Euglenoid movement inEuglena fusca: Evidence for sliding between pellicular strips

Summary InEuglena fusca, each pellicular strip carries a row of particles on its surface. The relative displacement of particles on adjacent strips was analysed by video-microscopy and evidence was obtained that adjacent pellicular strips slide relative to each other during euglenoid movement.E. fusca shows two types of euglenoid movement, oscillatory bending and rounding-up of the cell body. During oscillatory bending, the maximum velocity of sliding was 0.4 m/s and the maximum displacement distance between adjacent strips 2.3 m about their mean position. WhenE. fusca exhibited rounding-up of the cell body, particle displacement again occurred and the angle of the pellicular strips to the long axis of the cell body increased because of pellicular sliding. As a result the distance between the cell's anterior and posterior tips was reduced. There was no change in distance either between rows of particles or between particles within the same row. The findings are incompatible with theories of euglenoid movement requiring local contraction of pellicular strips and point to the likely existence of active sliding between adjacent strips.     

High-salt solutions prevent reactivation of euglenoid movement in detergent-treated cell models ofEuglena gracilis

Summary Detergent-treated cell models ofEuglena gracilis showed rounded-up movement of the cell body upon addition of ATP and Ca²⁺. Reactivation of the cell models was inhibited when the cell models had been treated with solutions containing >150 mM NaCl or >300 mM KC1. When the supernatant of salt-extracted cell models was subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis, two distinctive bands of 120 and 160 kDa were found to be enriched. The cell membrane and associated cytoskeleton (pellicular complex) were isolated after treatment with salt solutions, and examined by electron microscopy to identify essential cortical structures required for reactivating rounding-up cell movement. Among three regularly arranged microtubules, only one and its associated structures were selectively dissolved from the pellicular strips, while the other pellicular elements remained intact. These structures were located in the groove region where sliding between strips is believed to occur during cell shape change. These results suggest a possible involvement of microtubule 2 and its associated bridges in active sliding between adjacent pellicular strips during euglenoid movement.     

NOVEL PELLICLE SURFACE PATTERNS ON EUGLENA OBTUSA (EUGLENOPHYTA) FROM THE MARINE BENTHIC ENVIRONMENT: IMPLICATIONS FOR PELLICLE DEVELOPMENT AND EVOLUTION1

Euglena obtusa F. Schmitz possesses novel pellicle surface patterns, including the greatest number of strips (120) and the most posterior subwhorls of strip reduction in any euglenid described so far. Although the subwhorls form a mathematically linear pattern of strip reduction, the pattern observed here differs from the linear pattern described for Euglena mutabilis F. Schmitz in that it contains seven linear subwhorls, rather than three, and is developmentally equivalent to three whorls of exponential reduction, rather than two. These properties imply that the seven‐subwhorled linear pattern observed in E. obtusa is evolutionarily derived from an ancestral bilinear pattern, rather than from a linear pattern, of strip reduction. Furthermore, analysis of the relative lateral positions of the strips forming the subwhorls in E. obtusa indicates that (1) the identity (relative length, lateral position, and maturity) of each strip in any mother cell specifies that strip’s identity in one of the daughter cells following pellicle duplication and cell division, (2) the relative length of any given pellicle strip regulates the length of the nascent strip it will produce during pellicle duplication, and (3) pellicle pores develop within the heels of the most mature pellicle strips. These observations suggest that continued research on pellicle development could eventually establish an ideal system for understanding mechanisms associated with the morphogenesis and evolution of related eukaryotic cells.     

THE ULTRASTRUCTURE OF THE PELLICLE COMPLEX OF EUGLENA GRACILIS

The pellicle complex of E. gracilis is composed of the cell membrane, the ridge and groove with the notch, four fibrils, and the subpellicular ER. The cell membrane is of unit membrane configuration and covers the outside of the cell, the cytostome, the gullet, and the reservoir. The notch of the pellicle complex has always a close topographic relationship to two particular fibrils, as well as the subpellicular ER. The gullet is that region between the reservoir and the cytostome which, in addition to longitudinal fibrils, is surrounded by a single row of circular fibrils. The circumference of the cytostome has twenty large pellicular ridges alternating with small pellicular ridges. Alternating tall and small pellicular ridges cover the entire cell during division.     

The Fine Structure of Rhynchocystis pilosa (Sporozoa, Eugregarinida)

SYNOPSIS. The trophozoite of Rhynchocystis pilosa obtained from the seminal vesicles of the earthworm Lumbricus terrestris was studied by light and electron microscopy. The trophozoite's cortical organization is particularly interesting because of its unusual evaginations and associated fibrillar structures. The pellicle is formed by 2 concentric membranes elevated into 60–70 alternating primary and secondary ridges extending posteriad. Numerous long ‘hairs’ or cytopilia originate along the primary ridges and each contains a system of fibrils originating from an underlying longitudinal myoneme. Longitudinal rows of pores lie between adjacent pollicular ridges. Three systems of fibrils lie in the cortex of the trophozoite. A longitudinal myoneme consisting of 12–18 fibrils lies below each primary pellicular ridge. Circular myonemes lie below the pellicle in a parallel array along the length of the organism. Each myoneme consists of 4–8 fibrils structurally similar to those of the longitudinal myonemes. Pairs of fine filaments also lie in the inner pellicular membrane along the apex of each ridge. The trophozoite's anterior end is modified as an attachment organelle consisting of 30–35 delicate pellicular folds which originate at the base of an anterior papilla. The folds extend approximately 15 μ posteriad where they become continuous with the primary pellicular ridges. The nucleus lies in the cytoplasm near the posterior level of the attachment organelle and is surrounded by a double membrane perforated by numerous pores. The cytoplasm contains numerous small vesicles which may be found in dense aggregations. These aggregations often occur in proximity to Golgi complexes and certain membrane-bound bodies. Mitochondria are abundant in the cytoplasm as are large, ovoid paraglycogen bodies. Occasionally layers of granular membranes are arranged parallel to the surface of the paraglycogen bodies but also occur thruout the cytoplasm.     

New phagotrophic euglenoid species (new genus Decastava; Scytomonas saepesedens; Entosiphon oblongum), Hsp90 introns,and putative euglenoid Hsp90 pre-mRNA insertional editing

We describe three new phagotrophic euglenoid species by light microscopy and 18S rDNA and Hsp90 sequencing: Scytomonas saepesedens; Decastava edaphica; Entosiphon oblongum. We studied Scytomonas and Decastava ultrastructure. Scytomonas saepesedens feeds when sessile with actively beating cilium, and has five pellicular strips with flush joints and Calycimonas-like microtubule-supported cytopharynx. Decastava, sister to Keelungia forming new clade Decastavida on 18S rDNA trees, has 10 broad strips with cusp-like joints, not bifurcate ridges like Ploeotia and Serpenomonas (phylogenetically and cytologically distinct genera), and Serpenomonas-like feeding apparatus (8–9 unreinforced microtubule pairs loop from dorsal jaw support to cytostome). Hsp90 and 18S rDNA trees group Scytomonas with Petalomonas and show Entosiphon as the earliest euglenoid branch. Basal euglenoids have rigid longitudinal strips; derived clade Spirocuta has spiral often slideable strips. Decastava Hsp90 genes have introns. Decastava/Entosiphon Hsp90 frameshifts imply insertional RNA editing. Petalomonas is too heterogeneous in pellicle structure for one genus; we retain Scytomonas (sometimes lumped with it) and segregate four former Petalomonas as new genus Biundula with pellicle cross section showing 2–8 smooth undulations and typified by Biundula (=Petalomonas) sphagnophila comb. n. Our taxon-rich site-heterogeneous rDNA trees confirm that Heteronema is excessively heterogeneous; therefore we establish new genus Teloprocta for Heteronema scaphurum.     

A model for the morphogenesis of strip reduction patterns in phototrophic euglenids: evidence for heterochrony in pellicle evolution

We propose a general developmental model that explains the evolutionary origin, diversification, and inheritance of pellicle strip patterns in phototrophic euglenids. Dividing cells of Euglena gracilis, E. viridis, and Phacus similis were observed with scanning electron microscopy in order to study the morphogenesis of posterior whorls of strip reduction. We found evidence that constant whorl numbers are maintained through cell division because of organized strip growth before and during cytokinesis. Alternating nascent strips form a new whorl of strip reduction at each of the anterior and posterior ends of daughter cells. Strips that terminated to form posterior whorls in the mother cell change in length during the development of daughter cells. In the mother cells of E. gracilis, the strips forming whorls I and II grow to become whorls II and III, respectively, in the daughter cells; the strips forming whorl III in the mother cell lengthen and meet with other strips already present at the posterior tip of daughter cells. This process of whorl morphogenesis during asexual reproduction is consistent with known variation in pellicle strip patterns and suggests that heterochrony played a major role in the ultrastructural evolution of phototrophic euglenids.     

Fine structure of laboratory cultured Distigma proteus and cytochemical localization of acid phosphatase

The phylogenetic relationship and origin of the euglenoids are controversial at present. It is not clear which of the extant genera may be most primitive, although Distigma proteus has been suggested as an early progenitor by some researchers. Scanning (SEM) and transmission (TEM) electron microscopic data were obtained in an effort to clarify some of the major taxonomic characteristics of this organism. SEM analyses of cells fixed during euglenoid movement (metaboly) show that the spirally arranged pellicular strips in the expanded regions of the organism have a lower pitch than those in the more constricted regions. This finding reveals the mechanical basis for euglenoid contortional movements. Mitochondria observed by TEM contain discoidal cristae, but some mitochondria are particularly large (e.g., 1.5 μm) and contain concentrically arranged, multiply layered cristae located deeper within the matrix, as in Khawkinea sp. Acid phosphatase reaction product is located in the cisternae and peripheral saccules throughout the Golgi stack and is regularly observed in the cisternae of the ER located beneath the pellicular ridges. Vacuoles varying in size, containing acid phosphatase reaction product, occur particularly near the periphery of the cell including the region surrounding the flagellar pouch. Occasional deposits of the reaction product within what appear to be membranous extrusions occur at the outer surface of the cell and may be secreted from sub-pellicular organelles. © 1994 Wiley-Liss, Inc.     

Ultrastructure of the Fusion Area during Conjugation in the Suctorian Heliphrya erhardi (Rieder) Matthes*

SYNOPSIS. The suctorian Heliophrya erhardi (Rieder) Matthes is attached to the substrate by the flattened ventral side of the cell body. The dorsal is covered by a pellicle composed of 3 unit membranes. Below the pellicle is a 0.4–0.8-μm thick epiplasm composed of 6–8-nm thick fibrils. Microtubules form a network beneath the epiplasm. The epipalsm is penetrated by tube-like pellicular pits, which are lined by the cell membrane and end beneath the epiplasm in a saccule-like enlargement. During conjugation, 2 neighboring organisms form cytoplasmic processes which come into contact and fuse, thus forming a cytoplasmic bridge between the 2 cells. Around the bridge the pellicles of both organisms fuse, and the partners become united by a continuous common membrane system. Across the entire conjugation bridge the 2 fused epiplasms form a septum. Tube-like structures can be seen lying partly in the epiplasmic septum and partly in the adjacent cytoplasm. These structures are open at both ends and represent remnants of the pellicular pits. No trace of the original pellicular membranes can be found at the fusion area within the epiplasmic septum. The cytoplasm of the conjugation partners is separated only by the fused epiplasms forming the epiplasmic septum.     

Development of the pellicle and thecal plates following ecdysis in the dinoflagellateGlenodinium foliaceum

Summary The ultrastructure and development of the amphiesma of the dinoflagellateGlenodinium foliaceum was studied using conventional electron microscopy and immunocytochemistry. Ecdysis (shedding of the flagella, the outer two membranes of the cell, and the thecal plates) was induced by centrifugation. The cells were resuspended and the thickening of the pellicle and the development of the new thecal vesicles and plates was studied over a 9 h period. After ecdysis, the thin pellicle which underlay the thecal plates in the motile cells thickens to form a complex structure of four distinct layers: an outer layer of randomly oriented fibrils, a 50 nm layer of fibrils oriented perpendicular to the dense layer, the dense layer which has a trilaminate structure, and a wide inner homogeneous layer. The new thecal vesicles form in these pelliculate cells by the migration of electron translucent amphisomal vesicles over the layer of peripheral microtubules to a position directly under the plasmalemma. The thecal vesicles then flatten and elongate. A discontinuous pellicular layer appears within them. Subsequently, the thecal vesicles widen and are filled with a fibrillogranular substance overlying the pelliculate layer. The thecal plates form on top of this fibrillogranular material. By this time, most cells have escaped from the pellicle and are motile. At first, the outer thecal vesicle membrane is continuous with the inner thecal vesicle membrane at the sutures, but when this connection is broken, the dense pelliculate layers become continuous across the suture as does the inner thecal vesicle membrane. At ecdysis, this membrane becomes the new plasmalemma of the cell. Cells at each stage of pellicle thickening and thecal development were labelled with a polydonal antiserum raised against the 70 kDa epiplasmic protein ofEuglena acus. This antiserum labelled both the thecal plates of the motile cells and the inner homogeneous layer of the pellicle of ecdysed non-motile cells. No other amphiesmal structure was labelled, nor was any intracellular compartment.Abbreviations PBS phosphate-buffered saline - PIPES piperazine-N,N-bis[2-ethane sulfonic acid]     

The Fine Structure of Two Archigregarines, Selenidium fallax and Ditrypanocystis cirratuli

SYNOPSIS. In S. fallax and D. cirratuli the pellicle is thrown into longitudinal folds. The pellicle consists of 2 membranes, one 3-layered, the other 5-layered. Sub-pellicular fibrils, each about 23 mμ in diameter run along the pellicular folds. Pellicle and sub-pellicular fibrils together form the mechanism by which Selenidiids move. The undulating membranes of D. cirratuli are enlarged pellicular folds, the tips of which are packed with fibrils. The light ovoid patches seen in thin sections are sections through regions which contain a form of glycogen in the living animals. Typical mitochondria are absent. Objects described as lipochondria have a regular distribution at the bases of the grooves in the pellicle and are probably formed from the inner components of the pellicle.     

Khawkinea quartana, a Colorless Euglenoid Flagellate. I. Ultrastructure

Khawkinea quartana, a naturally occurring colorless homologue of Euglena, was examined with the electron microscope. The organism is biflagellate though only one of the 2 flagella emerges from the anterior reservoir. The pellicular strips covering the body of the organism are supported by microtubules which are continuous in part with microtubules bordering the reservoir. Additional rows of microtubules are found associated with the kinetosomes. An eyespot is located in the wall of the reservoir and, adjacent to it, the contractile vacuole. The nucleus, mitochondria, and Golgi complexes are similar to those described in other euglenoid flagellates. The food reserve is paramylon. The study supports the phylogenetic origin of Khawkinea from pigmented Euglena through the loss of chloroplasts.     

RESTING CYST FORMATION OF EUTREPTIELLA GYMNASTICA (EUGLENOPHYCEAE) IN THE NORTHERN COASTAL BALTIC SEA1

Resting cyst formation of Eutreptiella gymnastica Throndsen was observed during a mesocosm experiment, where nutrient enrichment had induced almost a unialgal bloom. Cells and resting cysts of E. gymnastica were examined in scanning (SEM) and transmission electron microscopy (TEM) and light microscopy. Mature cysts were spherical, with a smooth thick mucilaginous cover that appeared layered when observed with the TEM. Intermediate forms were spherical and lacking flagella and a mucilaginous cover; the euglenoid pellicular striation and canal opening were easily visible. The volume of these intermediate spherical cells and mature cysts was estimated to have increased threefold compared to flagellated cells and contained many paramylon grains. When the cells were grazed by zooplankton, the paramylon grains passed the gut intact and were packed into fecal pellets. Intact undigested paramylon grains were observed in SEM after the breaking up of the pellets.     

Comparative morphology of the euglenid pellicle. I. Patterns of strips and pores

In anticipation that improved knowledge of euglenid morphology will provide robust apomorphy-based definitions for clades, transmission and scanning electron microscopy were used to reveal novel morphological patterns associated with the euglenid pellicle. In some taxa, the number of pellicle strips around the cell periphery reduces as discrete whorls at the anterior and posterior ends of the cell. The number of whorls at either end varies between selected euglenid taxa but is invariant within a taxon. The pattern of strip reduction associated with these whorls is shown to have at least three evolutionarily linked states: exponential, pseudoexponential, and linear. Two general equations describe these states near the posterior end of euglenid cells. Exponential patterns of strip reduction near the anterior end are described by a third equation. In addition, several euglenid taxa were found to possess conspicuous pellicle pores. These pores are arranged in discrete rows that follow the articulation zones between adjacent strips. The number of strips between rows of pores varies between taxa and displays a series of consecutive character states that differ by a power of two. The patterns of pores may not only have phylogenetical and taxonomical value but may provide morphological markers for following strip maturation during cytoskeletal reproduction.     

Fine Structure of Hepatozoon mocassini (Apicomplexa,Eucoccidiorida) Gamonts and Modifications of the Infected Erythrocyte Plasmalemma1

Transmission electron microscopy and scanning electron microscopy were used to investigate the fine structure of Hepatozoon mocassini gamonts and modifications of the infected erythrocyte plasmalemma. Intraerythrocytic gamonts were contained within a parasitophorous vacuole. An electron-lucid space observed between the gamont pellicle and the membrane of the vacuole corresponded to the unstained space described in light microscopy studies. Gamonts possessed a conoid, polar ring, subpellicular microtubules, four pairs of rhoptries, micronemes, ovoid granules, mitochondria with tubular cristae, and a pellicle composed of three individual unit membranes. The conoid had an anterior diameter of 320 nm, a posterior diameter of 360 nm, and a length of 150 nm. In contrast to a report on Hepatozoon aegypti, no micropore or “canopy-like structure” was observed. The plasmalemma of infected erythrocytes exhibited two types of modifications: gross membrane deformations and knobs with an electron-dense central mass. These knobs are structurally distinct from previously described membrane excrescences.     

Light and Electron Microscopic Description of a Colorless Euglenoid,Serpenomonas costata n. g., n. sp.1

ABSTRACT. A new genus of rigid, colorless, phagotrophic euglenoid is described from a standing pond on a salt marsh. The cell body measures 21–25 μm long, is about 18 μm wide, has a slight dorso-ventral flattening, and is marked by distinct pellicular ridges. The organism, described as Serpenomonas costata, has two unequal, antapically inserted, heterodynamic flagella. The shorter flagellum is anteriorly directed during swimming and the longer one trails posteriorly. Cells move along the substrate with a creeping motion. The ingestion apparatus is composed of separate ribs extending the length of the cell and is incorporated into the ventral pellicular ridge. The apparatus is independent of the canal and reservoir and is not protrusible. The taxonomic affinities of Serpenomonas with other euglenoids are discussed.     

AMPHIESMAL ULTRASTRUCTURE OF DINOFLAGELLATES: A REEVALUATION OF PELLICLE FORMATION1

The ultrastructure of the amphiesma during pellicle formation was investigated in two species of Dinophyceae, Amphidinium rhynchocephalum Anissimowa and Heterocapsa niei (Loeblich) Morrill & Loeblich using thin sections. In both species the amphiesma consists of an outermost membrane (i.e. the plasma membrane) underlain by amphiesmal vesicles. In A. rhynchocephalum the latter appear empty whereas each amphiesmal vesicle in H. niei contains a thecal plate and a thin, amorphous layer (dark-staining layer) located between, the thecal plate and the inner amphiesmal vesicle membrane. When cells of both taxa are carefully fixed, amphiesmal vesicles are always separate entities (i.e. the sutures are undisrupted). During ecdysis the following amphiesmal components are shed: the plasma membrane, the outer amphiesmal vesicle membrane, and in H. niei the thecal plates. The inner membranes of the amphiesmal vesicles then fuse with each other and form a continuous membrane (termed pellicle membrane) that remains tightly oppressed to an underlying amorphous layer (pellicular layer). In A. rhynchocephalum the pellicular layer is already present in vegetative non-ecdysed cells, whereas in H. niei it forms during ecdysis beneath the pellicle membrane. During ecdysis in H. niei, material from the dark-staining layer precipitates on the outer surface of the pellicle membrane, where it forms a characteristic honeycomb pattern. The new observations are incorporated into a revised model of pellicle formation in dinoflagellates and contrasted with earlier proposals.     

Ultrastructure of Euglena anabaena var. minor (Euglenophyceae)

The freshwater green euglenoid Euglena anabaena var. minor has a pellicle with groove‐ridge articulation, a chloroplast with pyrenoids doubly sheathed by two paramylon caps, and a nucleus with permanently condensed chromosomes and nucleolus. The flagellar apparatus basically resembles that of Euglena. The dorsal root (DR) originates at the dorsal basal body of the emergent flagellum, while both the intermediate root (IR) and ventral root (VR) originate at the ventral basal body of the non‐emergent flagellum. The cytoplasmic pocket is associated with the ventral root/ reinforcing microtubular band. However, ultrastructural characterization of E. anabaena var. minor shows the pocket to consist of five to seven microtubules, and flagellar roots with microtubule configuration of 3–4–6 in the DR‐IR‐VR. The dorsal band microtubules pair at the reservoir‐canal transition level. The doublet microtubules are formed into triplets and doublets at the lower canal level and then make pellicular microtubules at the upper canal level.     

Observations on the fine structure of the pellicle pores ofEuglena granulata

Summary The structure or granules associated with the pellicle strips ofEuglena granulata (Klebs) Schmitz has been studied using light and electron microscopy. Two types of bodies can be distinguished in this association on the basis of their staining reactions, distribution, ultrastructure, and other characteristics. The first type, called pellicle pores, is distributed with regularity along certain pellicle strips; the pores are very uniform in size (about 300 m in diameter) and in content. They consist of an aperture and a compartment, the latter lined by the plasmalemma; in each compartment a dense, osmiophilic body and a series of tubules occur. The structure of the pellicle strips is modified at the points where the pellicle pores are present; the aperture extends to the cell surface in the groove between two pellicle strips. The second type of body, which undergoes vital staining with neutral red, is called a pellicle vacuole. These are variable in size (ca. 1 to 2 microns in diameter) and contain a variety of components including myelin figures, proliferated membranes, and sheets of electrondense material. The structure of these elements as well as their possible functional significance are discussed in some detail.