Reconstruction of the flagellar apparatus and microtubular cytoskeleton inPyramimonas gelidicola (Prasinophyceae,Chlorophyta)

Summary The absolute configuration of the flagellar apparatus inPyramimonas gelidicola McFadden et al. has been determined and shows identity withP. obovata, indicating that they are closely related. Comparison with the flagellar apparatus of quadriflagellate zoospores from the more advancedChlorophyceae suggest thatPyramimonas may be a primitive ancestral form. The microtubular cytoskeleton has been examined in detail and is shown to be unusual in that it does not attach to the flagellar apparatus. Cytoskeletal microtubules are nucleated individually, and this is interpreted as an adaptation to the methods of mitosis and scale deployment. In view of the primitive nature of these processes, it is proposed that this type of cytoskeletal organization may represent a less advanced condition than that of the flagellar root MTOCs (microtubule organizing centers) observed in theChlorophyceae.     

The flagellar root system of zoospores of the green algaChlorosarcinopsis (Chlorosarcinales) as compared withChlamydomonas (Volvocales)

The flagellar root system of zoospores in two species ofChlorosarcinopsis (C. minuta andC. spec.) has been studied in detail. The biflagellate zoospores show a cruciate root system, two of the four microtubular roots containing two microtubules, the other two four microtubules. The flagellar apparatus is otherwise identical with that ofChlamydomonas reinhardi as described byRingo (1967). Evidence is presented that the genusChlamydomonas is characterized by a bilateral symmetric root system (4-2-4-2) rather than a system with four equally numbered roots (i.e. 4-4-4-4). It is suggested that a root system with four identical cruciate roots is not present in any biflagellate algal cell. The taxonomic significance of cruciate root systems in green algae is discussed refering to the identical root systems ofChlorosarcinopsis andChlamydomonas.     

The structure of the flagellar apparatus of the swarm cells ofPhysarum polycephalum

Summary Flagellation ofPhysarum polycephalum amoebae (Myxomycete) involves the formation around the two kinetosomes of a flagellar apparatus leading to a modification in the shape of the amoeba and its nucleus. A tridimensional ultrastructural model of the flagellar apparatus is proposed, based upon observation of the isolated nucleo-flagellar apparatus complex. The flagellar apparatus is composed of a non-microtubular structure (the posterior para-kinetosomal structure), five microtubular arrays and two flagella: a long anterior flagellum and a short flagellum directed backwards. The asymmetry of the flagellar apparatus is due mainly to the presence of the posterior para-kinetosomal structure on the right side of the posterior kinetosome and of the two asymmetrical microtubular arrays 3 and 4. Thus, the flagellar apparatus is right-handed. This asymmetry implies also some spatial constraints on two other microtubular arrays (2 and 5). Except in the case of the microtubular array 1 which links the proximal end of the anterior kinetosome to the nuclear membrane, the number of microtubules of each microtubular array seems to be well defined: 39, 5–6, 7–9, and 2+2 for the microtubular arrays 2, 3, 4, and 5 respectively. All the elements of the nucleo-flagellar apparatus complex are linked either directly or indirectly through bridges. Furthermore, the microtubules which composed the microtubular array 3 are linked through bridges while the microtubules of the microtubular arrays 2, 3, and 4 seem to be linked through a reticulate material. All these spatial relationships lead to a great cohesion of the nucleo-flagellar apparatus complex which appears to be a well defined structure. This suggests thatPhysarum amoebal flagellation can be a promising system to study the morphogenesis of an eucaryotic cell.Abbreviations PIPES Piperazine-N,N-bis [2-ethane-sulfonic acid] - EGTA [Ethylenebis(oxyethylenenitrile)]tetraacetic acid - DMSO Dimethyl sulfoxide     

A prominent microtubule cytoskeleton in Acanthamoeba

A method for preparing by detergent extraction the cytoskeletons of substrate-attached, motile Acanthamoeba castellanii is described. A monoclonal antibody to yeast alpha tubulin has been used to demonstrate the presence of abundant microtubules in the cytoskeleton of this amoeba by fluorescence and whole-mount electron microscopy. Individual microtubules, often more than 10 micron long, interweave to form a well-developed 3-D network pervading the cytoplasm and embracing the nucleus. In some cases immunofluorescent staining reveals distinct nodes in the perinuclear region of this microtubular network.     

Cytoskeletal Association Is Important for Differential Targeting of Glucose Transporter Isoforms in Leishmania

The major glucose transporter of the parasitic protozoan Leishmania enriettii exists in two isoforms, one of which (iso-1) localizes to the flagellar membrane, while the other (iso-2) localizes to the plasma membrane of the cell body, the pellicular membrane. These two isoforms differ only in their cytosolic NH₂-terminal domains. Using immunoblots and immunofluorescence microscopy of detergent-extracted cytoskeletons, we have demonstrated that iso-2 associates with the microtubular cytoskeleton that underlies the cell body membrane, whereas the flagellar membrane isoform iso-1 does not associate with the cytoskeleton. Deletion mutants that remove the first 25 or more amino acids from iso-1 are retargeted from the flagellum to the pellicular membrane, suggesting that these deletions remove a signal required for flagellar targeting. Unlike the full-length iso-1 protein, these deletion mutants associate with the cytoskeleton. Our results suggest that cytoskeletal binding serves as an anchor to localize the iso-2 transporter within the pellicular membrane, and that the flagellar targeting signal of iso-1 diverts this transporter into the flagellar membrane and away from the pellicular microtubules.     

The microtubular cytoskeleton of three dinoflagellates: an immunofluorescence study

Summary The sub-thecal microtubular cytoskeleton of the dinoflagellatesAmphidinium rhynchocephalum, Gymnodinium sanguineum, andGymnodinium. sp has been investigated by indirect immunofluorescence microscopy. In these cells, the majority of cytoskeletal microtubules lie in the anterior-posterior plane. These longitudinal microtubules clearly originate from one of two radially arranged microtubular bands that correspond in location with the anterior and posterior edge of the cingolar depression. Despite the morphological variability of these gymnodinioid dinoflagellates, our data indicate that the microtubular cytoskeleton perfectly reflects the spatial patterning of the epicone and hypocone in each cell.Abbreviations ALB Anterior longitudinal microtubular bundles - ATB Anterior transverse microtubular bands - C cingulum - CLB Cingular longitudinal microtubular bundles - E Epicone - H Hypocone - PLB Posterior longitudinal microtubular bundles - PTB Posterior transverse microtubular bands - S Sulcus     

Cytoskeletal changes visualized by fluorescence microscopy during amoeba-to-flagellate and flagellate-to-amoeba transformations inPhysarum polycephalum

Summary Changes in the intracellular distribution of microtubules and microfilaments during amoeba-to-flagellate and flagellate-to-amoeba transformations inPhysarum polycephalum were examined by fluorescence microscopy using anti-tubulin antibody and NBD-phallacidin, respectively. Amoebae contained an extensive microtubular cytoskeleton, which was converted to a flagellar cone structure during transformation to flagellates in liquid medium. When flagellates reverted back to amoebae, this conical structure disintegrated prior to flagella resorption. Amoebae showed some microfilament-enriched domains along the periphery, from which numerous filamentous extrusions, probably pseudopods and filopods, emanated. Flagellates contained a ridge, a sheet-like structure, along their dorsal axis, especially in the earlier stages of flagellation. Another microfilament-enriched thick filamentous structure ran along the dorsal axis, starting from the anterior tip of the cell. This structure apparently coincided spatially with one of the bundles of microtubules. During the reversion to amoebae, other localized microfilaments were transiently observed at the posterior end. A model of cytoskeletal changes in the transformations between these two cell types was proposed.     

IMMUNOLOCALIZATION OF CENTRIN IN OXYRRHIS MARINA (DINOPHYCEAE)1

A new polyclonal antibody was raised against centrin isolated from the flagellate green alga Spermatozopsis similis (Chlorophyta; anti-SSC). It stains by immunofluorescence and immunoelectron microscopy well-known reference systems for centrin like the nucleus–basal body connectors in Chlamydomonas reinhardtii (Chlorophyta) and the system II fibers (rhizoplasts) of Scherffelia dubia (Chlorophyta). In addition, it recognizes in immunoblots a single 20-kDa protein in isolated cytoskeletons of Spermatozopsis similis and Tetraselmis striata (Chlorophyta) as well as purified centrin isolated from Tetraselmis striata. Using this antibody, centrin was localized in whole cells and isolated cytoskeletons of Oxyrrhis marina Dujardin (Dinophyceae) by immunofluorescence and immunogold electron microscopy. In the flagellar apparatus of O. marina, five different structures were antigenic. Four short fibers (connectives 1–4) link the basal bodies to the four major fibrous flagellar roots, which do not cross-react with anti-centrin. The most prominent of the labeled structures (connective 5), a crescent-shaped fiber, extends from the flagellar canal of the transverse flagellum along the base of the tentacle to the flagellar canal of the longitudinal flagellum, interconnecting the distal parts of the microtubular roots/bands in the basal apparatus. For most of its length, it underlies and is connected to a transversely oriented subamphiesmal microtubular band. In immunoblot analyses, anti-SSC recognizes only a single 20-kDa protein in cytoskeletons of O. marina. Functional and phylogenetic aspects of centrin-containing structures in dinoflagellates are discussed.     

Microtubules and the flagellar apparatus in zoospores and cysts of the fungusPhytophthora cinnamomi

Summary A correlated immunofluorescence and ultrastructural study of the microtubular cytoskeleton has been made in zoospores and young cysts ofPhytophthora cinnamomi. Labelling of microtubules using antibodies directed towards tubulin has revealed new details of the arrangement of the flagellar rootlets in these cells, and of the variability that occurs from cell to cell. Most of the variation exists at the distal ends of the rootlets, and may be correlated with differences in cell shape in these regions. The rootlets have the same right and left configuration in all zoospores. The arrangement of the rootlet microtubules at the anterior end of the zoospores raises the possibility that the microtubules on the left hand side of the groove may not comprise an independent rootlet which arises at the basal bodies.The absolute configuration of the flagellar apparatus has been determined from ultrastructural observations of serial sections. In the vicinity of the basal bodies, there is little, if any, variation between individuals, and the structure of the flagellar apparatus is similar to that described for related species of fungi. Two ribbon-like coils surround the central pair of microtubules at the distal tip of the whiplash flagellum, and clusters of intramembranous particles, similar to ciliary plaques, have been found at the bases of both flagella. There are two arrays of microtubules associated with the nucleus in the zoospores. One array lies next to the outer surface of the nuclear envelope, and probably functions in the shaping and positioning of the apex of the nucleus. The nuclear pores in this region are aligned in rows alongside these microtubules. The second array is formed by kinetochore microtubules which extend into a collar-like arrangement of chromatin material around the narrow end of the (interphase) nucleus. During encystment, all flagellar rootlets are internalized when the flagella are detached at the terminal plate. The rootlets arrays are no longer recognizable 5–10 minutes after the commencement of encystment.     

THE FLAGELLAR APPARATUS OF OXYRRHIS MARINA (PYRROPHYTA)1

The three-dimensional structure of the flagellar apparatus in the dinoflagellate Oxyrrhis marina has been reinvestigated and found to consist of several previously unknown components and component combinations that appear strikingly similar to those of some gymnodinoid taxa. The flagellar apparatus of this dinoflagellate is asymmetric and extremely complex consisting of a longitudinal and a transverse basal body that gives rise to eight structurally different components. The only posteriorly directed component is the large microtubular root that consists of 45–50 microtubules at its origin and is attached proximally to a perpendicularly oriented striated fibrous component. Arising from each basal body, two striated fibrous roots with different periodicities extend to the cell's left. A single stranded microtubular root with associated electron dense material emanates from the transverse basal body and also extends to the cell's left. A striated fibrous connective arises from the longitudinal basal body and extends toward the cell's right ventral surface and terminates near the sub-thecal microtubular system. A compound root consisting of microtubules and electron dense material also originates from the longitudinal basal body and extends ventrally into the anterior region of the tentacle. Structural similarities between the parallel striated fibrous roots of Oxyrrhis and Polykrikos are discussed as are flagellar apparatus similarities among other gymnodinoid dinoflagellates. A diagrammatic reconstruction of the Oxyrrhis flagellar apparatus is also presented.     

The architecture of the flagellar apparatus ofPrymnesium patellifera (Prymnesiophyta)

The flagellar apparatus of the small prymnesiophytePrymnesium patellifera has been analysed and a reconstruction is presented. Externally, the cell carries two sub-equal flagella and a short non-coiling haptonema. Within the cell, there are four microtubular roots and a number of fibrous bands, the latter interconnecting the two basal bodies and the haptonema base. One of the roots (r1) consists of a sheet of up to 25 microtubules originating close to the proximal extremity of the haptonema base, but the other three roots are composed of between 1 and 4 microtubules only. Distally, a large striated fibrous auxiliary connecting root extends across the anterior part of the cell linking root r1 and a mitochondrial profile on the opposite side of the cell. The arrangement of the components of the flagellar apparatus ofP. patellifera is commensurate with the general pattern found in many prymnesiophytes other than members of the Pavlovales, but there are a number of differences in detail from the other species described hitherto.     

COMPARATIVE ANALYSES OF THE DINOFLAGELLATE FLAGELLAR APPARATUS. III. FREEZE SUBSTITUTION OF AMPHIDINIUM RHYNCHOCEPHALUM1

The flagellar apparatus of the marine dinoflagellate Amphidinium rhynchocephalum Anissimowa was examined using the techniques of rapid freezing/freeze substitution and serial thin section three dimensional reconstruction. The flagellar apparatus is composed of two basal bodies that are offset from one another and lie at an angle of approximately 150° The transverse basal body is associated with two individual microtubules that extend from the proximal end of the basal body toward the flagellar opening. One of these microtubules is closely appressed to a striated fibrous root that also extends from the proximal base of the transverse basal body. The longitudinal basal body is associated with a nine member microtubular root that extends from the proximal end of the basal body toward the posterior of the cell. The longitudinal microtubular root and the transverse striated fiber are connected by a striated connective fiber. In addition to the microtubules associated with the transverse and longitudinal basal bodies, a group of microtubules originates adjacent to one of the transverse flagellar roots and extends into the cytoplasm. Vesicular channels extend from the flagellar openings to the region of the basal bodies where they expand to encompass the various connective structures of the flagellar apparatus. The possible function and evolutionary importance of these structures is discussed.     

The flagellar apparatus and striated rhizoplast of the zoospore ofOlpidium brassicae

Summary The flagellar apparatus and its associated structures of the zoospore ofOlpidium brassicae are described and compared with observations of other zoospores of the uniflagellatePhycomycetes. The zoospore ofO. brassicae is shown to have an extensive cone-shaped rhizoplast fused to both the functional and the vestigial kinetosomes. Three-dimensional reconstructions were made of the kinetosomal region. The vestigial kinetosome differs from the functional, as it only has triplet bundles of microtubules and it lacks a system of props. The proximal termination of the central pair of flagellar microtubules occurs within the axoneme. No terminal plate is observed. The occurrence of dictyosomes in theChytridiales, Monoblepharidales, andHyphochytriales is discussed and it is concluded that a dictyosome may be present in the encysting zoospore and the maturing zoosporangium ofO. brassicae but only vestiges of a dictyosome are to be found in the free-swimming zoospore.     

The flagellar root system in the gamete ofAcetabularia mediterranea

Summary Ultrastructural investigation of the flagellar root system ofAcetabularia gametes reveals one type of organization for both male and female gametes. There is a modified cruciate system with four microtubular bands X-2-X-2, with X=4. A prominent distal striated fiber and a small proximal striated fiber connect the flagellar bases. A striated root fiber type I underlies the microtubular root type II, and a short striated root fiber type I underlies the microtubular root type I (terminology ofMelkonian 1980 b). This specific root system has some details in common with theChlamydomonas type, and others with theUlvaphyceae and the siphonalean algaeDerbesia andBryopsis. This might indicate the phylogenetic relationships.     

STRUCTURE AND SIGNIFICANCE OF THE CRYPTOMONAD FLAGELLAR APPARATUS. I. CRYPTOMONAS OVATA (CRYPTOPHYTA)1

The absolute configuration of the flagellar apparatus in Cryptomonas ovata has been elucidated and found to be similar to that reported for Chilomonas paramecium. Variations apparent in the flagellar apparatus of Cryptomonas ovata include the presence of striations in the mitochondrion associated lamella, a rhizostyle which does not bear wing-like extensions from the microtubules and does not lie close to the nucleus, and a striated fibrous anchoring structure associated with one basal body which has not hitherto been described. The flagellar apparatus also includes a four stranded microtubular root which traverses into the anterior dorsal lobe of the cell, a striated fibrous root which is associated with a five stranded microtubular root, and a two stranded Cr root. The homologous nature of these roots to those in the larger cryptomonads is discussed in relation to the apparent reduction in flagellar apparatus size and complexity among the smaller cryptomonads. A diagrammatic reconstruction of the flagellar apparatus of Cryptomonas ovata is also presented.     

Ultrastructure of the flagellar apparatus inPleurochrysis (classPrymnesiophyceae)

Summary The ultrastructure of the flagellar apparatus of aPleurochrysis, a coccolithophorid was studied in detail. Three major fibrous connecting bands and several accessory fibrous bands link the basal bodies, haptonema and microtubular flagellar roots. The asymmetrical flagellar root system is composed of three different microtubular roots (referred to here as roots 1,2, and 3) and a fibrous root. Root 1, associated with one of the basal bodies, is of the compound type, constructed of two sets of microtubules,viz. a broad sheet consisting of up to twenty closely aligned microtubules, and a secondary bundle made up of 100–200 microtubules which arises at right angles to the former. A thin electron-dense plate occurs on the surface of the microtubular sheet opposite the secondary bundle. The fibrous root arises from the same basal body and passes along the plasmalemma together with the microtubular sheet of root 1. Root 2 is also of the compound type and arises from one of the major connecting bands (called a distal band) as a four-stranded microtubular root and extends in the opposite direction to the haptonema. From this stranded root a secondary bundle of microtubules arises at approximately right angle. Root 3 is a more simple type, composed of at least six microtubules which are associated with the basal body. The flagellar transition region was found to be unusual for the classPrymnesiophyceae. The phylogenetic significance of the flagellar apparatus in thePrymnesiophyceae is discussed.     

The intranuclear microtubule organizing centre in the plasmodium of the myxomycete Physarum polycephalum

Physarum possesses two different microtubule cytoskeletons. In amoebae, cytoplasmic and mitotic microtubules are nucleated by a typical centrosome. In contrast, it has been reported that plasmodia have an intranuclear spindle organizing centre (SPOC) devoid of centrioles. We present genetic evidence suggesting that the SPOC located in the centrosome is very similar to the intranuclear plasmodial SPOC. The immunostaining properties of a new monoclonal antibody against Physarum centrosome has been used to compare these different MTOCs. Moreover, a dense plasmodial microtubule network was present in interphase plasmodia and absent in plasmodia undergoing mitosis. MTOCs responsible for the nucleation of the cytoplasmic microtubule network and intranuclear SPOCs were located in two different compartments of the plasmodium.     

Analysis of cytoplasmic microtubules and flagellar roots in the zoospores ofAllomyces macrogynus

Summary Cytoskeletal and flagellar microtubules in the zoospores of the aquatic fungusAllomyces macrogynus are resistant to microtubule depolymerizing drugs. Consequently, we have analyzed the partial composition and organization of microtubules (Mts) in the cytoplasm and flagellar apparatus in the zoospores ofA. macrogynus. Evidence from two-dimensional gel electrophoresis demonstrated the presence of two -tubulin isoforms in axonemal and cytoplasmic Mts. In addition, a monoclonal antibody specific for acetylated -tubulin was used on one-dimensional protein blots to show that acetylated -tubulins are present in isolated zoospore cell bodies and axonemes. Immunofluorescence microscopy observations using this monoclonal antibody demonstrated that flagellar, kinetosomal, and cytoplasmic Mts were labeled. The nature of Mts in the flagellar apparatus was studied ultrastructurally. InA. macrogynus, the flagellar apparatus consists of the kinetosome, rhizopolast (striated flagellar rootlet), axoneme, and 9 sets of triplet Mts which radiate anteriorly from the proximal end of the kinetosome (microtubular rootlet), Analysis of the rhizoplast indicated that this structure does not contain Mts. The rhizoplast, which connects the functional kinetosome with a single, large basal mitochrondrion, consists of four electron-opaque bands. Serial-sectioning indicated that the rhizoplast is always adjacent to kinetosome triplets 1, 2, and 9, and thus lies perpendicular to the plane of flagellar beat. These results suggest that the primary function of the rhizoplast is to organize the kinetosome and mitochondrion with respect to one another and to bias flagellar beat in the appropriate orientation for cell motility.Abbreviations BSA bovine serum albumin - BCA bicinchoninic acid - DS dilute salts - EGTA ethylene glycol-bis-(-aminoethyl ether)-N,N-tetracetic acid - EM electron microscopy - Mes 2-(N-morpholinomethane sulfonic acid - Mt microtubule - NP-40 Nonidet P-40 - 1-D PAGE one-dimensional polyacrylamide gel electrophoresis - PBS phosphate-buffered saline - PMSF phenylmethylsulfonyl fluoride - SDS sodium dodecyl sulfate - 2-D PAGE two-dimensional polyacrylamide gel electrophoresis - Tween-20 polyoxyethylenesorbitan monolaurate     

The amoebae of Idionectes vortex (Cutosea,Amoebozoa): Motility,cytoskeleton architecture and extracellular scales

The Cutosea represent a deep-branching lineage within the phylum Amoebozoa that is still relatively poorly explored. Currently, there are four cutosean representatives known – the monotypic genera Armaparvus, Idionectes, Sapocribrum, and Squamamoeba – with marked genetic distances. Idionectes vortex is the deepest-branching species and differs markedly from the other Cutosea in ecology, life history, and most importantly, in its ability to form a flagellated swarmer with an exceptional swimming mechanism. As far as we know, the other Cutosea lack flagella and rather represent small, marine amoebae with a characteristic cell coat. The present paper focuses on the amoeboid life history stage of the algivorous amoeboflagellate Idionectes vortex to provide data for a first in-depth comparison with other Cutosea and to document structural specialties. The amoeboid stage of Idionectes is mainly associated with the specific feeding process, that is, the interaction with algal prey cells and phagocytosis of protoplast material. Yet, the present data from time-lapse microscopy, cytochemical stainings, and electron microscopy demonstrate clear similarities with the other cutosean species concerning amoeboid locomotion and cell coat ultrastructure. Furthermore, Idionectes amoebae exhibit a well-developed microtubular cytoskeleton, and an unusual basal apparatus that seems to undergo marked changes during the life history of this exceptional amoebozoan.     

The 3D Structure of the Apical Complex and Association with the Flagellar Apparatus Revealed by Serial TEM Tomography in Psammosa pacifica,a Distant Relative of the Apicomplexa

The apical complex is one of the defining features of apicomplexan parasites, including the malaria parasite Plasmodium, where it mediates host penetration and invasion. The apical complex is also known in a few related lineages, including several non-parasitic heterotrophs, where it mediates feeding behaviour. The origin of the apical complex is unclear, and one reason for this is that in apicomplexans it exists in only part of the life cycle, and never simultaneously with other major cytoskeletal structures like flagella and basal bodies. Here, we used conventional TEM and serial TEM tomography to reconstruct the three dimensional structure of the apical complex in Psammosa pacifica, a predatory relative of apicomplexans and dinoflagellates that retains the archetype apical complex and the flagellar apparatus simultaneously. The P. pacifica apical complex is associated with the gullet and consists of the pseudoconoid, micronemes, and electron dense vesicles. The pseudoconoid is a convex sheet consisting of eight short microtubules, plus a band made up of microtubules that originate from the flagellar apparatus. The flagellar apparatus consists of three microtubular roots. One of the microtubular roots attached to the posterior basal body is connected to bypassing microtubular strands, which are themselves connected to the extension of the pseudoconoid. These complex connections where the apical complex is an extension of the flagellar apparatus, reflect the ancestral state of both, dating back to the common ancestor of apicaomplexans and dinoflagellates.