Orderly formation of the double ring structures for plastid and mitochondrial division in the unicellular red alga Cyanidioschyzon merolae

The formation of the plastid-dividing ring (PD ring) and mitochondrion-dividing ring (MD ring) was studied in a highly synchronous culture of the unicellular red alga Cyanidioschyzon merolae. The timing and the order of formation of the MD and PD rings were determined by observing organelles around the onset of their division, using transmission electron microscopy. In  C. merolae, there is one chloroplast and one mitochondrion per cell, and the shape of the chloroplast changes sequentially from acorn-like, to round, to trapezoidal, to peanut-shaped, in that order, during the early stage of chloroplast division. None of the cells with acorn-shaped or round chloroplasts contained organelles with PD rings or MD rings, while all of the cells with peanut-shaped chloroplasts contained organelles with both PD rings and MD rings. In cells with peanut-shaped chloroplasts, the PD and MD rings were double ring structures, with an outer ring located on the cytoplasmic face of the outer membrane of the organelle, and an inner ring located in the matrix beneath the inner membrane. These results suggested that the double ring structures of the PD ring and the MD ring form when chloroplasts are trapezoidal in shape. Detailed three-dimensional observation of cells with trapezoidal chloroplasts revealed the following steps in the formation of the double ring structures of the PD and MD rings: (i) the inner ring of the PD ring forms first, followed by the outer ring; (ii) then the MD ring forms and becomes visible; (iii) when the double ring structures of the two rings have formed, the microbody then moves from its remote location to the plane of division of the mitochondrion and contraction of the PD and MD rings commences. These steps were also confirmed by computer-aided three-dimensional reconstruction of the images from serial thin sections. This study reveals the order of formation of the double ring structures of the PD and MD rings, and the behavior of the microbody around the onset of division of plastids and mitochondria. The results also provide the first evidence that the inner PD ring is not a tension element formed by the contractile pressure but a definite structure, independent of the outer ring. Received: 31 March 1998 / Accepted: 14 May 1998     

ULTRASTRUCTURE OF MUCOCYSTS AND PELLICLE OF TETRAHYMENA PYRIFORMIS

Tetrahymena pyriformis GL was fixed with glutaraldehyde and/or OsO₄ for a study of cytoplasmic ultrastructure. Many small vacuoles 0.05 to 0.5 µ in diameter were found to contain each a dense particle enveloped by a limiting membrane. This membrane is continuous with the membrane of the vacuole. The particles are irregular in shape and size, but similar to the mucocysts in the appearance of the matrix. It is suggested that they are the first morphologically distinguishable stages in the development of mucocysts. In the course of this development, amorphous material becomes crystalline with a longitudinal period of 150 A and a lateral period of 100 A. The mature mucocysts are rather uniform in size and have a spheroidal shape. During discharge, the crystalline pattern disappears and the mucocysts assume a spherical configuration. The inner limiting membrane of a mucocyst seems to disintegrate during the process of discharge while the outer membrane becomes continuous with the outermost pellicular membrane; the inner pellicular membrane is continuous with the cytoplasmic membrane. Rows of few to 15 or more microtubules were found either between the cytoplasmic membrane and the ectoplasmic layer (longitudinal fibrils) or underneath the ectoplasmic layer (transverse fibrils). The outer and inner pellicular membranes are uniformly spaced and connected by "cross-bridges." Details of these structures are described.     

L'Organisation Ultrastructurale Corticale de la Gregarine Lecudina pellucida; ses Rapports avec l'Alimentation et la Locomotion

SYNOPSIS. The structure of the cortical region (epicyte and ectoplasm) of the gregarine Lecudina pellucida , an intestinal parasite of the polychete worm Perinereis cultrifera was studied by electron microscopy.
The epicitary folds have 3 unit type membranes. Between the 1st and 2nd is a layer probably composed of fine longitudinal fibrils which has an arch-like or gutter-like structure at the crest of the folds. Inside these folds is cytoplasm without any noticeable differentiation or inclusion except for a granular (or finely fibrillar) layer under the limiting inner membrane and close to it.
The ectoplasmic zone of the entocyte is separated from the epicitary region by a lengthwise discontinuous cylindrical opaque layer, inwardly tangential to the folds. The ectoplasm lacks paraglycogen granules but has various organelles: apparently pinocytic vesicles against the wall between the folds, vesicles with myelinic membranes, opaque granules, a few mitochondria with blistered internal vesicles, and a few circular tubular fibers.
The superficial zone of the gregarine is supposed to contribute to nutrition, thru the extensive surface furnished by its folds and thru the pinocytic vesicles; but this alimentary intake is incomplete compared with that of the previously studied anterior region.
Insufficient mucus is discharged to account for locomotion. There are some circular ectoplasmic fibers, but locomotory myonemes are completely absent. However, there are deformations of the folds and corresponding waves that could account for locomotion by creeping or swimming. These movements of the folds might be due to the action of the contractile proteins and correspond with some of the layers seen in the wall.     

DIVISION APPARATUS OF THE CHLOROPLAST IN NANNOCHLORIS BACILLARIS (CHLOROPHYTA)1

Chloroplast division in Nannochloris bacillaris Naumann (Chlorophyta) was examined by electron microscopy after preparation of samples by freeze-substitution. A pair of belts appeared on the surface of the outer and inner envelope membranes at the middle of the chloroplast. These belts seemed to be constructed of thin fibrils that run parallel to the longitudinal direction of the belts. The outer fibrillar belt increased in width as the constriction of the chloroplast advanced. It appears that the fibrillar belt is the division apparatus of the chloroplast. It encircles the chloroplast and finally divides the chloroplast in two as the diameter of the belt decreases.     

MORPHOLOGY AND PAEDOGAMOUS SEXUAL REPRODUCTION IN CHLOROGONIUM CAPILLATUM SP. NOV. (VOLVOCALES, CHLOROPHYTA)1

Morphology and sexual reproduction in Chlorogonium capillatum Nozaki, Watanabe & Aizawa sp. nov. (Volvocales, Chlorophyta) originating from Miyatoko Mire, Japan, were studied under controlled laboratory conditions. Vegetative cells of this new species were fusiform with blunt anterior and posterior ends, and they had a massive parietal chloroplast and numerous contractile vacuoles distributed throughout the protoplast. Several to many pyrenoids were randomly distributed in the chloroplast, but they disappeared under the light microscope when grown photoheterotrophically. During asexual reproduction, the first division took place transversely without a preceding rotation of the parental protoplast. In sexual reproduction, the parental protoplast divided successively to form 32 or 64 small, biflagellate isogametes. After gametogenesis, the gametes did not escape from the parental cell (gametangial) wall, within which pairs of the adjoining gametes fused to form quadriflagellate zygotes. Such zygotes were then released from the parental cell wall and developed into hypnozygotes, which at maturity developed numerous thin spines or hairs on the zygote wall. On zygote germination, four biflagellate germ cells were released from the zygote wall separately. This type of gametic union, "paedogamy," has not previously been described in the green algae except for Chlorococcum echinozygotum Starr . Chlorogonium capillatum can be clearly distinguished from other described species of Chlorogonium by its numerous contractile vacuoles and blunt anterior and posterior ends in vegetative cells as well as by its unique sexual reproduction, in which paedogamous conjugation occurs, and numerous thin spines or hairs that develop on the hypnozygote walls .     

Arrangement and possible function of actin filament bundles in ectoplasmic specializations of ground squirrel Sertoli cells

We have investigated the arrangement and function of actin filament bundles in Sertoli cell ectoplasmic specializations found adjacent to junctional networks and in areas of adhesion to spermatogenic cells. Tissue was collected, from ground squirrel (Spermophilus spp.) testes, in three ways: seminiferous tubules were fragmented mechanically; segments of intact epithelium and denuded tubule walls were isolated by using EDTA in a phosphate-buffered salt solution; and isolated epithelia and denuded tubule walls were extracted in glycerol. To determine the arrangement of actin bundles, the tissue was fixed, mounted on slides, treated with cold acetone (-20 degrees C), and then exposed to nitrobenzoxadiazole-phallacidin. Myosin was localized using immunofluorescence. To investigate the hypothesis that ectoplasmic specializations are contractile, glycerinated models were exposed to exogenous ATP and Ca++; then contraction was assessed qualitatively by using nitrobenzoxadiazole-phallacidin as a marker. Actin bundles in ectoplasmic specializations adjacent to junctional networks circumscribe the bases of Sertoli cells. When intact epithelia are viewed from an angle perpendicular to the epithelial base, honeycomb staining patterns are observed. Filament bundles in Sertoli cell regions adjacent to spermatogenic cells dramatically change organization during spermatogenesis. Initially, the bundles circle the region of contact between the developing acrosome and nucleus. They then expand to cover the entire head. As the spermatid flattens, filaments on one side of the now saucer-shaped head orient themselves parallel to the germ cell axis while those on the other align perpendicularly to it. Before sperm release, all filaments course parallel to the rim of the head. Contrary to the results we obtained with myoid cells, we could not convincingly demonstrate myosin in ectoplasmic specializations or induce contraction of glycerinated models. Our data are consistent with the hypothesis that actin in ectoplasmic specializations of Sertoli cells may be more skeletal than contractile.     

Contractility of Glycerinated Amoeba proteus and Chaos-chaos*

Immediate contact with large volumes of cold 50% (v/v) buffered glycerol preserved typical ameboid shape of Chaos chaos and Amoeba proteus with no visible distortions. These technics allowed determination of the contraction sites in these glycerinated models upon application of ATP-Ca-Mg-solutions. The ectoplasmic tube was the main site of contraction. Preliminary EM investigations revealed thick and thin filaments, associated with the ectoplasmic tube near the plasmalemma, which appeared to be the basis for the contractility of the ectoplasmic tube. There was no predominant contraction of the pseudopodial tips or the endoplasm in these models. The changes of volume were as much as 50%, and in some cases were not accompanied by any change in the length of the ameba; however, lengthwise contractions of the ectoplasmic tube in some amebae occurred to as much as 25%. The data substantiate a basic requirement of the ectoplasmic tube contraction theory of ameboid locomotion.     

Crystal structure of a conserved domain in the intermembrane space region of the plastid division protein ARC6

The chloroplast division machinery is composed of numerous proteins that assemble as a large complex to divide double‐membraned chloroplasts through binary fission. A key mediator of division‐complex formation is ARC6, a chloroplast inner envelope protein and evolutionary descendant of the cyanobacterial cell division protein Ftn2. ARC6 connects stromal and cytosolic contractile rings across the two membranes through interaction with an outer envelope protein within the intermembrane space (IMS). The ARC6 IMS region bears a structurally uncharacterized domain of unknown function, DUF4101, that is highly conserved among ARC6 and Ftn2 proteins. Here we report the crystal structure of this domain from Arabidopsis thaliana ARC6. The domain forms an α/β barrel open towards the outer envelope membrane but closed towards the inner envelope membrane. These findings provide new clues into how ARC6 and its homologs contribute to chloroplast and cyanobacterial cell division.     

ULTRASTRUCTURE OF THE PSEUDOCAPILLITIUM AND SPORES OF THE MYXOMYCETE LYCOGALA EPIDENDRUM. LICEALES

The pseudocapillitium and spores of L. epidendrum were studied by transmission (TEM) and scanning electron microscopy (SEM). The SEM reveals that the pseudocapillitial surface is covered by bands of “wartlike” processes that alternate with non-ornamented regions. Otherwise, the pseudocapillitium is a hollow structure composed of three regions. The outer region is thin, electron dense and continuous with many irregular processes. Internal to this area is an amorphous region containing scattered electron dense material. The innermost region of the pseudocapillitium is thin, inconspicuous and usually electron dense. L. epidendrum possesses spores that are covered by a surface reticulum consisting of polygonal areas which are continuous with the outermost spore layer. The outer spore layer is thin and electron dense. The inner spore layer is an electron transparent region that contains granular or fibrillar components. Sections of spores showed a dense cytoplasm possessing most of the usual organelles along with microtubules and microbodies.     

Change of contractile behavior in plasmodia ofPhysarum polycephalum during mitosis

Summary Oscillations of ectoplasmic contraction in plasmodia of the myxomycetePhysarum polycephalum growing on agar containing semidefined medium were studied to determine if the contractile force is altered during the synchronous mitosis. In interphase the regular oscillations of contraction in the plasmodial sheet had an average period of 0.93 minutes in plasmodia growing at 24 °C. During mitosis the amplitude of these oscillations gradually decreased, ceasing for an average time of 2.7 minutes in 74% of the 23 plasmodia studied. Cessation of oscillating contractions in mitosis was accompanied by a decrease in the width of the channels embedded in the plasmodial sheet, and a decrease in the velocity of endoplasmic shuttle streaming usually to a complete standstill. Of 13 plasmodia in which the mitotic stage was very accurately determined, the stop in oscillating contractions occurred during metaphase in 10 plasmodia, and in prometaphase, anaphase, telophase in the 3 others. The cessation of contractile oscillations or of streaming did not occur absolutely simultaneously during mitosis in widely separated locations within one plasmodium, indicating mitotic asynchrony over a period of a few minutes within each plasmodium. We suggest that the halt of plasmodial migration during mitosis reported by others is caused by a decrease or cessation at slightly different times in the amplitude of ectoplasmic contractile oscillations in different areas of a plasmodium in mitosis resulting in an overall lack of coordination of endoplasmic flow throughout the plasmodium, thus temporarily halting migration. Possible physiological mechanisms linking a decrease in actomyosin contraction with the metaphase stage of mitosis are discussed.     

Relative motion inAmoeba proteus in respect to the adhesion sites

Summary The whole ectoplasmic layer of polytactic and heterotactic forms ofA. proteus behaves as self-contractile structure. Depending on the configuration of cell body and on the cell-to-substrate attachment conditions it continuously retracts from each distal cell projection toward its centre and/or from each free body end toward the actual adhesion sites. As in the monotactic forms, it leads to the withdrawal of the tail region behind the retraction center and may result in the fountain movement in front of it. In the long unattached pseudopodia of heterotactic forms the ectoplasm is retracted in the fountain form, with the velocity linearly increasing from the basis of pseudopodium up to its tip. In polytactic cells the fountain is often absent, if the advancing fronts immediately adhere to the substrate. When they develop in unattached condition, or are experimentally obliged to detach, the ectoplasmic cylinders of frontal pseudopodia are retracted backwards. On the substrates which do not offer firm points of support the cell periphery moves back as a whole,i.e., the principal ectoplasmic cylinder retracts together with the cylinders of lateral pseudopodia, and the direction and speed of movement in any spot is the resultant of forces produced by all other segments. The retraction of ectoplasmic gel layer is independent of the endoplasmic flow in such extent that a pseudopodium may be withdrawn as a whole in spite of the endoplasm streaming directed forwards in its interior. On the cell surface the particles attached by adhesion (glass rods) strictly follow the movements of the internal ectoplasmic structures, whereas the unattached particles flow forward in the direction of endoplasm streaming.Study supported by Research Project II. 1 of the Polish Academy of Science.     

Oriented thick and thin filaments in amoeba proteus

Actin and myosin filaments as a foundation of contractile systems are well established from ameba to man (3). Wolpert et al. (19) isolated by differential centrifugation from Amoeba proteus a motile fraction composed of filaments which moved upon the addition of ATP. Actin filaments are found in amebas (1, 12, 13) which react with vertebrate heavy meromyosin (HMM), forming arrowhead complexes as vertebrate actin (3, 9), and are prominent within the ectoplasmic tube where some of them are attached to the plasmalemma (1, 12). Thick and thin filaments possessing the morphological characteristics of myosin and actin have been obtained from isolated ameba cytoplasm (18, 19). In addition, there are filaments exhibiting ATPase activity in amebas which react with actin (12, 16, 17). However, giant ameba (Chaos-proteus) shapes are difficult to preserve, and the excellent contributions referred to above are limited by visible distortions occurring in the amebas (rounding up, pseudopods disappearing, and cellular organelles swelling) upon fixation. Achievement of normal ameboid shape in recent glycerination work (15) led us to attempt other electron microscope fixation techniques, resulting in a surprising preservation of A. proteus with a unique orientation of thick and thin filaments in the ectoplasmic region.     

Ultrastructure of the marine predatory flagellate <Emphasis Type="Italic">Metromonas simplex</Emphasis> Larsen et Patterson, 1990 (Cercozoa)

The ultrastructure of the marine predatory flagellate Metromonas simplex Larsen et Patterson was studied. The cell is surrounded by a low-contrast fibrous layer composed of thin hairs covered by a thin bilayer membrane and an outer layer of thin short fibers. The plasmalemma lies under these layers. The predator captures whole cells of the prey, usually bodonids or chrysomonads. The cytostome as a cell pocket is undetectable. The long flagellum bears very thin mastigonemes (hairs) with lengths of 0.8–1.0 μm; the short flagellum is naked and reduced in length. The transitional zone lacks spirals or other additional elements. The transversal plate is elevated on the cell surface. The flagellar root system is very simple and has one microtubular band which originates near the kinetosomes. The latter are parallel to each other and interconnected by fibrous bridges. The vesicular nucleus, Golgi apparatus, and endoplasmic reticulum are of typical structures. The oval mitochondria of 0.6–2.5 μm contain lamellar cristae. The cylindrical extrusomes (trichocysts) found in the cytoplasm have lengths of 1.0–1.4 μm and diameters of 0.12–0.08 μm. The trichocysts have a wheel-shaped structure with 13 spokes visible in cross-sections. The contractile vacuole is absent. The similarity that M. simplex shares with Metopion fluens Larsen et Patterson, cryothecomonads, and other predatory flagellates is discussed.     

Reorganization and translocation of the ectoplasmic cytoskeleton in the leech zygote by condensation of cytasters and interactions of dynamic microtubules and actin filaments

The formation and bipolar translocation of an ectoplasmic cytoskeleton of rings and meridional bands was studied in interphase zygotes of the glossiphoniid leech Theromyzon trizonare. Zygotes consisted of a peripheral organelle-rich ectoplasm and an internal yolk-rich endoplasm. After microinjection of labeled tubulin and/or actin, zygotes were examined by time-lapse video imaging, immunofluorescence and confocal microscopy. The rings and meridional bands were formed by condensation of a network of moving cytasters that represented ectoplasmic secondary centers of microtubule and actin filament nucleation. In some cases the network of cytasters persisted between the rings. The cytoskeleton had an outer actin layer and an inner microtubule layer that merged at the irregularly-shaped boundary zone. Bipolar translocation of the rings, meridional bands, or the network of cytasters led to accumulation of the cytoskeleton at both zygote poles. Translocation of the cytoskeleton was slowed or arrested by microinjected taxol or phalloidin, in a dose-dependent fashion. Results of drug treatment probably indicate differences in the degree and speed at which the cytoskeleton becomes stabilized. Moreover, drugs that selectively stabilized either microtubules or actin filaments stabilized and impaired movement of the entire cytoskeleton. Microtubule poisons and latrunculin-B failed to disrupt the cytoskeleton. It is concluded that the microtubule and actin cytoskeletons are dynamic, presumably cross-linked and resistant to depolymerizing drugs. They probably move along each other by a sliding mechanism that depends on the instability of microtubules and actin filaments.     

Photosynthetic Reactions in the Marine Alga Codium vermilara: II. Structural Studies

Chloroplasts from Codium vermilara, isolated by relatively crude methods, are able to fix CO₂ at rates comparable to the rates of intact plants. Sections in thalli of Codium vermilara show that the chloroplasts are surrounded by a thin layer of cytoplasm. This surrounding layer of cytoplasm, is retained also in isolated chloroplasts, and presumably preserves the intactness of the chloroplast envelope.     

Purity of Chloroplasts Prepared from the Siphonous Green Alga, Caulerpa simpliciuscula, as Determined by Their Ultrastructure and Their Enzymic Content

The ultrastructure and enzyme distribution in chloroplasts and other subcellular fractions isolated from the siphonous green alga, Caulerpa simpliciuscula, are described. The isolated chloroplasts were similar in appearance to those in the tissue from which they were derived, and in typical preparations 70% or more were intact. Chloroplasts which had lost their outer envelopes could be separated from intact plastids by centrifugation at low speeds through gradients of colloidal silica. Intact chloroplasts separated in this way retained their photosynthetic capacity and were impermeable to ferricyanide ions. The chloroplast preparations separated by differential centrifugation and refractionated using either discontinuous or continuous Percoll gradients contained non-chloroplast material. It was estimated that this amounted to a maximum of 10% of the mitochondrial population and 6% of cytoplasm extracted from the plant. The contaminating material surrounded the chloroplasts in a thin layer and was surrounded by a membrane.     

Ultrastructure of trichoblasts in the red alga Osmundea spectabilis var. spectabilis (Rhodomelaceae,Ceramiales)

The apex of the tetrasporangial branches of Osmundea spectabilis var. spectabilis (= Laurencia spectabilis var. spectabilis) exhibits cavities in which tufts of multicellular trichoblasts occur. Trichoblast development in Osmundea spectabilis var. spectabilis begins with the differentiation of an epidermal cell within the crypt. This cell differentiates into a trichoblast mother cell (TMC). The TMC divides to form a two-celled incipient trichoblast. Successive periclinal divisions of the apical cell of the young trichoblast result in the formation of a multicellular developing trichoblast. With the exception of the apical cell all trichoblast cells are at the same developmental stage. They possess a large nucleus, abundant plastids with peripheral and some internal thylakoids and dictyosomes. Daughter chloroplasts result from one constriction or multiple fission of a single chloroplast. Dictyosomal cisternae and mucilage sacs contribute material to wall formation. Each differentiating trichoblast cell is surrounded by a bi-layered wall. The outer wall layer represents the trichoblast mother cell wall and the inner wall layer is the trichoblast cell wall. Mature trichoblast cells have thin walls, probably as a consequence of mucilage extrusion, the most likely function of trichoblasts in Osmundea.     

Electron microscopy studies of the limiting layers of the rickettsia Coxiella burneti.

Surface layers of Coxiella burneti studied at a high resoulution reveal a plasma membrane and an outer surface membrane 6 to 7 nm thick, and a thin, moderately electron-dense intermediate layer associated with the inner surface of the outer membrane of many cells. This layer appears to be unaffected by lysozyme treatment. Ruthenium red staining was used to delineate a layer of filamentous material external to the outer membrane; this fuzzy layer has a mean thickness of 20 nm and is not often seen on the surface of cells prepared by conventional means. Both antigenic phase I and II cells show a ruthenium red-binding surface layer. It is suggested that this fuzzy layer may be, among other possibilities, a highly branched mucopolysaccharide.     

Ultrastructure of hyphae and ascospores in the genus Eremascus eidam

Hyphae and ascospores of Eremascus fertilis and E. albus were studied in ultrathin sections. The lateral wall of the hyphae had a thick electron-light inner layer and a thin dark outer layer. The septa had a simple central pore with or without a plug, and there were Woronin bodies in the vicinity. The wall of the ascospores of E. fertilis showed a thick light inner layer and a thin dark outer layer. In the wall of the spores of E. albus a dark fibrillar layer was present between the light inner layer and the dark outer layer. The spores of this species germinated with a tube the wall of which was continuous with a newly formed layer inside the spore wall.This investigation was supported by the Netherlands Organization for the Advancement of Pure Research (Z. W. O.)     

Seed Epidermis Development and Histochemistry in Solanum melongena L. and S. violaceum Ort.

Structure, development and histochemistry of the seed epidermiswere studied inSolanum melongena L. andS. violaceum Ort. usinglight and scanning electron microscopy. The epidermal cellsat the endosperm mother cell stage of ovule development hadthickened outer periclinal walls, consisting of two layers,a thin inner layer, and a thick outer layer. The latter whichstained positively for pectic substances became further thickenedduring the course of seed development; more so inS. melongena.The inner layer of the outer periclinal wall also was thickenedby depositions of cellulose but remained comparatively thin.The development of the inner periclinal and anticlinal wallstook place by the uneven deposition of concentric layers. Thesesecondary wall thickenings which appeared as pyramids in transversesection stained for cellulose, lignin and pectin. Further unevensecondary thickenings near the outer part of the anticlinalwalls resulted in the formation of projections which were hair-or ribbon-like in appearance. InS. melongena, these projectionsprogressed only a short distance from the anticlinal wall. InS.violaceum, on the other hand, they grew much longer formingstriations on the inside of the outer periclinal wall. InS.melongena, partial removal of the outer periclinal wall by enzymeetching exposed to surface view a beaded appearance of the cellboundaries. Complete erosion of the outer periclinal wall revealedthe hair-like projections of the underlying anticlinal walls.InS. violaceum, enzyme treatment exposed the striations whichformed bridge-like structures over the curves in the anticlinalwalls. Solanum melongena ; Solanum violaceum; seed epidermis; seed structure; seed development; cell wall histochemistry; cell wall projections; cell wall striations