An Ultrastructural Study of Ingestion and Digestion in Tetrahymena pyriformis*

SYNOPSIS. When the structures involved in digestive events in T. pyriformis are examined at the electron microscope level, some information is added to that long known from light microscopy. The food trapping mechanism consists of the three membranelles, undulating membrane, oral ribs, and a “valve” apparently closing the opening to the cytopharynx. Both of the latter structures are supported by microtubules. Fibers extend internally from the cytopharynx and are closely associated with the food vacuole as it forms. Clear vacuoles resembling pinocytic vacuoles appear to arise from differentiated areas of the pellicle and plasma membrane. These vacuoles may fuse with primary lysosomes. Hydrolases are thus contributed to the pinocytic vacuoles which may then fuse with food vacuoles. When first formed food vacuoles contain no hydrolases but may acquire them directly, from primary lysosomes or from pinocytic vacuoles. Digestion proceeds to completion in the food vacuole, at which time soluble food products are released to the cytoplasm. Undigested materials are lost through the cytopyge. In stationary growth phase cells autophagic vacuoles form containing mitochondria and other cellular particulates. Such vacuoles probably contain hydrolases when formed and they may receive others by fusion with primary lysosomes.     

Phagosome fusion vesicles of paramecium. I. Thin-section morphology

Ultrastructural studies of the digestive system of Paramecium caudatum focusing on the first 5 min of digestive-vacuole age reveal a set of vesicles, named phagosome fusion vesicles (PFVs), which fuse with the digestive vacuole just after the vacuoles are released from the cytopharynx and concomitant with vacuole acidification. Serial thin-sections of vacuoles labeled with horseradish peroxidase (HRP) and/or latex beads in pulse-chase studies were observed. PFVs, irregularly shaped, electron-translucent vesicles ranging from a small diameter to over 1 micro, are first seen in the region of the cytopharynx where they bind to the nascent vacuole membrane. Within 30 sec of vacuole release the PFVs fuse with the vacuole where they remain for a brief time connected to the vacuole by a narrow annulus. HRP-reaction product is found in vacuoles but not in PFVs before PFVs fuse with the vacuoles. After fusion with PFVs HRP is quickly inactivated. Tubular extensions of vacuole membrane then form between the fused PFVs. By 3 to 5 min both PFVs and tubules disappear from the vacuole surface and lysosomes appear in their place. We believe the tubules are pinched off as PFV membrane is being added to the vacuole. Microfilaments coat the membrane during all these dynamic events. Since the pH of the vacuole becomes acid during the first few minutes, we are now looking for a direct correlation between PFV fusion and acidification.     

Primary Lysosomes of the Ciliate Pseudomicrothorax dubius: Cytochemical Identification and Role in Phagocytosis*

SYNOPSIS. Filamentous cyanobacteria are ingested through the cytopharynx of the ciliate Pseudomicrothorax dubius. The cytopharynx is a complex of microtubules and microfilaments located in a highly vesiculated cytoplasm, the phagoplasm. Two types of membrane-bounded phagoplasmic vesicles can be distinguished by their differences in size, fine structure, and acid phosphatase (AcPase) content. One type has a homogeneous, electron-dense interior which is AcPase-positive. These vesicles are present in fed cells and in unfed cells devoid of food vacuoles, and thus appear to be primary lysosomes. During phagocytosis, exocytosis within the cytopharynx of the primary lysosomes results in the elaboration of a food vacuole. The vacuole grows by incorporation of lysosomal membrane; lysosomal hydrolases are liberated into the vacuole. Within less than 1 second of AcPase's entry into the food vacuole, it is detectable within the cyanobacterial cytoplasm, and within 5 seconds, destruction of the cyanobacterial filament is observed. It is hypothesized that the rapidity of hydrolase penetration of the cyanobacterial cell wall is the result of the action of molecules analogous to the “killing agents” of neutrophil leukocytes, which rapidly render bacterial envelopes permeable. AcPase, and presumably other hydrolases, are present in the cyanobacterial filament when filament destruction occurs; they thus appear implicated in this process. Hydrolases may activate an autodestruction mechanism in the cyanobacterium. Firm adherence of the food vacuole membrane to the cyanobacterial filament is demonstrated, and its role in phagocytosis is discussed.     

Microtubules, Microfilaments, and Membranes in Phagocytosis: Structure and Function of the Oral Apparatus of the Ciliate Climacostomum virens

Climacostomum virens uses oral membranelles to drive suspended food particles into its buccal cavity. The cavity leads to a buccal tube which extends into the cell by as much as half a cell length. The inner end of this tube is delimited by a haplokinety (two rows of basal bodies). Internal to this zone is the cytostome and cytopharynx where food vacuoles form. The buccal tube is encircled by a ring of fibrous material, the cytostomal cord, in the region of the cytostome immediately below the haplokinety. Ribbons of postciliary microtubules extend from the kinetosomes of the haplokinety, attach to the cytopharyngeal membrane, and pass under the cytostomal cord. They become broader and expand into the cytoplasm. Cytopharyngeal vesicles pass between the microtubular ribbons and fuse with the cytopharyngeal membrane to generate membrane for forming food vacuoles. The cytopharyngeal vesicles contain a material which is secreted into the forming food vacuoles. Ciliates continue to feed after incubation in a medium containing cycloheximide, indicating that they draw on a pre-existing pool of membrane when forming the food vacuole.     

Phagosome fusion vesicles of Paramecium. II. Freeze-fracture evidence for membrane replacement

Phagosome fusion vesicles (PFVs), a new population of relatively large granules in Paramecium caudatum which fuse with the first stage of digestive vacuoles (DV-I) shortly after these vacuoles are released from the cytopharynx (their site of formation), have been studied by using the freeze-fracture technique. Identification of PFVs is possible in the resulting replicas at all sites where they are commonly found in thin sections, at the cytopharynx, bound but not fused with nascent digestive vacuoles and fused with released vacuoles in the cell's posterior end. These PFVs have membranes which do not resemble the membranes of the forming digestive vacuole membrane or the discoidal vesicle membranes from which vacuole membrane is derived. Their smooth E-fracture face with only 50 to 100 intramembrane particles (IMPs) per micrometers 2 and particulate P-face (approximately 2500 IMPs/micrometers) do resemble the second vacuole stage (DV-II) which is characterized by a smaller diameter and acid pH. Evidence is presented for PFV fusion with the DV-I and for membrane replacement, at least in part, as the DV-I becomes a DV-II. Membrane replacement entails first adding PFVs to the DV-I and then removing the original discoidal vesicle-derived membrane as tubules as the vacuole condenses. Implications of the possible role of PFVs in forming intravacuolar symbiotic relationships are also discussed.     

FOOD VACUOLE MEMBRANE GROWTH WITH MICROTUBULE-ASSOCIATED MEMBRANE TRANSPORT IN PARAMECIUM

Evidence from a morphological study of the oral apparatus of Paramecium caudatum using electron microscope techniques have shown the existence of an elaborate structural system which is apparently designed to recycle digestive-vacuole membrane. Disk-shaped vesicles are filtered out of the cytoplasm by a group of microtubular ribbons. The vesicles, after being transported to the cytostome-cytopharynx region in association with these ribbons, accumulate next to the cytopharynx before they become fused with the cytopharyngeal membrane. This fusion allows the nascent food vacuole to grow and increase its membrane surface area. The morphology of this cytostome-cytopharynx region is described in detail and illustrated with a three-dimensional drawing of a portion of this region and a clay sculpture of the oral apparatus of Paramecium. Evidence from the literature for the transformation of food vacuole membrane into disk-shaped vesicles both from condensing food vacuoles in the endoplasm and from egested food vacuoles at the cytoproct is presented. This transformation would complete a system of digestive vacuole membrane recycling.     

Brush-border formation in the midgut of an insect,Calliphora erythrocephala meigen

Summary The embryonic development of the brush-border of anterior midgut cells of Calliphora was studied by electron microscopy. Dense surface-forming vesicles, as described by Bonneville (1970), are found prior to microvillus formation. These dense vesicles provide membranous and coating material for the moulding of the microvilli. The number of dense vesicles increases rapidly to a maximum just before brush-border formation, after which it decreases very rapidly, accompanied by an increase in the number of microvilli. Formation of microvilli proceeds in essentially the same way as in Xenopus. First, some of the vesicles fuse with the apical cell membrane, resulting in an increase of the cell surface, part of which is coated with filamentous material deriving from the dense vesicles. This in turn leads to bulging, and short irregular microvilli appear. These are erected and elongated.Prefabricated tubular elements are believed to play a part in this erection and elongation, probably due to the unwinding of spirally coiled strands.Microvillus formation proper lasts 2 to 3 hours in Calliphora. Almost the entire amount of membranous and coating material is prefabricated prior to the formation of microvilli.     

Effects of Chloroquine on the Feeding Mechanism of the Intraerythrocytic Human Malarial Parasite Plasmodium falciparum1

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

DIGESTION AND THE DISTRIBUTION OF ACID PHOSPHATASE IN BLEPHARISMA

Suspensions of Blepharisma intermedium were fed latex particles for 5 min and then were separated from the particles by filtration. Samples were fixed at intervals after separation and incubated to demonstrate acid phosphatase activity. They were subsequently embedded and sectioned for electron microscopy. During formation of the food vacuole, the vacuolar membrane is acid phosphatase-negative. Within 5 min, dumbbell-shaped acid phosphatase-positive bodies, possibly derived from the the acid phosphatase-positive Golgi apparatus, apparently fuse with the food vacuole and render it acid phosphatase-positive. A larger type of acid phosphatase-positive, vacuolated body may also fuse with the food vacuole at later stages. At about 20 min after formation, acid phosphatase-positive secondary pinocytotic vesicles pinch off from the food vacuoles and approach a separate system of membrane-bounded spaces. By 1 hr after formation, the food vacuole becomes acid phosphatase-negative, and the undigested latex particles are voided into the membrane-bounded spaces. The membrane-bounded spaces are closely associated with the food vacuole at all stages of digestion and are generally acid phosphatase-negative. Within the membrane-bounded spaces, dense, pleomorphic, granular bodies are found, in which are embedded mitochondria, paraglycogen granules, membrane-limited acid phosphatase-containing structures, and Golgi apparatuses. The granular bodies may serve as vehicles for the transport of organelles through the extensive, ramifying membrane-bounded spaces.     

Changes in Oral Apparatus Structure Accompanying Vacuolar Formation in the Macrostomal Form of Tetrahymena vorax. A Model for the Formation of Food Vacuoles in Tetrahymena1

The large cytopharyngeal pouch of the macrostomal form of Tetrahymena vorax, following the addition of calcium, can form a sealed, empty vacuole. The open cytostomal region of this cell, which averages about 16 μ in diameter, is closed by an upward (ventral) movement of the right and posterior ribbed walls, both of which project into the cytostomal cavity. At the same time, the anterior and left walls of the cytostome-cytopharyngeal complex move to the right, forming a diagonally (right to left) placed furrow in the floor of the buccal cavity as these walls meet. As a result of the movement, the edges of the single membrane-bounded cytopharyngeal pouch are brought together and fuse, producing the closed vacuole. Elements of the cytoskeleton appear to participate in the closure process. Three major groups of ribbed wall microtubules support the open cytostome. The anterior ribbed wall microtubules pass laterally along the anterior (dorsal) portion of the cytopharyngeal pouch to the left where they end in the specialized cytoplasm. Middle oral rib microtubules terminate at the right and posterior margin of the cytopharynx while microtubules from the most posterior region of the ribbed wall pass to the left terminating in the specialized cytoplasm. The fine filamentous reticulum, a striated reticulum that borders the right, posterior, and anterior margins of the cytostome-cytopharyngeal complex, is in an ideal position to participate in these movements. It is anchored anteriorly high up in the buccal cavity to the cross-connective between the third membranelle and the undulating membrane complex. It courses beneath the right and posterior ribbed walls and runs laterally along the anterior margin of the cytopharynx to the left side. Contraction or pulling of this reticulum would act to bring the microtubule-reinforced walls of the cytopharynx together permitting fusion of the cytopharyngeal pouch membranes to form a sealed vacuole.     

Distribution of Acid Phosphatase in Paramecium caudatum: Its Relations with the Process of Digestion

SYNOPSIS. The distribution of acid phosphatase was investigated at the ultrastructural level in Paramecium caudatum. Acid phosphatase occurs in endoplasmic reticulum, Golgi apparatus, food vacuoles, autophagic vesicles, vacuolar and dense bodies. Some slight deposits are also seen in the mitochondria.
These observations point out that this hydrolase activity is related to digestive processes. The enzyme, originating from the endoplasmic reticulum and Golgi apparatus reaches the food vacuole or autophagic vesicle likely via the reticulum. The digestion of the bacteria or of the enclosed organelle gives rise to electronopaque material which is later found in dense bodies. These dense bodies are likely secondary lysosomes and it is possible that they may fuse with the young food vacuole or with autophagic vesicles.     

Light and Electron Microsopic Observations on the Pathogenesis of Naegleria fowleri in Mouse Brain and Tissue Culture

Two strains of pathogenic Naegleria were employed to infect mice and monkey kidney (Vero line) cell cultures. Mice were infected intranasally. Moribund mice were sacrificed and their brains processed for light and electron microscopy. The normal architecture of the infected brain was completely destroyed; the olfactory lobes and the cerebral cortex showed the heaviest damage. The inflammatory response was mainly in the form of neutrophil polymorphs (PMN) and was confined to the olfactory lobes and the superficial regions of cerebral cortex. Numerous amebas were seen interspersed with the degenerating neurons, glial processes, and PMN. Most conspicuous were the food vacuoles which contained host tissue in various stages of digestion. Amebas in the brain tissue also produced many micropinocytotic vesicles from the surface of the plasma membrane. These vesicles are interpreted as vehicles of transport of nutritive materials from the host tissue. The infected cell culture showed the characteristic cytopathic effect (CPE). The CPE was chiefly in the form of cell shrinkage, nuclear pycnosis and discontinuity of cell sheet. Amebas were often seen in an intracellular location. The Vero cells produced many fuzzy pinocytotic vesicles at these loci where the ameba plasma membrane and Vero cell membrane were in close apposition; the probable significance of this is discussed. Most impressive, however, were the pseudopodial formation and capturing of the host material which indicated the great phagocytic activity of the amebas. This was confirmed further by the presence of large numbers of food vacuoles containing host material in various stages of digestion. These observations show that the amebas invade and destroy the brain tissue by active phagocytosis.     

ELECTRON MICROSCOPY OF A CONTRACTILE-VACUOLE MUTANT OF CHLAMYDOMONAS MOEWUSII (CHLOROPHYTA) DEFECTIVE IN THE LATE STAGES OF DIASTOLE1

Electron microscopy of a “vacuole-less” mutant of Chlamydomonas moewusii Gerloff revealed the presence of small anterior vacuoles. These vacuoles behaved like contractile vacuoles in wild-type cells, but they were apparently unable to complete diastole and discharge their contents. When wild-type and mutant cells were incubated in hypertonic medium, small coated vacuoles persisted in the region where contractile vacuoles form. When these cells were transferred to hypotonic medium, the vacuoles appeared to fill and fuse to form larger vacuoles Shortly after the appearance of full expanded contractile vacuoles, collapsed vacuoles were observed in wild-type cells suggesting the completion of diastole and the onset of systole. In mutant cells, the initial steps of filling and fusion to form larger vacuoles apparent interactions of vacuoles with the plasma membrane were not observed. New contractile vacuoles accumulated around the nucleus. When fusion of the contractile vacuole with the plasma membrane was blocked by EGTA, a similar accumulation of large vacuoles occurred. Our observations suggest that the contractile-vacuole mutant of C. Moewusii produces vacuoles which can accumulate excess water as part of the mechanism of osmoregulation but which cannot complete diastole.     

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

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

Calmodulin Localization and its Effects on Endocytic and Phagocytic Membrane Trafficking in Paramecium multimicronucleatum

ABSTRACT. In ciliates, calmodulin (CaM), as in other cells, has multiple functions, such as activation of regulatory enzymes and modulating calcium‐dependent cellular processes. By immunogold localization, CaM is concentrated at multiple sites in Paramecium. It is seen scattered over the cytosol, but bound to its matrix, and is concentrated at the pores of the contractile vacuole complexes and with at least three microtubular arrays. It was localized peripheral to the nine‐doublet microtubules of the ciliary axonemes. The most striking localization was on the akinetic side only of the cytopharyngeal microtubular ribbons opposite the side where the discoidal vesicles, acidosomes and the 100‐nm carrier vesicles bind and move. CaM was also present at the periphery of the postoral microtubular bundles along which the early vacuole moves and was associated with the cytoproct microtubules that guide the spent digestive vacuoles to the cytoproct. It was not found on the membranes of, or in the interior of nuclei, mitochondria, phagosomes, and trichocysts, and was only sparsely scattered over the cytosolic sides of discoidal vesicles, acidosomes, lysosomes, and digestive vacuoles. Together the associations with specific microtubular arrays and the effects of trifluoperazine and calmidazolium indicate that CaM is involved (i) in vesicle transport to the cytopharynx area for vacuole formation and subsequent vacuole acidification, (ii) in early vacuole transport along the postoral fiber, and (iii) in transporting the spent vacuole to the cytoproct. Higher CaM concentrations subjacent to the cell's pellicle and close to the decorated tubules of the contractile vacuole complex may support a role for CaM in ion traffic.     

Structure and behavior of contractile vacuoles inChlamydomonas reinhardtii

Summary The contractile vacuole (CV) cycle ofChlamydomonas reinhardtii has been investigated by videomicroscopy and electron microscopy. Correlation of the two kinds of observation indicates that the total cycle (15 s under the hypo-osmotic conditions used for videomicroscopy) can be divided into early, middle, and late stages. In the early stage (early diastole, about 3 s long) numerous small vesicles about 70–120 nm in diameter are present. In the middle stage (mid-diastole, about 6 s long), the vesicles appear to fuse with one another to form the contractile vacuole proper. In the late stage (late diastole, also about 6 s long), the CV increases in diameter by the continued fusion of small vesicles with the vacuole, and makes contact with the plasma membrane. The CV then rapidly decreases in size (systole, about 0.2 s). In isosmotic media, CVs do not appear to be functioning; under these conditions, the CV regions contain numerous small vesicles typical of the earliest stage of diastole. Fine structure observations have provided no evidence for a two-component CV system such as has been observed in some other cell types. Electron microscopy of cryofixed and freeze-substituted cells suggests that the irregularity of the profiles of larger vesicles and vacuoles and some other morphological details seen in conventionally fixed cells may be shrinkage artefacts. This study thus defines some of the membrane events in the normal contractile vacuole cycle ofChlamydomonas, and provides a morphological and temporal basis for the study of membrane fusion and fluid transport across membranes in a cell favorable for genetic analysis.Abbrevations CV contractile vacuole - PM plasma membrane     

Endocytosis of cationized ferritin by zoospores of the fungusAphanomyces euteiches

Summary Cationized ferritin, a marker for adsorptive endocytosis, was taken up by zoospores of the fungusAphanomyces euteiches. The probe was endocytosed into the numerous, often coated, vesicles surrounding the contractile vacuole. The vacuole itself contained very little ferritin. It is suggested that the contractile vacuole complex is the main area of membrane recycling in the zoospore. After zoospore encystment some of the ferritin was found in multivesicular bodies and the remnants of the contractile vacuole.     

ER arrival sites for COPI vesicles localize to hotspots of membrane trafficking

COPI‐coated vesicles mediate retrograde membrane traffic from the cis‐Golgi to the endoplasmic reticulum (ER) in all eukaryotic cells. However, it is still unknown whether COPI vesicles fuse everywhere or at specific sites with the ER membrane. Taking advantage of the circumstance that the vesicles still carry their coat when they arrive at the ER, we have visualized active ER arrival sites (ERAS) by monitoring contact between COPI coat components and the ER‐resident Dsl tethering complex using bimolecular fluorescence complementation (BiFC). ERAS form punctate structures near Golgi compartments, clearly distinct from ER exit sites. Furthermore, ERAS are highly polarized in an actin and myosin V‐dependent manner and are localized near hotspots of plasma membrane expansion. Genetic experiments suggest that the COPI?Dsl BiFC complexes recapitulate the physiological interaction between COPI and the Dsl complex and that COPI vesicles are mistargeted in dsl1 mutants. We conclude that the Dsl complex functions in confining COPI vesicle fusion sites.     

The fine structure of Crithidia fasciculata with special reference to the organelles involved in the ingestion and digestion of protein

Summary As in other trypanosomatids, the cell membrane of Crithidia fasciculata overlies a single layer of microtubules. Each microtubule possesses a large number of periodically arranged drumstick-like appendages and adjacent microtubules are joined by fibrillar connectives. Anteriorly, the microtubules gradually taper to terminate just before or just after entering the reservoir. An attempt is made to correlate microtubule tapering with maintenance of form of the truncated anterior end of the cell. Smooth and coated vesicles are proliferated from the Golgi saccules and the prominent contractile vacuole lies nearby. The single mitochondrion is extensive and expanded at one point to form a capsule for the kinetoplast. The cristae are predominantly plate-like but other configurations do occur. The cytostome, a shallow invagination of the reservoir membrane, is found between two constrictions in the reservoir wall. Supporting the cytostome are several microtubules which penetrate deeply into the cytoplasm. Ingestion of ferritin occurs by pinocytosis from the cytostome and by coated vesicle formation from the reservoir membrane. Digestion probably occurs in multivesicular bodies which contain acid phosphatase activity.     

Presence of a partially-coated reticulum in angiosperms

Summary The form and distribution of partially-coated membrane systems and coated vesicles in the leaf glands ofPhaseolus and the root cortical cells ofZea were investigated. Partially-coated membranes exist as a reticulum which is either sparsely branched or extensively anastomosed. Coated vesicles and coated membrane regions may occur at all points that are in the vicinity of such a reticulum. Golgi stack membranes, though associated with the partially-coated reticulum in many cases, show no consistent orientation to it. Occasionally, the reticulum and the associated coated vesicles are located away from any Golgi stack. We examined other plant tissues from such species asAllium cepa, Beta vulgaris andNicotiana tabacum and the partially-coated reticulum was observed in all material. We suggest that membrane flow may be occurring from the partially-coated reticulum to either the Golgi stack or to other intracellular compartments.