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)     

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.     

大鼠肾近球小管细胞胞饮体膜氢泵活性和水的渗透性转运的特征

本实验采用异硫氰酸-葡聚糖荧光素(fluorescein isothiocyanate-dextran,FITC-dextran)体内标记法,研究大鼠肾近球小管细胞胞饮体(endosome)膜上 H~+-ATP 酶的活性及水的渗透性转运。通过观察在胞饮体外加入一定量 ATP 后,胞饮体内 pH 值的时间反应曲线,从而测定 ATP-依赖的 H~+在胞饮体膜上的转运情况。胞饮体内的酸化速度及 pH 的最低值与加入的 ATP 浓度有关。在加入 ATP 前,胞饮体内的 pH 值为7.4,加入不同浓度的 ATP 后,即[ATP]为0.005,0.05,0.5,5和10mmol/L,胞饮体内 pH 最低值分别为7.30,6.99,6.68,6.38和6.39。此种由 ATP 引起的酸化反应,被0.5mmol/L N-ethylmaleimide(NEM)抑制97%,但不被钒酸盐和 oligomycin 所抑制。实验还同时观察了此种胞饮体水的渗透性转运机制。通过在胞饮体膜内外建立一个蔗糖浓度梯度。观察 FITC-dextran 荧光信号的快速动力学变化过程,从而测定由于渗透压梯度引起的水在胞饮体膜上转运的特征。在230℃时,水的渗透性通透系数(osmotic water permeability coefficient,P_f)为0.03cm/s;加入0.5mmol/L HgCl_2后,水的转运被抑制70%。此抑制反应可被5mmol/L 巯基乙醇(β-Mcrcaptoethanol)完全逆转。上述结果提示:大鼠肾近球小管胞饮体膜含有H~+-ATP 酶和水的转运通道。胞饮     

Acidification of endocytic vesicles by an ATP-dependent proton pump

One of the early events in the pathway of receptor-mediated endocytosis is the acidification of the newly formed endocytic vesicle. To examine the mechanism of acidification, we used fluorescein-labeled alpha 2- macroglobulin (F-alpha 2M) as a probe for endocytic vesicle pH. Changes in pH were determined from the change in fluorescein fluorescence at 490-nm excitation as measured with a microscope spectrofluorometer. After endocytosis of F-alpha 2M, mouse fibroblast cells were permeabilized by brief exposure to the detergent digitonin. Treatment with the ionophore monensin or the protonophore carbonyl cyanide p- trifluoromethoxyphenylhydrazone (FCCP) caused a rapid increase in the pH of the endocytic vesicle. Upon removal of the ionophore, the endocytic vesicle rapidly acidified only when MgATP or MgGTP was added. Neither ADP nor the nonhydrolyzable analog, adenosine 5'-(beta, gamma- imido)triphosphate (AMP-PNP) could support acidification. The ATP- dependent acidification did not require a specific cation or anion in the external media. Acidification was insensitive to vanadate and amiloride but was inhibited by Zn2+ and the anion transport inhibitor diisothiocyanostilbene disulfonic acid (DIDS). We also examined the acidification of lysosomes with the permeabilized cell system, using fluorescein isothiocyanate dextran as probe. DIDS inhibited the ATP- dependent reacidification of lysosomes, although at a lower concentration than that for inhibition of endocytic vesicle reacidification. These results demonstrate that endocytic vesicles contain an ATP-dependent acidification mechanism that shares similar characteristics with the previously described lysosomal proton pump.     

Rapid acidification of endocytic vesicles containing asialoglycoprotein in cells of a human hepatoma line

Acidification of endocytic vesicles has been implicated as a necessary step in various processes including receptor recycling, virus penetration, and the entry of diphtheria toxin into cells. However, there have been few accurate pH measurements in morphologically and biochemically defined endocytic compartments. In this paper, we show that prelysosomal endocytic vesicles in HepG2 human hepatoma cells have an internal pH of approximately 5.4. (We previously reported that similar vesicles in mouse fibroblasts have a pH of 5.0.) The pH values were obtained from the fluorescence excitation profile after internalization of fluorescein labeled asialo-orosomucoid (ASOR). To make fluorescence measurements against the high autofluorescence background, we developed digital image analysis methods for estimating the pH within individual endocytic vesicles or lysosomes. Ultrastructural localization with colloidal gold ASOR demonstrated that the pH measurements were made when ligand was in tubulovesicular structures lacking acid phosphatase activity. Biochemical studies with 125I-ASOR demonstrated that acidification precedes degradation by more than 30 min at 37 degrees C. At 23 degrees C ligand degradation ceases almost entirely, but endocytic vesicle acidification and receptor recycling continue. These results demonstrate that acidification of endocytic vesicles, which causes ligand dissociation, occurs without fusion of endocytic vesicles with lysosomes. Methylamine and monensin raise the pH of endocytic vesicles and cause a ligand-independent loss of receptors. The effects on endocytic vesicle pH are rapidly reversible upon removal of the perturbant, but the effects on cell surface receptors are slowly reversible with methylamine and essentially irreversible with monensin. This suggests that monensin can block receptor recycling at a highly sensitive step beyond the acidification of endocytic vesicles. Taken together with other direct and indirect estimates of endocytic vesicle pH, these studies indicate that endocytic vesicles in many cell types rapidly acidify below pH 5.5, a pH sufficiently acidic to allow receptor-ligand dissociation and the penetration of some toxin chains and enveloped virus nucleocapsids into the cytoplasm.     

Very high water permeability in vasopressin-induced endocytic vesicles from toad urinary bladder

The regulation of transepithelial water permeability in toad urinary bladder is believed to involve a cycling of endocytic vesicles containing water transporters between an intracellular compartment and the cell luminal membrane. Endocytic vesicles arising from luminal membrane were labeled selectively in the intact toad bladder with the impermeant fluid-phase markers 6-carboxyfluorescein (6CF) or fluorescein-dextran. A microsomal preparation containing labeled endocytic vesicles was prepared by cell scraping, homogenization, and differential centrifugation. Osmotic water permeability was measured by a stopped-flow fluorescence technique in which microsomes containing 50 mM mannitol, 5 mM K phosphate, pH 8.5 were subject to a 60-mM inwardly directed gradient of sucrose; the time course of endosome volume, representing osmotic water transport, was inferred from the time course of fluorescence self-quenching. Endocytic vesicles were prepared from toad bladders with hypoosmotic lumen solution treated with (group A) or without (group B) serosal vasopressin at 23 degrees C, and bladders in which endocytosis was inhibited by treatment with vasopressin at 0-2 degrees C (group C), or with vasopressin plus sodium azide at 23 degrees C (group D). Stopped-flow results in all four groups showed a slow rate of 6CF fluorescence decrease (time constants 1.0-1.7 s for exponential fit) indicating a component of nonendocytic 6CF entrapment into sealed vesicles. However, in vesicles from group A only, there was a very rapid 6CF fluorescence decrease (time constant 9.6 +/- 0.2 ms, SEM, 18 separate preparations) with an osmotic water permeability coefficient (Pf) of greater than 0.1 cm/s (18 degrees C) and activation energy of 3.9 +/- 0.8 kcal/mol (16 kJ/mol). Pf was inhibited reversibly by greater than 60% by 1 mM HgCl2. The rapid fluorescence decrease was absent in vesicles in groups B, C, and D. These results demonstrate the presence of functional water transporters in vasopressin-induced endocytic vesicles from toad bladder, supporting the hypothesis that water channels are cycled to and from the luminal membrane and providing a functional marker for the vasopressin-sensitive water channel. The calculated Pf in the vasopressin-induced endocytic vesicles is the highest Pf reported for any biological or artificial membrane.     

Apical and basolateral endocytic pathways of MDCK cells meet in acidic common endosomes distinct from a nearly-neutral apical recycling endosome

Quantitative confocal microscopic analyses of living, polarized MDCK cells demonstrate different pH profiles for apical and basolateral endocytic pathways, despite a rapid and extensive intersection between the two. Three-dimensional characterizations of ligand trafficking demonstrate that the apical and basolateral endocytic pathways share early, acidic compartments distributed throughout the medial regions of the cell. Polar sorting for both pathways occurs in these common endosomes as IgA is sorted from transferrin to alkaline transcytotic vesicles. While transferrin is directly recycled from the common endosomes, IgA is transported to a downstream apical compartment that is nearly neutral in pH. By several criteria this compartment appears to be equivalent to the previously described apical recycling endosome. The functional significance of the abrupt increase in lumenal pH that accompanies IgA sorting is not clear, as disrupting endosome acidification has no effect on polar sorting. These studies provide the first detailed characterizations of endosome acidification in intact polarized cells and clarify the relationship between the apical and basolateral endocytic itineraries of polarized MDCK cells. The extensive mixing of apical and basolateral pathways underscores the importance of endocytic sorting in maintaining the polarity of the plasma membrane of MDCK cells.     

Identification and characterization of ATP-dependent proton transport by rat liver multivesicular bodies

Multivesicular bodies (MVB), prelysosomal organelles in the endocytic pathway, were prepared from estrogen-treated rat livers and examined for the presence of ATP-dependent proton transport. Vesicle acidification, assessed by acridine orange fluorescence quenching, was ATP dependent (ATP much greater than GTP, UTP), was enriched 25-fold over homogenate, was abolished by pretreatment with protonophores or a nonionic detergent, exhibited a pH optimum of 7.5, was inhibited by N-ethylmaleimide (NEM) (IC50 approximately 5 microM) and N,N'-dicyclohexylcarbodiimide (IC50 approximately 5 microM), and was resistant to inhibition by vanadate, ouabain, and oligomycin. Acidification exhibited no specific cation requirement; however, maximal rates of acidification depended upon the presence of Cl- (Km approximately 20 mM). Other anions were less effective in supporting acidification (Cl- greater than Br- greater than much greater than gluconate, NO-3, SO2-4, and mannitol), and indeed NO-3 inhibited acidification even in the presence of 150 mM Cl-. The proton transport mechanism appeared to be electrogenic based on: (a) enhancement of acidification by valinomycin in the presence of K gluconate, and (b) ATP-dependent fluorescence quenching of bis(3-phenyl-5-oxoisoxasol-4-yl)pentamethine oxonol, a membrane potential-sensitive anionic dye. Furthermore, the magnitude of the pH and electrical gradients generated by the proton transport mechanism appeared to vary inversely in the presence and absence of Cl-. Finally, MVB exhibited ATPase activity that was resistant to ouabain and oligomycin, but was inhibited 32.3% by 1 mM NEM, 33.7% by 200 microM dicyclohexylcarbodiimide, and 18.7% by KNO3. In isolated MVB, therefore, the NEM-sensitive ATPase activity may represent the enzymatic equivalent of a proton pump. These studies identify and characterize an ATP-dependent electrogenic proton transport process in rat liver MVB which shares many of the properties of the proton pump described in clathrin-coated vesicles, endosomes, lysosomes, Golgi, and endoplasmic reticulum from liver and other tissues. Acidification of MVB differed somewhat from that of rat liver clathrin-coated vesicles in response to Br- and NO-3, suggesting that membrane properties of these two organelles might differ.     

Mobilization of iron from endocytic vesicles. The effects of acidification and reduction

The factors necessary to dissociate iron from transferrin in endocytic vesicles and to mobilize the iron across the vesicle membrane were studied in a preparation of endocytic vesicles markedly enriched in transferrin-transferrin receptor complexes isolated from rabbit reticulocytes. Vesicles were prepared with essentially fully saturated transferrin by incubating the reticulocytes with the protonophore carbonyl cyanide 4-(trifluoromethoxy)phenylhydrazone prior to incubation with 59Fe, 125I-transferrin with or without fluorescein isothiocyanate labeling. Initiation of acidification by the addition of ATP was sufficient to achieve dissociation of 59Fe from transferrin with a rate constant of 0.054 +/- 0.06 s-1. Mobilization of 59Fe out of the vesicles required, besides ATP, the addition of a reductant with 1 mM ascorbate, allowing approximately 60% mobilization at 10 min with a rate constant of 0.0038 +/- 0.0006 s-1. An NADH:ferricyanide reductase activity could be demonstrated in the vesicles with an activity of 7.1 x 10(-9) mol of NADH reduced per min/mg of vesicle protein. Both dissociation and mobilization were inhibited by N-ethylmaleimide, carbonyl cyanide 4-(trifluoromethoxy)phenylhydrazone, and monensin. Mobilization, but not dissociation, was inhibited by the permeant Fe(II) chelator alpha,alpha'-dipyridyl. The Fe(III) chelators deferoxamine, diethylenetriaminepentaacetic acid, and apotransferrin did not promote mobilization of dissociated iron in the absence of a reductant. This study establishes the basis for the cellular incorporation of iron through the endocytic pathway in which the endocytic vesicle membrane utilizes, in a sequential way, an acidification system, an iron reduction system, and an Fe(II) transporter system.     

ATP-dependent acidification of membrane vesicles isolated from purified rat liver lysosomes. Acidification activity requires phosphate

Membrane vesicles were isolated from purified liver lysosomes of rats treated with Triton WR-1339. In order to preserve ATP-dependent acidification activity, proteolysis of membranes was minimized by adding protease inhibitors and by centrifuging to form dilute bands of vesicles rather than highly concentrated pellets. The membrane vesicle fraction represented about 20% of the total lysosomal protein, 80% of the ATPase activity, and 3% of the solute proteins as marked by N-acetylglucosaminidase. About one-half of the membranes were oriented right side out. The space unavailable to [14C]sucrose corresponded to 3 microliters/mg of membrane protein which indicates that the membranes form vesicles about one-tenth the size of lysosomes. Uptake of either [14C]methylamine or [14C]chloroquine by lysosomal membrane vesicles was ATP-dependent, indicating acidification of the intravesicle space. The acidification activity was inhibited when either 1.5 microM carbonyl cyanide p-trifluoromethoxy-phenylhydrazone, 100 microM dicyclohexylcarbodiimide, or millimolar concentrations of such permeant weak bases as ammonium sulfate and dansyl cadaverine were added. Acidification of lysosomal vesicles by ATP occurred electroneutrally. This acidification activity was not dependent on added salts but was inhibited by the anion transport inhibitors pyridoxal phosphate and diisothiocyanostilbene disulfonic acid, thus suggesting co-transport of protons and anions. Results which indicate that phosphate is the transported anion included (a) ATP-dependent uptake of [32P]phosphate by lysosomal membrane vesicles and (b) stimulation of ATP-dependent acidification of these vesicles by added phosphate. These observations provide further evidence that maintenance of the acid intralysosomal pH necessary for activation of lysosomal hydrolases is due to an ATP-driven proton pump located in the lysosomal membrane.     

Weak bases and ionophores rapidly and reversibly raise the pH of endocytic vesicles in cultured mouse fibroblasts

It has been shown that endocytic vesicles in BALB/c 3T3 cells have a pH of 5.0 (Tycko and Maxfield, Cell, 28:643-651). In this paper, a method for measuring the effect of various agents, including weak bases and ionophores, on the pH of endocytic vesicles is presented. The method is based on the increase in fluorescein fluorescence with 490-nm excitation as the pH is raised above 5.0. Intensities of cells were measured using a microscope spectrofluorometer after internalization of fluorescein-labeled alpha 2-macroglobulin by receptor-mediated endocytosis. The increase in endocytic vesicle pH was determined from the increase in fluorescence after addition of various concentrations of the test agents. The following agents increased endocytic vesicle pH above 6.0 at the indicated concentrations: monensin (6 microM), FCCP (10 microM), chloroquine (140 microM), ammonia (5 mM), methylamine (10 mM). The ability of many of these agents to raise endocytic vesicle pH may account for many of their effects on receptor-mediated endocytosis. Dansylcadaverine caused no effect on vesicle pH at 1 mM. The observed increases in vesicle pH were rapid (1-2 min) and could be reversed by removal of the perturbant. This reversibility indicates that the vesicles themselves contain a mechanism for acidification. The increase in vesicle pH due to these treatments can be observed visually using an SIT video camera. Using this method, it is shown that endocytic vesicles become acidic at very early times (i.e., within 5-7 min of continuous uptake at 37 degrees C).     

Myo6 facilitates the translocation of endocytic vesicles from cell peripheries

Immunolocalization studies in epithelial cells revealed myo6 was associated with peripherally located vesicles that contained the transferrin receptor. Pulse-chase experiments after transferrin uptake showed that these vesicles were newly uncoated endocytic vesicles and that myo6 was recruited to these vesicles immediately after uncoating. GIPC, a putative myo6 tail binding protein, was also present. Myo6 was not present on early endosomes, suggesting that myo6 has a transient association with endocytic vesicles and is released upon early endosome fusion. Green fluorescent protein (GFP) fused to myo6 as well as the cargo-binding tail (M6tail) alone targeted to the nascent endocytic vesicles. Overexpression of GFP-M6tail had no effect on a variety of organelle markers; however, GFP-M6tail displaced the endogenous myo6 from nascent vesicles and resulted in a significant delay in transferrin uptake. Pulse-chase experiments revealed that transferrin accumulated in uncoated vesicles within the peripheries of transfected cells and that Rab5 was recruited to the surface of these vesicles. Given sufficient time, the transferrin did traffic to the perinuclear sorting endosome. These data suggest that myo6 is an accessory protein required for the efficient transportation of nascent endocytic vesicles from the actin-rich peripheries of epithelial cells, allowing for timely fusion of endocytic vesicles with the early endosome.     

Acidification and ion permeabilities of highly purified rat liver endosomes

While it is well established that acidic pH in endosomes plays a critical role in mediating the orderly traffic of receptors and ligands during endocytosis, little is known about the bioenergetics or regulation of endosome acidification. Using highly enriched fractions of rat liver endosomes prepared by free flow electrophoresis and sucrose density gradient centrifugation, we have analyzed the mechanism of ATP-dependent acidification and ion permeability properties of the endosomal membrane. This procedure permitted the isolation of endosome fractions which were up to 200-fold enriched as indicated by the increased specific activity of ATP-dependent proton transport. Acidification was monitored using hepatocyte and total liver endosomes selectively labeled with pH-sensitive markers of receptor-mediated endocytosis (fluorescein isothiocyanate asialoorosomucoid) or fluid-phase endocytosis (fluorescein isothiocyanate-dextran). In addition, changes in membrane potential accompanying ATP-dependent acidification were directly measured using the voltage-sensitive fluorescent dye Di-S-C3(5). Our results indicate that ATP-dependent acidification of liver endosomes is electrogenic, with proton transport being accompanied by the generation of an interior-positive membrane potential opposing further acidification. The membrane potential can be dissipated by the influx of permeant external anions or efflux of internal alkali cations. Replacement externally of permeable anions with less permeable anions (e.g. replacing Cl- with gluconate) diminished acidification, as did replacement internally of a more permeant cation K+ with less permeant species (such as Na+ or tetramethylammonium). ATP-dependent H+ transport was not coupled to any specific anion or cation, however. The endosomal membrane was found to be extremely permeable to protons, with protons able to leak out almost as fast as they are pumped in. Thus, the internal pH of endosomes is likely to reflect a dynamic equilibrium of protons regulated by the intrinsic ion permeabilities of the endosomal membrane, in addition to the activity of an ATP-driven proton pump.     

Functional colocalization of water channels and proton pumps in endosomes from kidney proximal tubule

The apical membrane of mammalian proximal tubule undergoes rapid membrane cycling by exocytosis and endocytosis. Osmotic water and ATP- driven proton transport were measured in endocytic vesicles from rabbit and rat proximal tubule apical membrane labeled in vivo with the fluid phase marker fluorescein-dextran. Osmotic water permeability (Pf) was determined from the time course of fluorescein-dextran fluorescence after exposure of endosomes to an inward osmotic gradient in a stopped- flow apparatus. Pf was 0.009 (rabbit) and 0.029 cm/s (rat) (23 degrees C) and independent of osmotic gradient size. Pf in rabbit endosomes was inhibited reversibly by HgCl2 (KI = 0.2 mM) and had an activation energy of 6.4 +/- 0.5 kcal/mol (15-35 degrees C). Endosomal proton ATPase activity was measured from the time course of internal pH, measured by fluorescein-dextran fluorescence, after the addition of external ATP. Endosomes contained an ATP-driven proton pump that was sensitive to N-ethylmaleimide and insensitive to vanadate and oligomycin. In response to saturating [ATP] the pump acidified the endosomal compartment at a rate of 0.17 (rat) and 0.029 pH unit/s (rabbit); at an external pH of 7.4, the steady-state pH was 6.4 (rat) and 6.5 (rabbit). To examine whether water channels and the proton ATPase were present in the same endosome, the time course of fluorescein-dextran fluorescence was measured in response to an osmotic gradient in the presence and absence of ATP. ATP did not alter endosome Pf, but decreased the amplitude of the fluorescence signal by 43 +/- 3% (rabbit) and 47 +/- 4% (rat).(ABSTRACT TRUNCATED AT 250 WORDS)     

Kinetic characterization of reductant dependent processes of iron mobilization from endocytic vesicles.

The reductant dependence of iron mobilization from isolated rabbit reticulocyte endosomes containing diferric transferrin is reported. The kinetic effects of acidification by a H(+)-ATPase are eliminated by incubating the endosomes at pH 6.0 in the presence of 15 microM FCCP to acidify the intravesicular milieu and to dissociate 59Fe(III) from transferrin. In the absence of reductants, iron is not released from the vesicles, and iron leakage is negligible. The second-order dependence of rate constants and amounts of 59Fe mobilized from endosomes using ascorbate, ferrocyanide, or NADH are consistent with reversible mechanisms. The estimated apparent first-order rate constant for mobilization by ascorbate is (2.7 +/- 0.4) x 10(-3) s-1 in contrast to (3.2 +/- 0.1) x 10(-4) s-1 for NADH and (3.5 +/- 0.6) x 10(-4) s-1 for ferrocyanide. These results support models where multiple reactions are involved in complex processes leading to iron transfer and membrane translocation. A type II NADH dehydrogenase (diaphorase) is present on the endosome outer membrane. The kinetics of extravesicular ferricyanide reduction indicate a bimolecular-bimolecular steady-state mechanism with substrate inhibition. Ferricyanide inhibition of 59Fe mobilization is not detected. Significant differences between mobilization and ferricyanide reduction kinetics indicate that the diaphorase is not involved in 59Fe(III) reduction. Sequential additions of NADH followed by ascorbate or vice versa indicate a minimum of two sites of 59Fe(III) residence; one site available to reducing equivalents from ascorbate and a different site available to NADH. Sequential additions using ferrocyanide and the other reductants suggest interactions among sites available for reduction. Inhibition of ascorbate-mediated mobilization by DCCD and enhancement of ferrocyanide and NADH-mediated mobilization suggest a role for a moiety with characteristics of a proton pore similar to that of the H(+)-ATPase. These data provide significant constraints on models of iron reduction, translocation, and mobilization by endocytic vesicles.     

Measurements of the acidification kinetics of single SynaptopHluorin vesicles

Uptake of neurotransmitters into synaptic vesicles is driven by the proton gradient established across the vesicle membrane. The acidification of synaptic vesicles, therefore, is a crucial component of vesicle function. Here we present measurements of acidification rate constants from isolated, single synaptic vesicles. Vesicles were purified from mice expressing a fusion protein termed SynaptopHluorin created by the fusion of VAMP/synaptobrevin to the pH-sensitive super-ecliptic green fluorescent protein. We calibrated SynaptopHluorin fluorescence to determine the relationship between fluorescence intensity and internal vesicle pH, and used these values to measure the rate constant of vesicle acidification. We also measured the effects of ATP, glutamate, and chloride on acidification. We report acidification time constants of 500 ms to 1 s. The rate of acidification increased with increasing extravesicular concentrations of ATP and glutamate. These data provide an upper and a lower bound for vesicle acidification and indicate that vesicle readiness can be regulated by changes in energy and transmitter availability.     

Evidence for two endocytic transport pathways in plant cells

Intracellular trafficking of endocytic vesicles in eukaryotes varies with the nature of the cargo molecules and the targeted organelle, and proceeds through an intricate network of internal endosomal compartments. However, the path for fluid-phase endocytosis (FPE), the internalization of external solutes from the apoplast via plasmalemma generated vesicles, remains unresolved despite some indication of a direct transport route to the vacuole. To test this hypothesis, we made use of the membrane-impermeable Na-dependent fluorescent marker Coro-Na in combination with the fluorescent membrane marker FM 4-64 and confocal laser scanning microscopy. When protoplasts from sweet lime juice cells were incubated in Na-free solution, FM 4-64, Coro-Na, and 200 mM sucrose, two distinct types of labeled vesicles were evident. A set of vesicles (1 μm in diameter) was intensely labeled with Coro-Na and to a lesser extent with FM 4-64, whereas the second type of 1–7 μm structures appeared exclusively labeled with FM 4-64. These data demonstrate the parallel functioning of two endocytic pathways in plant cells. In one system, a set of small endocytic vesicles merge with the endosome, whereas a separate set of vesicles fuse to form larger vesicles independent from the endosome. Although it is likely that both vesicle systems eventually contribute to solutes reaching the vacuole, given their size (1–7 μm), and based on previous observations of endocytic vesicle formation protruding from the plasmalemma and merging with the vacuole, we conclude that these latter vesicles constitute the primary FPE vesicle system.     

Motor protein independent binding of endocytic carrier vesicles to microtubules in vitro

We have established an in vitro assay to characterize the binding of endocytic carrier vesicles to microtubules. Magnetic beads coated with microtubules were used as an affinity matrix. A fraction from nocodazole-treated cells enriched in endocytic carrier vesicles, labeled with internalized horseradish peroxidase, was used in the binding experiments. Binding of the endocytic carrier vesicles to microtubules in vitro was cytosol-dependent. This activity of cytosolic factors was saturable, heat-sensitive, and insensitive to N-ethyl-maleimide. Binding was sensitive to GTP and ATP. Addition of neuronal microtubule-associated proteins completely abolished binding of the endocytic organelles to microtubules. This binding was independent of the cytosolic microtubule-based motor proteins kinesin and cytoplasmic dynein, since cytosol depleted of these proteins remained fully active. Microtubule-binding proteins from HeLa cells, however, stimulated the interaction of endocytic carrier vesicles with microtubules. Trypsinized vesicles could no longer bind to microtubules in the presence of cytosol. These results suggest that cytosolic microtubule-binding proteins, other than the known microtubule-based motor proteins, as well as membrane proteins are involved in the nucleotide-dependent interaction of endocytic carrier vesicles with microtubules.     

Rapid acidification of endocytic vesicles containing alpha 2-macroglobulin

We have used fluorescein-labeled alpha 2-macroglobulin (F-alpha 2M) to measure pH changes in the microenvironment of internalized ligands following receptor-mediated endocytosis. Fluorescence intensities of single BALB/c 3T3 mouse fibroblasts were measured by using a microscope spectrofluorometer with narrow bandpass excitation filters. The pH was determined from the ratio of fluorescein fluorescence intensities with 450 nm and 490 nm excitation. A standard pH curve was obtained by incubating cells with F-alpha 2M for 30 min at 37 degrees C followed by fixation and incubation in buffers of varying pH. To measure the pH of endocytic vesicles, cells were incubated with F-alpha 2M for 15 min at 37 degrees C. Fluorescence intensities were measured on living cells within 5 min of rinsing. Under these conditions, the pH of the F-alpha 2M microenvironment was 5.0 +/- 0.2. Using colloidal gold-alpha 2M for electron microscopic localizations we have verified that, under these conditions, alpha 2M is predominantly in uncoated vesicles that are negative for acid phosphatase activity. With further incubation for 1/2 hr, we obtained a pH of 5.0 +/- 0.2 for the F-alpha 2M. Using fluorescein dextran, we obtained a lysosomal pH of 4.6 +/- 0.2. These results indicate that endocytic vesicles become acidic prior to fusion with lysosomes.