Involvement of smooth and coated vesicles in the function of the contractile vacuole complex of some cryptophycean flagellates

The contractile vacuole complex of cryptophycean flagellates comprises the contractile vacuole, a pore and a vesicular spongiome. A minority of spongiome vesicles bear a 15-nm coat on the cytoplasmic surface of the membrane. The coat superficially resembles a clathrin coat. The majority of vesicles are smooth surfaced. Both types of vesicles are found at the same time. Smooth vesicles can be seen in profile suggesting vesicle-vesicle and vesicle-vacuole fusion. It is suggested that smooth vesicles are involved in the segregation of fluid from the cytoplasm and in filling the vacuole. Coated elements exist only as independent vesicles and as coated pits in the contractile vacuole membrane. There is no evidence of fusion of coated vesicles. It is suggested that coated vesicles function to retrieve specific membrane components from the contractile vacuole.     

REGULAR STRUCTURES IN MEMBRANES : I. Membranes in the Endocytic Complex of Ileal Epithelial Cells

An "apical endocytic complex" in the ileal lining cells of suckling rats is described. The complex consists of a continuous network of membrane-limited tubules which originate as invaginations of the apical plasma membrane at the base of the microvilli, some associated vesicles, and a giant vacuole. The lumenal surface of this tubular network of membranes and associated vesicles is covered with a regular repeating particulate structure. The repeating unit is an ~7.5-nm diameter particle which has a distinct subunit structure composed of possibly nine smaller particles each ~3 nm in diameter. The ~7.5-nm diameter particles are joined together with a center-to-center separation of ~15 nm to form long rows. These linear aggregates, when arranged laterally, give rise to several square and oblique two-dimensional lattice arrangements of the particles which cover the surface of the membrane. Whether a square or oblique lattice is generated depends on the center-to-center separation of the rows and on the relative displacement of the particles in adjacent rows. Four membrane faces are revealed by fracturing frozen membranes of the apical tubules and vesicles: two complementary inner membrane faces exposed by the fracturing process and the lumenal and cytoplasmic membrane surfaces revealed by etching. The outer membrane face reveals a distinct array of membrane particles. This array also sometimes can be seen on the outer (B) fracture face and is sometimes faintly visible on the inner (A) fracture face. Combined data from sectioned, negatively stained, and freeze-etched preparations indicate that this regular particulate structure is a specialization that is primarily localized in the outer half of the membrane mainly in the outer leaflet.     

Le Cortex de la Vacuole Contractile et son Ultrastructure chez les Ciliés

SYNOPSIS. In various ciliates the contractile vacuole is a permanent organelle, delimited by a differentiated cortex.
The cortex is made up of a dense reticulum of anastomosing tubules limited by a smooth membrane, and vesicles. This "spongiome" can be considered as a localized and specialized condensation of the endoplasmic reticulum.     

Distribution of alkaline phosphatase in vegetative dictyostelium cells in relation to the contractile vacuole complex

The structure of the contractile vacuole complex of Dictyostelium discoideum has long been a subject of controversy. A model that originated from the work of John Heuser and colleagues described this osmoregulatory organelle as an interconnected array of tubules and cisternae the membranes of which are densely populated with vacuolar proton pumps. A conflicting model described this same organelle as bipartite, consisting of a pump-rich spongiome and a pump-free bladder, the latter membranes being identified by their alkaline phosphatase activity. In the present study we have employed an antiserum specific for Dictyostelium alkaline phosphatase to examine the distribution of this enzyme in vegetative cells. The antiserum labels puncta, probably vesicles, that lie at or near the plasma membrane and are sometimes, but only rarely, enriched near contractile vacuole membranes. We conclude that alkaline phosphatase is not a suitable marker for contractile vacuole membranes. We discuss these results in relation to the two models of contractile vacuole structure and suggest that all data are consistent with the first model.     

The ionic composition of the contractile vacuole fluid of Paramecium mirrors ion transport across the plasma membrane

In vivo K+, Na+, Ca2+, Cl- and H+ activities in the cytosol and the contractile vacuole fluid, the overall cytosolic osmolarity, the fluid segregation rate per contractile vacuole and the membrane potential of the contractile vacuole complex of Paramecium multimicronucleatum were determined in cells adapted to 24 or 124 mosm l(-1) solutions containing as the monovalent cation(s): 1) 2 mmol l(-1) K+; 2) 2 mmol l(-1) Na+; 3) 1 mmol l(-1) K+ plus 1 mmol l(-1) Na+; or 4) 2 mmol l(-1) choline. In cells adapted to a given external osmolarity i) the fluid segregation rate was the same if adapted to either K+ or Na+, twice as high when adapted to solutions containing both K+ and Na+, and reduced by 50% or more in solutions containing only choline, ii) the fluid of the contractile vacuole was always hypertonic to the cytosol while the sum of the ionic activities measured in the fluid of the contractile vacuole was the same in cells adapted to either K+ or Na+, at least 25% higher in cells adapted to solutions containing both K+ and Na+, and was reduced by 55% or more in solutions containing only choline, iii) the cytosolic osmolarity was the same in cells adapted to K+ alone, to Na+ alone or to both K+ and Na+, whereas it was significantly lower in cells adapted to choline. At a given external osmolarity, a positive relationship between the osmotic gradient across the membrane of the contractile vacuole complex and the fluid segregation rate was observed. We conclude that both the plasma membrane and the membrane of the contractile vacuole complex play roles in fluid segregation. The presence of external Na+ moderated K+ uptake and caused the Ca2+ activity in the contractile vacuole fluid to rise dramatically. Thus, Ca2+ can be eliminated through the contractile vacuole complex when Na+ is present externally. The membrane potential of the contractile vacuole complex remained essentially the same regardless of the external ionic conditions and the ionic composition of the fluid of the contractile vacuole. Notwithstanding the large number of V-ATPases in the membrane of the decorated spongiome, the fluid of the contractile vacuole was found to be only mildly acidic, pH 6.4.     

Membrane Dynamics of the Contractile Vacuole Complex of Paramecium1

ABSTRACT. Membrane dynamics of the contractile vacuole complex of Paramecium were investigated using conventional electron microscopy of cells so that the vacuoles were serial-sectioned longitudinally and transversely. During systole, vacuolar membrane collapses first into flattened cisternae which undergo further modification into a mass of interconnected small membrane tubules. These tubules retain their connections with the radiating microtubular ribbons; consequently they are found only in the poleward hemisphere. Permanent connections between ampullae and the collapsed vacuole membrane could not be verified nor was a sphincter-like mechanism for closing such a junction observed. Membranes of the ampullae and the collecting canals also collapse to varying extents into arrays of tubules that remain bound to microtubular ribbons during diastole. Thus vacuole, ampullae, and collecting canal membranes all assume tubular forms when internal volume is at a minimum. Having failed to observe a microfilamentous encasement of the vacuole, we suggest that an alternative mechanism for the “contractile” function should be sought. One such is based on fluid volume increase and fluid flow within transiently interconnected tubular membrane systems that cycle between a tubular and a planar membrane form as internal volume is periodically increased and reduced. The driving force for this mechanism might best be sought in the molecular structure of the membranes of the contractile vacuole complex.     

Tubular-vesicular transformation in the contractile vacuole system of Dictyostelium

The contractile vacuole complex of Dictyostelium is the paradigm of a membrane system that undergoes tubular-vesicular transitions during its regular cycle of activities. This system acts as an osmoregulatory organelle in freshwater amoebae and protozoa. It collects fluid in a network of tubules and cisternae, and pumps it out of the cell through transient pores in the plasma membrane. Tubules and vacuoles are interconvertible. The tubular channels are associated with the cortical actin network and are capable of moving and fusing. The contractile vacuole complex is separate from vesicles of the endosomal pathway and preserves its identity in a dispersed state during cell division. We outline techniques to visualize the contractile vacuole system by electron and light microscopy. Emphasis is placed on GFP-fusion proteins that allow visualization of the dynamics of the contractile vacuole network in living cells. Proteins that control activities of this specialized organelle in Dictyostelium have been conserved during evolution and also regulate membrane trafficking in man.     

An Electron Microscope Study of the Contractile Vacuole in Tokophrya infusionum

Contractile vacuoles are organelles that collect fluid from the cytoplasm and expel it to the outside. After each discharge (systole), they appear again and expand (diastole). They are widely distributed among Protozoa, and have been found also in some fresh water algae, sponges, and recently in some blood cells of the frog, guinea pig, and man. In spite of the extensive work on the contractile vacuole, very little is known concerning its mode of operation. An electron microscope study of a suctorian Tokophrya infusionum provided an opportunity to study thin sections of contractile vacuoles, and in these some structures were found which could be part of a mechanism for the systolic and diastolic motions the organelle displays. In Tokophrya, as in Suctoria and Ciliata in general, the contractile vacuole has a permanent canal connecting it with the outside. The canal appears to have a very elaborate structure and is composed of three parts: (1) a pore; (2) a channel; and (3) a narrow tubule located in a papilla protruding into the cavity of the contractile vacuole. Whereas the pore and channel have fixed dimensions and are permanently widely open, the tubule has a changeable diameter. At diastole it is so narrow (about 25 to 30 mµ in diameter) that it could be regarded as closed, while at systole it is widely open. It is assumed that the change in diameter is due to the contraction of numerous fine fibrils (about 180 A thick) which are radially disposed around the canal in form of a truncated cone, with its tip at the channel, and its base at the vacuolar membrane. It seems most probable that the broadening of the tubule results in discharge of the content of the contractile vacuole. In the vicinity of the very thin limiting vacuolar membrane, small vesicles and canaliculi of the endoplasmic reticulum, very small dense particles, and mitochondria may be found. In addition, rows of closely packed vesicles are present in this region, and in other parts of the cytoplasm. It is suggested that they might represent dictyosome-like bodies, responsible for withdrawing fluids from the cytoplasm and then conveying them to the contractile vacuole, contributing to its expansion at diastole.     

The contractile vacuole and its membrane dynamics

The contractile vacuole (CV) is an osmoregulatory organelle whose mechanisms of function are poorly understood. Immunological studies in the last decade have demonstrated abundant proton-translocating V-type ATPases (V-ATPases) in its membrane that could provide the energy, from proton electrochemical gradients, for moving ions into the CV to be followed by water. This review emphasizes recent work on the contractile vacuole complex (CVC) of Paramecium including (1) CV expulsion, (2) a role for V-ATPases in sequestering fluid, (3) identifying ions in the cytosol and in the CV, (4) in situ electrophysiological parameters of the CVC membrane, and (5) a better understanding of the membrane dynamics of this organelle.     

The vacuolar-atpase of Paramecium multimicronucleatum: gene structure of the B subunit and the dynamics of the V-ATPase-rich osmoregulatory membranes

Previous studies have shown that the vacuolar-ATPase (V-ATPase) of the contractile vacuole complexes (CVCs) in Paramecium multimicronucleatum is necessary for fluid segregation and osmoregulation. In the current study, immunofluorescence showed that the development of a new CVC begins with the formation of a new pore around which the collecting canals form. The decorated membranes are then deposited around the newly formed collecting canals. Quick-freeze deep-etch techniques reveal that six 10-nm-wide V-ATPase V, sectors, tightly packed into a 20 x 30-nm rectangle, form two rows of these compacted sectors that helically wrap around the cytosolic side of decorated membrane tubules. During new CVC formation, packing of decorated tubules around mature CVCs was temporarily disrupted so that some of these decorated tubules became transformed into decorated vesicles. Freeze-fracturing of these decorated vesicles revealed a highly pitted E-face and a particulate P-face. The V-ATPase was purified for the first time in any ciliated protozoan and shown to contain, as in other cells, the V1 subunits A to E, and four 14-20 kDa polypeptides. The B subunit was cloned and found to be encoded by one gene containing four short introns. This subunit has 510 amino acid residues with a predicted molecular weight of 56.8 kDa, a value similar to B subunits of other organisms. Except for the N- and C-termini, it has a 75% sequence identity with other B subunits, suggesting that the B subunits in Paramecium, like other species, have been conserved and that the entire surface of this subunit may be important in interacting with other subunits.     

Freeze-fracture studies of frog atrial fibres.

The freeze-fracturing technique was used to characterize the junctional devices involved in the electrical coupling of frog atrial fibres. These fibres are connected by a type of junction which can be interpreted as a morphological variant of the "gap junction" or "nexus". The most characteristic features are rows of 9-nm junctional particles forming single or anastomosed circular profiles on the inner membrane face, and corresponding pits on the outer membrane face. Very seldom aggregates consisting of few geometrically disposed 9-nm particles are found. The significance of the junctional structures in the atrial fibres is discussed, with respect to present knowledge about junctional features of gap junctions in various tissues, including embryonic ones.     

THE MECHANISM OF THE NEPHRIDIAL APPARATUS OF PARAMECIUM MULTIMICRONUCLEATUM : II. The Filling of the Vesicle by Action of the Ampullae

Our recent analysis of the nephridial apparatus of Paramecium multimicronucleatum by high-speed cinematography (300 fps at X 250) indicates that before the water expulsion vesicle ("contractile vacuole") is completely voided of fluid during expulsion, the ampullae surrounding and confluent with the vesicle swell with fluid entering from their respective nephridial tubules. Once the membranes of the excretory pore at the base of the excretory canal (leading from the vesicle proper to the outside) have constricted and resealed the excretory pore, the up till then constricted injection tubules of the ampullae which conduct fluid to the vesicle open as waves of contraction along the coacervate gel around the ampulla and proceed along each ampulla from distal to proximal end. The coacervate gel around any one ampulla does not necessarily contract in phase with that of any other ampulla. Each ampulla acts independently. The fluid from the ampullae is thus pumped sequentially, but not in predetermined order, into the water expulsion vesicle, refilling and distending it. Our previous studies (Organ et al., 1968a) suggest that an actomyosinoid ATP-using mechanism may be functional in the ampullary contractions.     

Plasma membrane specialization at the discharge site of the excretory poreless vacuole of the ciliate Euplotes raikovi

The contractile vacuole of Euplotes raikovi consists basically of a membrane-delimited cistern that has no direct communication with the exterior of the cell. Contiguous alveoli interpose between the cisterna and the plasma membrane and probably receive the cisternal contents before being expelled. The area of the plasma membrane that interacts with the outer membrane of the alveoli overlying the cistern has been found to carry a special region of intramembranous particles organized in 100-200 strands, showing varied sizes and a tendency to align parallel with one another. The region is also characterized by a smooth central core and by characteristic deformations that have been interpreted as focal sites of discharge of the contractile vacuole.     

Rab8a regulates the exocyst-mediated kiss-and-run discharge of the Dictyostelium contractile vacuole

Water expulsion by the contractile vacuole (CV) in Dictyostelium is carried out by a giant kiss-and-run focal exocytic event during which the two membranes are only transiently connected but do not completely merge. We present a molecular dissection of the GTPase Rab8a and the exocyst complex in tethering of the contractile vacuole to the plasma membrane, fusion, and final detachment. Right before discharge, the contractile vacuole bladder sequentially recruits Drainin, a Rab11a effector, Rab8a, the exocyst complex, and LvsA, a protein of the Chédiak-Higashi family. Rab8a recruitment precedes the nucleotide-dependent arrival of the exocyst to the bladder by a few seconds. A dominant-negative mutant of Rab8a strongly binds to the exocyst and prevents recruitment to the bladder, suggesting that a Rab8a guanine nucleotide exchange factor activity is associated with the complex. Absence of Drainin leads to overtethering and blocks fusion, whereas expression of constitutively active Rab8a allows fusion but blocks vacuole detachment from the plasma membrane, inducing complete fragmentation of tethered vacuoles. An indistinguishable phenotype is generated in cells lacking LvsA, implicating this protein in postfusion detethering. Of interest, overexpression of a constitutively active Rab8a mutant reverses the lvsA-null CV phenotype.     

The Dictyostelium LvsA protein is localized on the contractile vacuole and is required for osmoregulation

LvsA is a Dictyostelium protein that is essential for cytokinesis and that is related to the mammalian beige/LYST family of proteins. To better understand the function of this novel protein family we tagged LvsA with GFP using recombination techniques. GFP-LvsA is primarily associated with the membranes of the contractile vacuole system and it also has a punctate distribution in the cytoplasm. Two markers of the Dictyostelium contractile vacuole, the vacuolar proton pump and calmodulin, show extensive colocalization with GFP-LvsA on contractile vacuole membranes. Interestingly, the association of LvsA with contractile vacuole membranes occurs only during the discharge phase of the vacuole. In LvsA mutants the contractile vacuole becomes disorganized and calmodulin dissociates from the contractile vacuole membranes. Consequently, the contractile vacuole is unable to function normally, it can swell but seems unable to discharge and the LvsA mutants become osmosensitive. These results demonstrate that LvsA can associate transiently with the contractile vacuole membrane compartment and that this association is necessary for the function of the contractile vacuole during osmoregulation. This transient association with specific membrane compartments may be a general property of other BEACH-domain containing proteins.     

Characterisation of the water expulsion vacuole inPhytophthora nicotianae zoospores

Summary The water expulsion vacuole (WEV) in zoospores ofPhytophthora nicotianae and other members of the Oomycetes is believed to function in cell osmoregulation. We have used videomicroscopy to analyse the behaviour of the WEV during zoospore development, motility and encystment inP. nicotianae. After cleavage of multinucleate sporangia, the WEV begins to pulse slowly but soon attains a rate similar to that seen in motile zoospores. In zoospores, the WEV has a mean cycle time of 5.7 ± 0.71 s. The WEV continues to pulse at this rate until approximately 4 min after the onset of encystment. At this stage, pulsing slows progressively until it becomes undetectable. The commencement of WEV operation in sporangia coincides with the reduction of zoospore volume prior to release from the sporangium. Disappearance of the WEV during encystment occurs as formation of a cell wall allows the generation of turgor pressure in the cyst. As in other organisms, the WEV inP. nicotianae zoospores consists of a central bladder surrounded by a vesicular and tubular spongiome. Immunolabelling with a monoclonal antibody directed towards vacuolar H⁺-ATPase reveals that this enzyme is confined to membranes of the spongiome and is absent from the bladder membrane or zoospore plasma membrane. An antibody directed towards plasma membrane H⁺-ATPase shows the presence of this ATPase in both the bladder membrane and the plasma membrane over the cell body but not the flagella. Analysis of ATPase activity in microsomal fractions fromP. nicotianae zoospores has provided information on the biochemical properties of the ATPases in these cells and has shown that they are similar to those in true fungi. Inhibition of the vacuolar H⁺-ATPase by potassium nitrate causes a reduction in the pulse rate of the WEV in zoospores and leads to premature encystment. These results give support to the idea that the vacuolar H⁺-ATPase plays an important role in water accumulation by the spongiome in oomycete zoospores, as it does in other protists.Abbreviations BMM butyl methylmethacrylate - F fix 4% formaldehyde fixation - GF fix 4% formaldehyde and 0.2% glutaraldehyde fixation - V-ATPase vacuolar H⁺-ATPase - WEV water expulsion vacuole     

A giant phosphoprotein localized at the spongiome region of Crithidia luciliae thermophila

A giant protein with an apparent molecular mass of 2,300-kDa was identified in the Triton X-100 soluble fraction of Crithidia luciliae thermophila. Polyclonal antibody raised against this protein reacted by immunoblot analysis with proteins of similar molecular mass in Crithidia fasciculata and Crithidia oncopelti. In addition, the antibody immunoprecipitates the protein either after in vivo phosphorylation with [32P]orthophosphoric acid or after metabolically labeling with [35S]methionine. Indirect immunofluorescence microscopy analysis performed either with fixed or with live parasites showed a single fluorescent spot at the level of the flagellar pocket region. Immunogold electron microscopy of thin sections of the parasite revealed that the antigen is localized at a restricted area of the spongiome, between the contractile vacuole and the flagellar pocket. Furthermore, Triton X-114 phase separation of whole cell membrane proteins, metabolically labeled with [35S]methionine, demonstrated that the giant protein remains in the aqueous phase. These results indicate that this phosphoprotein behaves as a peripheral membrane protein localized at the spongiome region, suggesting that it might be involved in the osmoregulatory process.     

Ultrastructural Aspects of the Somatic Cortex and Contractile Vacuole of the Ciliate,Ichthyophthirius multifiliis Fouquet1

The trophont stage in the life cycle of Ichthyophthirius multifiliis was studied in the electron microscope. Surface ridges contain up to 24 ridge microtubules, disposed as a ribbon. Kinetosomes show the classic morphology of 9 triplets of microtubules. Associated with each kinetosome is a kinetodesmal fibril, originating in proximity to triplets 5, 6, and 7, and having a 30 nm periodicity; 3 to 5 postciliary microtubules, originating between triplets 8 and 9; and up to 3 transverse microtubules, originating at triplet 4, as well as a parasomal sac. Each cell is partially enclosed by a system of 3 “unit” membranes: the outer limiting membrane, and the outer and inner alveolar membranes. The last two membranes define the alveolar sac. Mucocysts, each with a dense core, are present in large numbers. The contractile vacuole system includes the contractile vacuole, associated tubules and vesicles, injection canals, a discharge canal, and a pore. Microtubules abound in the walls of the contractile vacuole, injection and discharge canals, and in the region of the pores, where both ring and radial microtubular arrangements are noted. The ultrastructure suggests that I. multifiliis is more closely related to Tetrahymena pyriformis than to Paramecium aurelia.     

Freeze-fracture studies of frog neuromuscular junctions during intense release of neurotransmitter. I. Effects of black widow spider venom and Ca2+-free solutions on the structure of the active zone

Black widow spider venom (BWSV) was applied to frog nerve-muscle preparations bathed in Ca2+-containing, or Ca2+-free, solutions and the neuromuscular junctions were studied by the freeze-fracture technique. When BWSV was applied for short periods (10-15 min) in the presence of Ca2+, numerous dimples (P face) or protuberances (E face) appeared on the presynaptive membrane and approximately 86% were located immediately adjacent to the double rows of large intramembrane particles that line the active zones. When BWSV was applied for 1 h in the presence of Ca2+, the nerve terminals were depleted of vesicles, few dimples or protuberances were seen, and the active zones were almost completely disorganized. The P face of the presynaptic membrane still contained large intramembrane particles. When muscles were soaked for 2-3 h in Ca2+-free solutions, the active zones became disorganized, and isolated remnants of the double rows of particles were found scattered over the P face of the presynaptic membrane. When BWSV was applied to these preparations, dimples or protuberances occurred almost exclusively alongside disorganized active zones or alongside dispersed fragments of the active zones. The loss of synaptic vesicles from terminals treated with BWSV probably occurs because BWSV interferes with the endocytosis of vesicle membrane. Therefore, we assume that the dimples or protuberances seen on these terminals identify the sites of exocytosis, and we conclude that exocytosis can occur mostly in the immediate vicinity of the large intramembrane particles. Extracellular Ca2+ seems to be required to maintain the grouping of the large particles into double rows at the active zones, but is not required for these particles to specify the sites of exocytosis.     

The plant ER: a dynamic organelle composed of a large number of discrete functional domains

The endoplasmic reticulum (ER) of plants is comprised of a three-dimensional network of continuous tubules and sheets that underlies the plasma membrane, courses through the cytoplasm, and links up with the nuclear envelope. Aside from discussing the dynamic properties of this versatile and adaptable organelle, the review highlights the structure and the functional properties of 16 types of morphologically defined ER membrane domains. Owing to their lablie or transient nature, several of these domains can only be visualized reliably through the use of ultrarapid freezing techniques. The ER domains discussed are: the lamin receptor domain; the nuclear pores; the nuclear envelope-ER gates, the microtubule nucleation domains; the protein and oil body-forming domains; the vacuole-forming ER; the actin-binding, the plasma membrane-anchoring and the vacuole and mitochondrion-attachment domains; the lipid recycling ER cisternae and the plasmodesmata. Preliminary evidence suggests that this list will have to be expanded in the near future. Understanding the assembly, the functional roles, and the developmental regulation of these domains has implications both for understanding cell structure and function, and for exploiting plants for agricultural and biotechnological purposes.