ULTRASTRUCTURE AND CYTOCHEMISTRY OF EARLY SPERMATANGIAL DEVELOPMENT IN ANTITHAMNION NIPPONICUM (CERAMIACEAE,RHODOPHYTA)1

Spermatial development and differentiation of wall components were investigated by electron microscopy and cytochemical methods in Antithamnion nipponicum Yamada et Inagaki. The spermatium is composed of two parts, a globular head and two appendages projecting from near the basal portion. The appendages originate form spermatangial vesicles (SVs) and follow a developmental sequence beginning as amorphous material and ending as fully formed fibrous structures compressed with in the SVs. SV formation is due to contributions initially from endoplasmic reticulum and later form dictyosome-derived vesicles. Chemical differentiation of the spermatial wall occurs early in its development. Calcofluor white ST does not label spermatial walls, indicating an absence of cellulose polysaccharides, which are abundant in vegetative cell walls. Labeled lectins show that α-d -methyl manose and / or α-d -glucose as well as N-acetyl-glucosamine, β-d -galactose, and α-l -fucose moieties are present on the spermatial wall but not in the vegetative cell wall. The glyconjugate with α-d -methyl mannose and / or glucose residues, previously reported as a gamete recognition molecule in this species, is distributed along the surface of spermatia as well as in the SV during spermatangial development.     

ULTRASTRUCTURE OF SPERMATIAL DEVELOPMENT IN THE PARASITIC RED ALGAE LEVRINGIELLA GARDNERI AND ERYTHROCYSTIS SACCATA12

Morphologically, the development of spermatia in Levringiella gardneri and Erythrocystis saccata is identical, although cytologically several differences are evident. Mature spermatia contain 1 or 2 large spermatial vesicles that contain fibrous material, several small mitochondria, some proplastids, and are surrounded by a wall, either single-layered as in Erythrocystis or triple-layered as in Levringiella. Spermatial vesicles are formed by aggregations of endoplasmic reticulum in Levringiella, whereas concentric membrane bodies and dictyosomes may be involved in Erythrocystis. In addition to being fibrillar, the contents of the vesicle assume a convoluted appearance in Levringiella. Several spermatia are formed per mother cell and are connected by small pit connections which rupture to allow spermatial release from the spermatangial branch.     

Asymmetrical orientation of phospholipids and their interactions with marker enzymes in pig heart mitochondrial inner membrane

The transverse distribution of phospholipids and their interactions with marker enzymes were investigated in pig heart mitoplasts and inverted vesicles, using phospholipase A₂ from N. naja venom and chemical labeling with TNBS and FDNB. Morphological integrity was checked by freeze-fracturing. Fifty percent of phosphatidylcholine was hydrolyzed in mitoplasts as well as in inverted vesicles, suggesting an even distribution of this phospholipid on the two halves of the inner membrane; however, the fatty acid distribution did not appear the same in the two membrane fractions. Cardiolipin is exclusively hydrolyzed in inverted vesicles proving its location on the inner face of the inner membrane. The results obtained from phospholipase hydrolysis and TNBS labeling suggest that three different pools of phosphatidylethanolamine occur in the membrane: a first pool—about 50–60% of the total membrane phosphatidylethanolamine–is quickly accessible from the two sides of the membrane, a second pool—about 20–30% is slowly available, and finally 20–30% are buried within the membrane and inaccessible to the phospholipase and the probe. The cytochrome c oxidase activity increased in mitoplasts with the phospholipase attack suggesting a better accessibility of added cytochrome c after the attack. The rotenone-sensitive NADH-cytochrome c reductase was activated in mitoplasts but completely inactivated in inverted vesicles by the attack; the addition of cardiolipin liposomes restored the latter activity. The soluble matricial malate dehydrogenase was released, but the particulate form of this enzyme, strongly associated to the membrane, was detached only after attack of inverted vesicles.     

THE NUCLEUS OF NOCTILUCA SCINTILLANS : Aspects of Nucleocytoplasmic Exchanges and the Formation of Nuclear Membrane

The unicellular organism, Noctiluca, has been examined with the electron microscope. The nucleus is small compared to the very large size of the cell, but the nuclear border has an organization which indicates an active nucleocytoplasmic exchange. Whereas annuli are missing over most parts of the nuclear membrane proper, there are "annulated vesicles" in a layer inside the nuclear membrane. The hypothesis is put forth that nuclear substances move through the annuli into these vesicles, and that the annulated vesicles themselves are transported through the nuclear membrane. The various forms of the annulated vesicles are consistent with this hypothesis. An implication of this postulate is the synthesis of annulated membranes inside a closed nucleus which are physically separate from the endoplasmic reticulum. The chromosomes are in a state resembling prophase chromosomes and are surrounded by granular masses. Only a small portion of the entire nuclear volume is occupied by the chromosomes. There are many nucleolus-like bodies.     

Localization of D-lactate dehydrogenase in membrane vesicles prepared by using a french press or ethylenediaminetetraacetate-lysozyme from Escherichia coli.

The localization of D-lactate dehydrogenase in membrane vesicles prepared from Escherichia coli was studied using antibody against the purified enzyme. The activity of D-lactate dehydrogenase and D-lactate-dependent oxygen uptake of membrane vesicles prepared by using a French press were completely inhibited by this antibody, suggesting that the enzyme is localized on the outside of these vesicles. This and previous results (Futai, 1974) strongly indicate the inversion of these vesicles. The D-lactate dehydrogenase and D-lactate-dependent oxygen uptake of membrane vesicles prepared by treatment with ethylenediaminetetraacetate-lysozyme were inhibited about 15% by the antibody, whereas proline transport of the vesicles was insensitive to antibody. These results suggest that most of the membrane vesicles have D-lactate dehydrogenase on the inside of the membrane and that such vesicles transport amino acids. This essentially confirms the results of Short, Kaback, and Kohn (1975). However, unlike them we observed that a small but significant portion of activity was sensitive to the antibody as shown above. This portion may represent the completely inverted vesicles in the preparation. Ferricyanide reductase activity cannot be detected in spheroplasts, but about 30 to 50% of the total was detected in membrane vesicles prepared by treatment with ethylenediaminetetraacetate. This confirms our previous findings with membrane prepared by a slightly different procedure. It is concluded that in these vesicles about half the reactive sites for ferricyanide are moved from inside to outside the membrane, whereas 85% of the D-lactate dehydrogenase remains inside the membrane.     

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.     

The formation of the ecdysial droplets and the ecdysial membrane in an insect

Insect cuticle forms as a result of overlapping sequences of two kinds of process, those involving vesicles of the Golgi complex, and those related to transport through and/or assembly at the apical plasma membrane. The ecdysial droplets are the last layer of old cuticle to be deposited before ecdysis and form from the contents of secretory vesicles from Golgi complexes. Ecdysial droplets and secretory vesicles both stain with PTA and react with silver hexamine after oxidation with periodic acid. The vesicles discharge in localized apical areas devoid of microvilli where they accumulate as droplets measuring about 3 [ x 1 [. The. droplets span the last few lamellae of the endocuticle which becomes the ecdysial membrane. They dissolve to leave the ecdysial membrane full of holes at the time that the rest of the old cuticle is digested.     

Sealed inside-out and right-side-out plasma membrane vesicles : optimal conditions for formation and separation

Plasma membrane preparations of high purity (about 95%) are easily obtained by partitioning in aqueous polymer two-phase systems. These preparations, however, mainly contain sealed right-side-out (apoplastic side out) vesicles. Part of these vesicles have been turned inside-out by freezing and thawing, and sealed inside-out and right-side-out vesicles subsequently separated by repeating the phase partition step. Increasing the KCI concentration in the freeze/thaw medium as well as increasing the number of freeze/thaw cycles significantly increased the yield of inside-out vesicles. At optimal conditions, 15 to 25% of total plasma membrane protein was recovered as inside-out vesicles, corresponding to 5 to 10 milligrams of protein from 500 grams of sugar beet (Beta vulgaris L.) leaves. Based on enzyme latency, trypsin inhibition of NADH-cytochrome c reductase, and H⁺ pumping capacity, a cross-contamination of about 20% between the two fractions of oppositely oriented vesicles was estimated. Thus, preparations containing about 80% inside-out and 80% right-side-out vesicles, respectively, were obtained. ATPase activity and H⁺ pumping were both completely inhibited by vanadate (K_i ≈ 10 micromolar), indicating that the fractions were completely free from nonplasma membrane ATPases. Furthermore, the polypeptide patterns of the two fractions were close to identical, which shows that the vesicles differed in sidedness only. Thus, preparations of both inside-out and right-side-out plasma membrane vesicles are now available. This permits studies on transport, signal transduction mechanisms, enzyme topology, etc., using plasma membrane vesicles of either orientation.     

STUDIES ON DEVELOPING AND RELEASED SPERMATIA IN THE RED ALGA,TIFFANIELLA SNYDERAE (RHODOPHYTA)1

Developing and released spermatia of the red alga, Tiffaniella snyderae (Farl.) Abb. were studied. Spermatia were observed under hydrodynamically defined conditions and found to be released from the exposed spermatangial heads in a spermatium-plus-strand unit that remained connected to the spermatangial head. Interactions of single-spermatial strands resulted in the formation of multi-spermatial strands as long as 600 μm with as many as 47 spermatia along their length; however, most were 100–200 μm with 8–21 spermatia. Strand length and number of spermatia were correlated. Spermatial strands contracted or extended and rotated as the water velocity past the plant was changed, and in still water the strands retracted into a clump on the spermatangial head surface. Each strand type exhibited a characteristic threshold water velocity at which it reached maximum length, and above which it broke and was carried away. Fluorescence microscopy showed that the strands did not contain nucleic acid (DNA) and could thus be differentiated from filamentous blue-green algal and bacterial epiphytes. Histochemical staining indicated that the strands and spermatial vesicles contained an acidic, sulfated polysaccharide. Chelation of Ca²⁺ with EGTA resulted in strand breakdown suggesting that this divalent cation may be involved in strand integrity. Scanning electron microscopy revealed that release from the spermatangia occurred through tears in the cuticle covering the spermatangial head if it was still present, or from exposed spermatangia. Individual spermatia were attached tangentially to a well-defined strand 0.64 μm in diameter in the contracted state to 0.2 μm in the extended state. Transmission electron microscopy of spermatangial heads showed that immature spermatangia were characterized by a centrally positioned nucleus and abundant ER cisternae filled with a moderately electron dense granular material. Later in development the spermatangia acquire two spermatial vesicles containing highly convoluted fibrillar contents. The cell becomes polarized with the nucleus displaced apically and the spermatial vesicles occupying the basal half of the spermatangium. At maturity one of the vesicles is released basally. Liberated spermatia contain a membrane-bound nucleus and mitochondria and are associated with an oblong accumulation of fibrous material similar in size and position to the strand observed with the SEM. These strands are discussed in relation to red algal fertilization and other phases of the red algal life-history.     

ATTACHMENT AND FUSION OF GAMETES DURING FERTILIZATION OF PALMARIA SP. (RHODOPHYTA)1

Fertilization of cultured microscopic female gametophytes by spermatia from field-collected male gametophytes of Palmaria sp. was observed by light and transmission electron microscopy. Liberated spermatia had a prophase-arrested nucleus with a pair of polar rings. The protoplast of spermatia was covered with ca. a 3-μm-thick hyaline covering. After spermatium inoculation, the spermatial covering was attached specifically to the coat surrounding the cell wall of the trichogyne. The spermatial covering was eliminated only at the site of gamete attachment, resulting in direct attachment of the spermatial plasma membrane to the trichogyne within 5 min after spermatium inoculation. This direct attachment was followed by completion of spermatial nuclear division and cell wall formation. The polar rings disappeared before prometaphase. The cytoplasm of the binucleate spermatium invaded the trichogyne cell wall and subsequently fused with the trichogyne cytoplasm. The trichogyne could fuse with many spermatia, and many male nuclei (the derivative nuclei of spermatial nuclear division) could enter the trichogyne cytoplasm.     

Orientation and integrity of plasma membrane vesicles obtained from carrot protoplasts

Two fractions enriched in plasma membrane derived from suspension-cultured carrot (Daucus carota L.) cells were examined to determine if they differed from each other either in physical nature or in orientation. Parameters studied included the protein composition of purified membranes derived from trypsinized and nontrypsinized protoplasts as well as from trypsinized purified plasma membranes, the effect of inhibitors and membrane perturbants on ATPase activity, the binding of [acetyl-¹⁴C]concanavalin A to purified membrane fractions, and the competitive removal of [acetyl-¹⁴C]concanavalin A from purified membranes derived from [acetyl-¹⁴C]concanavalin A-labeled protoplasts. One fraction (at density of 1.102 grams per cubic centimeter on Renografin gradients) appears to be a mixed population of `tightly' sealed vesicles with the majority being rightside-out vesicles of plasma membrane, and the other fraction (density 1.128 grams per cubic centimeter) apparently is a population of predominantly `leaky' vesicles and/or nonvesicular fragments of plasma membrane, a large portion of which appear to be `leaky' inside-out vesicles. In addition, it is shown that plasma membrane-enriched fractions can be distinguished from cellular endomembranes on the basis of protein and glycoprotein composition.     

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.     

Fine structure of spermatial surface in the red alga Antithamnion nipponicum (Rhodophyta)

In the ceramiacean red alga Antithamnion nipponicum Yamada et Inagaki, the structure of the spermatial covering and appendages was examined using confocal laser scanning microscopy, scanning and transmission electron microscopy. The liberated spermatium was subspherical, ca 4.5 μm in size with a colorless covering 2.7–3.0‐μm thick. Two flexible, ribbon‐like appendages arose from the periphery of the spermatial covering. The appendages averaged 80 μm in length and were 0.5–0.6 μm width in most parts. Each appendage consisted of a number of thin longitudinal fibrils. Concanavalin A conjugated with fluorescein isothiocyanate, colloidal gold orferritin, bound specifically with the inner layer of spermatial covering and spermatial appendages. When the liberated spermatia were incubated with mature female gametophytes, the spermatial appendages entangled around the tricho‐gyne.     

INNERVATION OF THE FIBRILLAR FLIGHT MUSCLE OF AN INSECT: TENEBRIO MOLITOR (COLEOPTERA)

The structure of peripheral nerves, and the organization of the myoneural junctions in flight muscle fibers of a beetle is described. The uniaxonal presynaptic nerve branches display the "tunicated" structure reported in the case of other insect nerves and the relationship between the axon and the lemnoblast folds is discussed. The synapsing nerve terminal shows many similarities with that of central and peripheral junctions of other insects and of vertebrates (e.g., the intra-axonal synaptic vesicles) but certain important differences have been noted between this region in Tenebrio flight muscle and in other insect muscles. Firstly, the axon discards the lemnoblast before the junction is established and the axon effects a circumferential synapse with the plasma membrane of the fiber, which alone shows the increased thickness often observed in both pre- and postsynaptic elements. Secondly, in addition to the synaptic vesicles within the axon are present, in the immediately adjacent sarcoplasm, great numbers of larger postsynaptic vesicles which, it is tentatively suggested, may represent the sites of storage of the enzymatic destroyer of the activating substance similarly quantized within the intra-axonal vesicles. The spatial relationship between the peripherally located junctions and the portion of the fiber plasma membrane internalized as circumtracheolar sheaths is considered, and the possible significance of this with respect to impulse conduction is discussed briefly.     

Biphasic effect of orthophosphate on the (Na, K)-pump of human red cells

Cultures from various normal and neoplastic cell lines exfoliated vesicles with 5'-nucleotidase activity which reflected the ecto-enzyme activity of the parent monolayer culture. The ratio of 5'-nucleotidase to ATPase activity in the microvesicles indicated that cellular ecto-ATPase was conserved in the exfoliative process. Phospholipids of the microvesicles contained significantly increased amounts of sphingomyelin and total polyunsaturated fatty acids. It was concluded that the shedded vesicles constituted a select portion of the plasma membrane. Examination by electron microscopy showed the vesicles had an average diameter of 500 to 1000 nm and often contained a second population of vesicles about 40 nm in diameter. As much as 70% of the plasma membrane ecto-5'-nucleotidase activity of a culture was released into the medium over a 24-h period. Phosphoesterhydrolases from C-6 glioma or N-18 neuroblastoma microvesicles dephosphorylated cell surface constituents when in contact with monolayer cultures. Exfoliated membrane vesicles may serve a physiologic function; it is proposed that they be referred to as exosomes.     

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.     

Membrane Transport in Isolated Vesicles from Sugarbeet Taproot: III. Effects of Fluoride on ATPase Activity and Transport

The effects of fluoride on the tonoplast type ATPase and transport activities associated with sealed membrane vesicles isolated from sugarbeet (Beta vulgaris L.) storage tissue were examined. This anion had two distinct effects upon the proton-pumping vesicles. When ATP hydrolysis was measured in the presence of gramicidin D, significant inhibition (approximately 50%) only occurred when the fluoride concentration approached 50 millimolar. In contrast, the same degree of inhibition of proton transport occurred when the fluoride concentration was about 24 millimolar. Effects on proton pumping at this concentration of fluoride could be attributed to an inhibition of chloride movement which serves to dissipate the vesicle membrane potential. Valinomycin could partially restore ATPase activity in sealed vesicles which were inhibited by fluoride and this restoration occurred with a reduction in the membrane potential. Fluoride demonstrated a competitive interaction with chloride-stimulation of proton transport and inhibited the uptake of radioactive chloride into sealed vesicles. When the vesicles were allowed to develop a pH gradient in the absence of KCl, and KCl was subsequently added, fluoride reduced enhancement of the existing pH gradient by KCl. The results are consistent with a chloride carrier that is inhibited by fluoride.     

ELECTRON MICROSCOPIC OBSERVATIONS ON THE DIFFERENTIATION AND RELEASE OF SPERMATIA IN THE MARINE RED ALGA POLYSIPHONIA HENDRYI (CERAMIALES,RHODOMELACEAE)

Spermatial differentiation in Polysiphonia hendryi begins after nonpolar, avacuolate spermatia are cleaved from their mother cells. The spermatia and their mother cells are embedded within the spermatangium, a confluent wall matrix of the male branch. As the young spermatium enlarges and becomes ellipsoid, the wall fibrils of the spermatangium are compressed, forming a separating layer. Spermatia become polar with rough endoplasmic reticulum coalescing to form a large, fibrillar spermatial vacuole that becomes extracytoplasmic in later development. Following spermatial vacuole formation, dictyosomes form and deposit a spermatial wall, severing the spermatial mother-cell pit connection. Enlargement of younger spermatia, which are lateral to the older ones, squeezes the maturing spermatia, pushing them from the male branch, and leaving a scar that compresses and heals. Through this release mechanism, new sites are created for additional spermatial proliferation.     

Mode of action of colicin Ib Formation of ion-permeable membrane channels

Addition of purified colicin Ib to whole Escherichia coli cells or cytoplasmic membrane vesicles inhibits their subsequent ability to generate a membrane potential. In addition, this colicin is shown to bring about a voltage-dependent increase in the conductance of an artificial planar bilayer membrane prepared from soybean phospholipids. This results from the formation of ion-permeable channels. These data provide strong evidence that the depolarization of Escherichia coli cells by this colicin results from an Ib-induced increase in membrane permeability to ions.     

The DCCD-binding polypeptide is close to the F1 ATPase-binding site on the cytoplasmic surface of the cell membrane of Escherichia coli

Removal of the F₁ ATPase from membrane vesicles of $\text{Escherichia}\text{coli}$ resulted in leakage of protons across the membrane through the F_O portion of the ATPase complex. The leakage of protons was prevented by antiserum to the N,N′-dicyclohexylcarbodiimide (DCCD)-binding polypeptide in everted but not in “right-side out” membrane vesicles. The antiserum prevented the rebinding of F₁ ATPase to F₁-stripped everted membrane vesicles. It is concluded that in F₁-depleted vesicles the DCCD-binding polypeptide is exposed on the cytoplasmic surface of the cell membrane at or close to the binding site of the F₁ ATPase.