Intramembrane particle structures in epithelial cells of the toad urinary bladder: a quantitative freeze-fracture study

Freeze-fracture electron microscopy reveals intramembrane particle arrays in basal membranes of granular epithelial cells as well as both upper and lower plasma membranes of the underlying basal cells in the toad urinary bladder. These particle arrays are morphologically indistinguishable from the luminal membrane aggregates which are known to be associated with antidiuretic hormone (ADH)-stimulated water transport. In both granular and basal cells particle arrays are frequently located in and/or around the openings of vesicular and/or tubular structures fused to the plasma membranes, suggesting that they may be transferred from the cytoplasm by membrane fusion. Quantification of cytoplasmic aggrephores in control granular cells shows that they can be numerous and as close to the basolateral membrane as they are with the luminal membrane, to which they are known to fuse and deliver aggregates upon ADH stimulation. Aggrephore-like tubules were also found in the basal cells. Particle array densities were quantified for 6 pairs of control and ADH-stimulated hemibladders. At least 1440 microns 2 area of plasma membrane for each membrane domain was examined. Results indicate that the presence of these particle arrays in granular and basal cell membranes is highly variable and that exposure to ADH does not cause a statistically significant increase in their frequency.     

Visualization of endocytosed markers in freeze-fracture studies of toad urinary bladder

Antidiuretic hormone (ADH) stimulation increases the apical membrane water permeability of granular cells in toad urinary bladder. This response correlates closely with the fusion of tubular cytoplasmic vesicles with the membrane and delivery of intramembrane particle (IMP) aggregates from the tubules (aggrephores) to the apical membrane. These aggregates are believed to be associated with the channels responsible for the water permeability increase. Removal of ADH triggers apical membrane endocytosis and disappearance of aggregates from the apical membrane. However, it has been unclear whether aggregate disappearance is due to disassembly of aggregates within the apical membrane or to their endocytic retrieval as intact structures. Using colloidal gold and horseradish peroxidase to follow endocytosis from the apical surface after ADH removal, we have directly observed in cross-fractured bladder cells the intramembrane structure of intracellular vesicles that contain these fluid-phase markers. Under these conditions, intact aggregates can be identified in the membrane of tubular endocytosed vesicles. This directly demonstrates that conditions which lower apical membrane water permeability cause the tubular aggrephores to "shuttle" intact aggregates from the apical membrane back into the cytoplasm. An additional population of vesicles with tracer are found which are spherical and display structural features of the apical membrane, as well as occasional aggregates. These vesicles may be responsible for retrieval of aggregates from the surface apical membrane.     

Isolation and characterization of specialized regions of toad urinary bladder apical plasma membrane involved in the water permeability response to antidiuretic hormone

Summary Antidiuretic hormone (ADH) increases the apical (external facing) membrane water permeability of granular cells that line the toad urinary bladder. In response to ADH, cytoplasmic vesicles called aggrephores fuse with the apical plasma membrane and insert particle aggregates which are visualized by freeze-fracture electron microscopy. Aggrephores contain particle aggregates within their limiting membranes. It is generally accepted that particle aggregates are or are related to water channels. High rates of transepithelial water flow during ADH stimulation and subsequent hormone removal decrease water permeability and cause the endocytosis of apical membrane and aggrephores which retrieve particle aggregates. We loaded the particle aggregate-rich endocytic vesicles with horseradish peroxidase (HRP) during ADH stimulation and removal. Epithelial cells were isolated and homogenized, and a subcellular fraction was enriched for sequestered HRP obtained. The HRP-enriched membrane fraction was subjected to a density shifting maneuver (Courtoy et al.,J. Cell Biol. 98:870, 1984), which yielded a purified membrane fraction containing vesicles with entrapped HRP. The density shifted vesicles were composed of approximately 20 proteins including prominent species of 55, 17 and 7 kD. Proteins of these molecular weights appear on the apical surface of ADH-stimulated bladders, but not the apical surface of control bladders. Therefore, we believe these density shifted vesicles contain proteins involved in the ADH-stimulated water permeability response, possibly components of particle aggregates and/or water channels.     

ADH-induced water permeability: what role for the microtubular network?

1. ADH-induced intramembrane particle aggregates in the apical membrane of the epithelial cells are specifically related to water permeability in the epithelium. 2. Colchicine and nocadozole (both of which bind to tubulin) inhibit ADH-induced osmotic water flow in the amphibian bladder. 3. Microtubules may be involved in the translocation of the aggrephores prior to their insertion into the plasma membrane.     

Regulation of luminal membrane water permeability by water flow in toad urinary bladder

Intramembranous particle aggregates (presumed sites for water flow) which appear in the luminal membrane consequent to ADH treatment are derived from cytoplasmic membrane structures (now termed "aggrephores") which fuse with the luminal membrane. We have previously shown that bladders stimulated in the absence of an osmotic gradient have about twice as many aggregates and about three times as many sites of aggrephore fusion as bladders stimulated with ADH in the presence of a 175 milliosmolal gradient. The present studies show that the frequency of fused aggrephores and luminal membrane aggregates can be modified as a consequence of alterations in transmembrane water flow initiated by changing the transbladder osmotic gradient during hormone stimulation. Bladders treated with ADH for 1 hr without a gradient and then for 1 hr with a gradient had approximately 1/3 as many aggregates and fusion sites as paired bladders treated for 2 hr without a gradient. Conversely, bladders treated with ADH for 1 hr with a gradient and then for 1 hr without a gradient had approximately 2x as many aggregates and fusion sites as bladders treated for 2 hr with a gradient. In other experiments we demonstrate that the time course of hormone washout is greatly accelerated if carried out in the presence of an osmotic gradient. In paired bladders that were first stimulated with ADH for 30 min in the absence of a gradient, aggregates and fusion sites as well as osmotic water permeability determined in fixed bladders, persisted at near maximum levels for 15 min of washout in the absence of a gradient.(ABSTRACT TRUNCATED AT 250 WORDS)     

Role of ADH-induced intramembrane particle aggregates (author's transl)

In certain epithelial tissues, water permeability is markedly increased by antidiuretic hormone. This so-called hydrosmotic effect has been shown to be mediated by 3'-5' cyclic adenosine monophosphate, which, in turn, alters the permeability o the luminal membrane of receptor cells. This review deals wity ultrastructural alterations occurring in the membrane, as observed with freeze-fracture electron microscopy. Basically, these alterations consist of organized particle aggregates which appear in the apical membrane. In all experimental conditions, similar aggregates can be observed in the membrane of cytoplasmic vesicles. ADH stimulation triggers the fusion of these vesicles with the apical membrane resulting in the concomitant transfer of particle aggregates. It has been shown, in a wide range of experimental conditions, that both number and total area of the aggregates are directly proportional to the water permeability of the tissue. It is generally assumed that particle aggregates contain transmembrane channels that are selectively to water.     

Membrane structural studies of the action of vasopressin

Freeze-fracture electron microscopy of the toad urinary bladder indicates that distinctive intramembrane particle aggregates are responsible for the increase in apical membrane water permeability that occurs with vasopressin (VP) stimulation. In unstimulated bladders the aggregates occur in the cytoplasm of the cells in tubular membrane structures now called aggrephores. After stimulation by VP, aggrephores are shuttled to the surface and fuse with the apical membrane. It is suggested by structural observations and by measurements of membrane capacitance that the area of aggregates inserted into the apical membrane is much greater than previously suspected because many aggregates remain in the wall of the fused aggrephores. The area of the aggregates in a stimulated bladder is sufficiently large for these structures to represent an organized array of water channels that mediates the change in apical membrane permeability. Work with antibodies supports the concept that these channels are not always resident in the apical membrane but become inserted only after stimulation by the hormone VP.     

Stabilization of vasopressin-induced membrane events by bifunctional imidoesters

Vasopressin increases the water permeability of the luminal membrane of the toad bladder epithelial cell. This change in permeability correlates with the occurrence in luminal membranes of intramembrane particle aggregates, which may be the sites for transmembrane water flow. Withdrawal of vasopressin is ordinarily associated with a rapid reduction of water flow to baseline values and a simultaneous disappearance of the particle aggregates. The bifunctional imidoesters dithiobispropionimidate (DTBP) and dimethylsuberimidate (DMS), which cross-link amino groups in membrane proteins and lipids, slow the return of water flow to baseline after vasopressin withdrawal. Cross- linking is maximal at pH 10, and is reduced as pH is lowered. Freeze- fracture studies show persistence of luminal membrane particle aggregates in cross-linked bladders and a reduction in their frequency as water flow diminishes. Fusion of aggregate-containing cytoplasmic tubular membrane structures with the luminal membrane is also maintained by the imidoesters. Reductive cleavage of the central S-S bond of DTBP by beta-mercaptoethanol reverses cross-linking, permitting resumption of the rapid disappearance of the vasopressin effect. Bladders that have undergone DTBP cross-linking and beta- mercaptoethanol reduction respond to a second stimulation by vasopressin. Thus, the imidoesters provide a physiologic and reversible means of stabilizing normally rapid membrane events.     

Retention of antidiuretic hormone-induced particle aggregates by luminal membranes separated from toad bladder epithelial cells

Aggregates of intramembrane particles appear in the luminal membranes of renal collecting duct and amphibian bladder cells after stimulation by antidiuretic hormone (ADH). We undertook this freeze-fracture study to determine whether particle aggregates, once in place, remain in the luminal membrane of the amphibian bladder after the membrane is physically separated from the rest of the cell. We found that the aggregates do remain in high yield in isolated membranes stabilized with a bifunctional imidoester (DTBP) followed by fixation with glutaraldehyde, or unfixed but stabilized with DTBP. These findings support the view that the particles are intrinsic membrane components and that their organization in the form of aggregates does not depend on the presence of the intact cell. In addition, the availability of isolated membranes containing particle aggregates provides a starting point for the isolation of the water-conducting proteins.     

VIP36, a novel component of glycolipid rafts and exocytic carrier vesicles in epithelial cells.

In simple epithelial cells, apical and basolateral proteins and lipids in transit to the cell surface are sorted in the trans-Golgi network. We have recently isolated detergent-insoluble complexes from Madin-Darby canine kidney cells that are enriched in glycosphingolipids, apical cargo and a subset of the proteins of the exocytic carrier vesicles. The vesicular proteins are thought to be involved in protein sorting and include VIP21-caveolin. The vesicular protein VIP36 (36 kDa vesicular integral membrane protein) has been purified from a CHAPS-insoluble residue and a cDNA encoding VIP36 has been isolated. The N-terminal 31 kDa luminal/exoplasmic domain of the encoded protein shows homology to leguminous plant lectins. The transiently expressed protein is localized to the Golgi apparatus, endosomal and vesicular structures and the plasma membrane, as predicted for a protein involved in transport between the Golgi and the cell surface. It is diffusely localized on the plasma membrane but can be redistributed by antibody modulation into caveolae and clathrin-coated pits. We speculate that VIP36 binds to sugar residues of glycosphingolipids and/or glycosylphosphatidyl-inositol anchors and might provide a link between the extracellular/luminal face of glycolipid rafts and the cytoplasmic protein segregation machinery.     

Localization of barriers to water flow in toad urinary bladder

Although it is well accepted that vasopressin (ADH) increases the permeability to water of the toad bladder granular cell's luminal membrane, recent studies have suggested that regulation also takes place at an additional "postluminal" site within the epithelial granular cell. These studies are based upon the observation that a number of experimental maneuvers can alter tissue permeability to water, but do not change the number of particle aggregates observed on the protoplasmic face of the granular cell's luminal membrane with freeze-fracture electron microscopy. These aggregates are believed by many investigators to mediate the transport of water across the luminal membrane. The dissociation between permeability and aggregate frequency described above has been variously interpreted as the consequence of changes in the permeability of the aggregates themselves, or of changes in the permeability of a "postluminal" barrier that is functionally in series with the luminal membrane. We attempted to distinguish between these 2 possibilities by studying paired toad bladders during 3 protocols that alter vasopressin-stimulated water flow across the intact tissue without altering aggregate frequency. Estimates of the permeability of postluminal barriers were obtained by exposing the luminal surface to amphotericin B, an antibiotic that forms water-permeant channels in the luminal membrane. Of the 3 protocols, only diminishing bladder filling volume decreased the water flow elicited by luminal amphotericin B, suggesting that only that protocol indeed decreased the permeability of some postluminal barrier. The other 2 protocols, increasing PCO2 and repeatedly stimulating the bladder with vasopressin, did not alter amphotericin B-elicited flow, suggesting that postluminal barriers were not altered by these 2 protocols.(ABSTRACT TRUNCATED AT 250 WORDS)     

Antidiuretic hormone response in the amphibian urinary bladder: time course of cytochalasin-induced vacuole formation, an ultrastructural study employing ruthenium red

Cytochalasin is known to inhibit the antidiuretic hormone-induced hydro-osmotic response (bulk water flow) in the amphibian urinary bladder without altering hormone-stimulated diffusional water permeability or short-circuit current. In addition, histological studies have shown that the mold metabolite induces the formation of large intracellular vacuoles or lakes in the epithelial cells. We report here a transmission electron microscopic time-course study which indicates that during the early phases of the ADH response cytochalasin causes the formation of numerous multivesicular bodies or aggregates derived from individual basolateral pinocytotic vesicles. Because of their apparent hypertonic nature, the vesicles, as well as the vesicular aggregates, accumulate water during hormone-stimulated hydro-osmotic flow. As a result, the multivesicular bodies dilate and fuse to form the large intracellular lakes characteristic of cytochalasin treatment in the presence of both an applied osmotic gradient and vasopressin. In the presence of mucosal ruthenium red, the luminal glycocalyx was heavily stained with this tracer. At no time, however, even in the presence of hormone, was there any evidence for the uptake of this dye at the apical epithelial border. In the presence of serosal ruthenium red, the lateral intercellular spaces, basolateral pinocytotic vesicles, basal lamina, and collagen, as well as other subepithelial structures, were ruthenium positive. With cytochalasin D, vasopressin, and serosal ruthenium red, both the pinocytotic vesicles and the multivesicular bodies demonstrated an apparent membrane associated ruthenium positive coat. The tracer data indicates that the basolateral pinocytotic vesicles, increased by the presence of hormone, are indeed endocytotic in nature. The mucopolysaccharide coat associated with these structures may be involved in ionic and/or fluid transport.     

Molecular and cellular mechanisms involved in transepithelial transport

Conclusions Our current understanding of vesicular transport across polarized epithelial cells is largely derived from studies of various cell lines in vitro and rat liver in vivo. It may be assumed that the basic mechanisms and cellular machineries which control membrane protein sorting, coated pit-mediated internalization, membrane fusion and fission, play important roles in the phenomenon of selective transcytosis. At the present, however, no general rules have been established that explain the traffic of different membrane proteins and ligands across specific epithelial cell types. For example, the pattern of protein movement that seems to represent a default pathway in certain cell types appears to be signal-mediated in others.The dissection at the molecular level of the components involved in transepithelial traffic of membrane proteins will require complementary experimental approaches, including the isolation of specific transcytotic carrier vesicles, their biochemical characterization, the reconstitution of the various steps in cell-free systems, and analysis of the traffic patterns of transcytotic proteins in different cell types after transfection and in transgenic animals.     

Role of nonacidic endosomes in recycling of ADH-sensitive water channel structures.

Toad urinary bladder epithelial cells respond to the hormone ADH by increasing the water permeability of their luminal membrane. This action is mediated by insertion into the apical membrane of specific water channels. In the absence of ADH these channels appear to be present in tubular cytoplasmic vesicles as morphologically distinctive intramembrane structures called particle aggregates. ADH induces these vesicles to fuse with the apical membrane, transferring their aggregate-water channels into the apical membrane. When ADH stimulation is removed (ADH reversal), aggregates and fluid-phase markers from the mucosal bath appear in water-permeable vesicles in the cytoplasm. We have examined the fate of fluid-phase markers and aggregates with time after ADH reversal. Although the fluid-phase markers horseradish peroxidase and colloidal gold are initially found predominantly in tubular vesicles near the apical surface, by 30 min the markers were found in perinuclear multivesicular bodies (MVBs) of heterogeneous size and shape. These MVBs appear to be nonacidic since they fail to accumulate DAMP. Acid phosphatase (AcPase) was undetectable in these structures. After 60 min, labeled MVBs tended to be smaller, and some of these structures displayed DAMP accumulation and AcPase activity. By evaluation of uncleaned replicas it was possible to localize recycled aggregate-water channels with respect to internalized fluid-phase markers. Thirty minutes after retrieval from the apical surface in tubular vesicles, aggregates could be localized to both the central body and tubular projections of labeled MVBs. At 60 min following reversal, most MVBs had a reduced number of aggregates compared with 30 min, and compact structures could be identified that contained markers but no detectable aggregates. These observations show that aggregates and fluid-phase markers enter a nonacidic endosomal compartment with an MVB morphology following ADH reversal. At extended times following reversal, labeled MVBS having lysosomal characteristics and labeled MVBs having no detectable aggregates can be found, suggesting that aggregates are sorted or degraded prior to this stage.     

Role of osmotic forces in exocytosis: studies of ADH-induced fusion in toad urinary bladder

Antidiuretic hormone (ADH) treatment of toad urinary bladder activates an exocytotic-like process by which intramembrane particle aggregates are transferred from membranes of elongated cytoplasmic tubules to the luminal-facing plasma membrane. We find that the number of these ADH- induced fusion events, and the number of aggregates appearing in the luminal membrane, are reduced when the luminal bathing medium is made hyperosmotic. As an apparent consequence of the inhibition of their fusion with the luminal membrane, the elongated cytoplasmic tubules become enormously swollen into large, rounded vesicles. These results are consistent with the view that osmotic forces are essential to the basic mechanism of exocytosis.     

Vasopressin-induced intramembrane particle aggregates. A dose-response relationship in the isolated cortical collecting duct of the rabbit kidney

The water permeability of collecting ducts is greatly increased by the antidiuretic hormone, vasopressin (VP). Freeze-fracture studies were carried out to test if this permeability increase is associated with the appearance of intramembrane particle (IMP) aggregates and whether increased doses of VP lead to an increase in the number and size of particle aggregates in the luminal membrane of principal cells in the isolated cortical collecting duct. Unstimulated cells expressed 17 +/- 6.5 particle aggregates per 100 microns 2. Stimulation with VP at concentrations of 20 or 200 microU/ml increased the number of particle aggregates significantly to 129 +/- 15.8 and 324 +/- 45.8, respectively. The size of the particle aggregates increased from 0.0012 microns 2 under control conditions to 0.025 microns 2 at 20 microU/ml VP and to 0.063 microns 2 at 200 microU/ml VP. In addition, the total area occupied by the IMP increased from 0.02 microns 2/100 microns 2 (controls) to 3.17% and 20.38% (after 20 and 200 microU ADH/ml, respectively). Particle aggregates were also observed in the luminal plasma membrane of isolated collecting ducts fixed immediately after dissection, resembling the in vivo status. These results demonstrate that a dose-dependent relationship exists between the concentration of the applied VP and the number of particle aggregates, as well as the size of the aggregates. Cytoplasmic tubular vesicles in fusion with the apical membrane were observed.     

Compound exocytosis of casein micelles in mammary epithelial cells

Ultrastructure of lactating bovine and rat mammary epithelial cells was studied with emphasis on secretory vesicle interactions. In the apical zone of the cell, adjacent secretory vesicles formed ball and socket configurations at their points of apposition. Similar configurations were formed between plasma membrane and secretory vesicle membrane. These structures may be formed by the diffusion of water between vesicles with different osmotic potentials. Frequently, vesicular chains consisting of 10 or more linked secretory vesicles were observed. Prior to the exocytotic release of casein micelles, adjacent vesicles fused through fragmentation of the ball and socket membrane. These membrane fragments and the casein micelles appeared to be secreted into the alveolar lumen after passing from one vesicle into another and finally through a pore in the apical plasma membrane. Emptied vesicular chains appeared to collapse and fragmentation of their membrane was observed. Based on these observations, we suggest that most vesicular membrane does not directly contact or become incorporated into the plasma membrane during secretion of the nonfat phase of milk.     

Endocytosis in the uterine luminal and glandular epithelial cells of mice during early pregnancy

We have localized horseradish peroxidase (HRP) in the mouse uterus after intravenous administration on days 1 and 5 of pregnancy in an effort to understand how serum proteins reach the uterine lumen. Direct movement of HRP into uterine and glandular lumina was blocked by the epithelial tight junctions on both days. In luminal and glandular epithelial cells at both times, HRP was localized in endocytic vesicles along the basolateral membranes, multivesicular bodies (mvb), elongated dense bodies below the nucleus (bdb), and many small vesicles near the apical surface of the cells. The uptake of HRP was most extensive in the luminal epithelium on day 1: the number of tracer-containing apical vesicles and bdb was largest, and there were also clusters of vesicles containing the tracer above the nucleus. Acid phosphatase was localized on day 1 in mvb and bdb in both cell types, indicating that these structures are lysosomes. It appeared that HRP followed two pathways after basolateral endocytosis by the epithelial cells: it was transported to the apical region of the cells, where it was present in small vesicles that may release their contents into the uterine or glandular lumina, or it was transported to lysosomes. To investigate whether macromolecules may be transported from the uterine lumen to the stroma, we also studied endocytosis at the apical pole of luminal epithelial cells after intraluminal injection of HRP. There was no detectable uptake of HRP from the lumen on day 1, and no tracer was detected in the intercellular spaces or basement membrane region. On day 5, a large amount of HRP was taken up from the lumen into apical endocytic vesicles, mvb, and dense bodies, but tracer was not present in the Golgi apparatus, lateral intercellular spaces, or the basement membrane region at the times studied. These observations indicate that there was no transport of luminal macromolecules to the uterine stroma on day 1, while the possibility of transport on day 5 requires further study.     

76 and 14 kDa polypeptides, two major components released from amphibian urinary bladder epithelium. Localization and potential role

Several experimental conditions such as antidiuretic hormone (ADH) challenge, apical treatment with phorbol myristate acetate (PMA), and mechanical stretching of the tissue are known to increase the insertion of intramembrane particle aggregates and/or granule exocytosis at the apical border of epithelial cells of amphibian urinary bladders. A constant release of 2 peptides of 76 and 14 kDa apparent molecular mass, respectively, was associated with these treatments. The localization of these 2 polypeptides was assessed by immunofluorescence and electron microscopy immunocytochemistry using fluorescent, peroxidase, and colloidal gold probes. The 76 kDa polypeptide appeared to be associated with the cell coat and with the granule content which is released at the apical cell surface. The 14 kDa peptide was also found in the cell coat, and postembedding immunocytochemistry indicates its presence in cytoplasmic subapical vesicles (aggrephores and/or granules). The migration of these 76 and 14 kDa polypeptides in SDS-polyacrylamide gel electrophoresis was modified neither by a treatment at 90 degrees C, nor by the presence or absence of calcium in the medium. Treatment with EGTA did not modify the fluorescence emission of the two peptides and, consequently, they are probably not among the major calcium binding proteins. The addition to the mucosal medium of the stretch extract or of antibodies raised against the 76 and 14 kDa peptides did not modify ADH-induced water permeability. However, a significant decrease of the hydrosmotic response to ADH occurred in subsequent stimulation-washout cycles when the anti-14 kDa peptide antiserum was applied to the mucosal bath. When the bladders were incubated with a stretch extract, we observed a slight alteration of the short-circuit current (Isc), an increase of the basal Na+ transport, and a decrease of the maximal Isc in response to ADH. The 76 kDa protein, released in the apical medium, could play a protective role in the cellular plasma membrane and could participate in the formation of the thick cell coat lining the apical membrane of the granular cells. The 14 kDa protein might be one of the proteins associated with the aggregates, but further studies will be necessary to clarify its exact role in the ADH-induced permeability modifications observed in amphibian urinary bladders.     

Fusion images and intramembrane particle aggregates during the action of antidiuretic hormone

Summary Antidiuretic hormone (ADH) causes the appearance of water-conducting particle aggregates in the luminal membrane of receptor cells in amphibian bladder and skin, and in the mammalian collecting duct. The aggregates originate from cytoplasmic tubules that fuse with the luminal membrane during ADH stimulation. We have studied the process of fusion and the structure of the particle aggregates by a rapid-freeze technique that renders chemical fixation and glycerol protection unnecessary. Our findings differ in some important respects from previously published work. Aggregate particles, in our study, partition equally between the external (EF) and protoplasmic (PF) membrane leaflets, rather than remaining in the protoplasmic leaflet exlcusively. By including the entire population of fusion images in our survey, we have found that aggregate delivery in ADH-treated cells proceeds preferentially from small fusion images whose diameter is significantly less than the 0.12 m characteristic of the carrier tubules themselves. We have also found that, even in unstimulated preparations, fusion images are numerous, being mostly of small diameter. ADH stimulation produces a moderate increase in the number of fusion images and a significant increase in fusion-image diameter. These findings indicate that the individual particles are mobile within the membrane, lacking interparticle linkage. In addition, contact of cytoplasmic tubules with the luminal membrane may take place even in the absence of ADH, producing small fusion images which are not associated with aggregate delivery to the luminal membrane.Faculty Scholar, Josiah Macey Jr. Foundation