this article, we examine the membrane organization and dynamics of cell polarity, focusing on the polarized tethering and docking of vesicles at the plasma membrane. We highlight key components and regulators of polarized exocytosis including the exocyst, small GTPases, and phospholipids. We also use different organisms and systems to show analogous mechanisms during cell polarization. In the second part of this article, we focus on the aforementioned reciprocal effects of cell polarity and membrane trafficking using two representative examples, one from yeast (Cdc42 polarization) and one in mammalian epithelial cells (E-cadherin trafficking).     

Cargo Recognition in Clathrin-Mediated Endocytosis

The endosomal system is expansive and complex, characterized by swift morphological transitions, dynamic remodeling of membrane constituents, and intracellular positioning changes. To properly navigate this ever-altering membrane labyrinth, transmembrane protein cargoes typically require specific sorting signals that are decoded by components of protein coats. The best-characterized sorting process within the endosomal system is the rapid internalization of select transmembrane proteins within clathrin-coated vesicles. Endocytic signals consist of linear motifs, conformational determinants, or covalent modifications in the cytosolic domains of transmembrane cargo. These signals are interpreted by a diverse set of clathrin-associated sorting proteins (CLASPs) that translocate from the cytosol to the inner face of the plasma membrane. Signal recognition by CLASPs is highly cooperative, involving additional interactions with phospholipids, Arf GTPases, other CLASPs, and clathrin, and is regulated by large conformational changes and covalent modifications. Related sorting events occur at other endosomal sorting stations.The internalization of a subset of plasma membrane proteins by clathrin-mediated endocytosis is one the best-characterized sorting processes that takes place in the endomembrane system of eukaryotic cells (Kirchhausen 2014). Selection of transmembrane proteins (referred to as “cargo”) for internalization by clathrin-mediated endocytosis involves recognition of endocytic signals in the cytosolic domains of the proteins by adaptors located in the inner layer of clathrin coats. Signal–adaptor interactions lead to concentration of the transmembrane proteins within clathrin-coated pits that eventually bud into the cytoplasm as clathrin-coated vesicles (Kirchhausen 2014). Transmembrane proteins that have endocytic signals are thus rapidly delivered to endosomes, whereas those that lack signals remain at the plasma membrane. This article summarizes recent progress in the elucidation of the mechanisms of signal recognition in clathrin-mediated endocytosis, with additional reference to related intracellular sorting events. Further information on this topic can be found in previous reviews (Bonifacino and Traub 2003; Traub 2009; Kelly and Owen 2011).     

Trafficking of immunoglobulin receptors in epithelial cells:signals and cellular factors

A typical feature of epithelial cells is the polarized distribution of their respective plasma membrane proteins. Apical and basolateral proteins can be sorted both in the trans-Golgi network and endosomes, or in both locations. Inclusion into basolateral carriers in the TGN requires the presence of distinct cytoplasmic determinants, which also appear to be recognized in endosomes. Inactivation of the basolateral sorting information leads to the efficient apical delivery, probably due to the unmasking of a recessive apical signal. Factors associated with the cytosolic face of organelles probably not only recognize these signals to mediate the inclusion of the proteins into the correct transport vesicles, but also target the carriers to the corresponding plasma membrane domain. Our interest has focused on analyzing at the molecular level how epithelial MDCK cells generate and maintain a polarized phenotype, taking advantage of immunoglobulin receptors to study the biosynthetic and endocytic pathways and the corresponding sorting events.     

Evidence for channel mediated transport of boric acid in squash (Cucurbita pepo)

Boron (B) is taken up by plant roots as undissociated boric acid which is a non-electrolyte of similar size to urea and other non-electrolytes. In animal systems, non-electrolytes are transported across biological membranes through aquaporins or through non-aquaporin channels. In artificial lipids boric acid is known to diffuse directly through the lipid bilayer at a rate that is determined by lipid composition. A possible role for channel proteins in in-vitro B uptake is suggested by recent work in which B uptake into isolated membrane vesicles was inhibited by channel blockers and by demonstration that the expression of the plant channel protein PIP1 in Xenopus oocytes increases boric acid uptake by 30%. This study examines whether B transport is a channel-mediated process in intact plants. In the presence of the channel inhibitors HgCl₂, phloretin, and DIDS, B uptake by squash plants was reduced by 40–90% by HgCl₂ (as HgCl₂ varied from 50 M to 1 mM), 44% by phloretin (250 M) and 58% by DIDS (250 M). The effect of Hg ions on B uptake was reversed by 2-mercaptoethanol. The addition of other non-electrolytes in size ranges similar to boric acid inhibited B uptake to various degrees. Addition of urea resulted in 54% decrease in B uptake, while, acetamide, formamide, thiourea and glycerol inhibited uptake by 50, 35, 53 and 44%, respectively. The effect of HgCl₂ on B uptake was greater at high B concentrations than at low B concentrations. These data and information from in-vivo studies suggest two possible mechanisms of B uptake: passive diffusion through lipid bilayers and channel-mediated transport.