Synthesis and assembly of flagellar surface antigens during zoosporogenesis inPhytophthora cinnamomi

Summary Cryomicrotomy and immunofluorescence microscopy employing three different categories of monoclonal antibody (MAb) that label antigens on the surface of one or both flagella ofPhytophthora dnnamomi have been used to follow the synthesis and assembly of flagellar surface components. MAb Zf 1 binds to the surface of both the anterior tinsel and posterior whiplash flagella, as well as to a nuclear component. The labeling of the flagella is punctate in nature, is brighter at the flagellar base, and does not always extend to the distal tip of the flagella. MAbs in the Zt group recognise an antigen that is located along the sides of the tinsel flagellum and may be associated with the base of the mastigonemes. Immunodot-blot analysis has shown that binding of Zt MAbs is abolished by pretreatment with either pronase or periodate oxidation indicating that the antigen is a glycoprotein. MAbs in the Zg group bind to the mastigonemes on the tinsel flagellum and to packets of mastigonemes in the cytoplasm of zoospores. Zt and Zg antigens increase in abundance during zoosporogenesis and are present throughout the life cycle of the fungus, whereas the non-nuclear localisation of the Zf antigen appears only during sporulation. Prior to association with the flagellar surface, all three components become clustered in the groove region of zoospores. They do not become associated with the flagellar surface until at least 15 min after the flagellar axoneme has formed.Abbreviations BSA bovine serum albumin - DAPI 4,6-diamidino-2-phenylindole - DMF dimethylformamide - lgG₁ immunoglobulin G₁ - MAbs monoclonal antibodies - NIM non-immune mouse antibodies - PBS phosphate-buffered saline - PBST phosphate-buffered saline with 0.5% Tween 20 - PIPES 1,4-piperazinediethanesulfonic acid - PPD paraphenylenediamine dihydrochloride - RT room temperature - TBS tris-buffered saline - TEST tris-buffered saline with 0.05% Tween 20     

Centrin association with the flagellar apparatus in spores ofPhytophthora cinnamomi

Summary Antibodies raised against the calcium-binding protein centrin, were used to identify and localise centrin containing structures in the flagellar apparatus of zoospores and cysts of the oomycetePhytophthora cinnamomi. Immunoblotting of extracts from zoospores indicates that theP. cinnamomi centrin homologue is a 20 kDa protein. Immunofluorescence microscopy with anti-centrin antibodies reveals labelling in the flagella, the basal body connector and co-localisation along the microtubular R1 root (formerly called AR3) that runs from the right side of the basal body of the anterior flagellum into the anterior of the zoospore close to the ventral surface. The centrin (R1^cen) and tubulin components of the R1 root split into four loops on the right hand side of the ventral groove and rejoin along the left hand side of the groove. The R1 root continues down the left hand side of the zoospore past the basal bodies and parallel to the R4 root. We propose that at least inP. cinnamomi there is no R2 root. Immunogold labelling confirms that centrin is a component of the basal body connector complex. When the zoospores become spherical during encystment, the R1^cen pivots by approximately 90 ° with respect to the nucleus.     

Localization of calmodulin in flagella of zoospores ofPhytophthora cinnamomi

Summary Calmodulin distribution in the tinsel and whiplash flagella of zoospores ofPhytophthora cinnamomi has been studied by immunofluorescence microscopy and immunogold labelling. In whole zoospores labelled with a monoclonal antibody raised against pea calmodulin, followed by a second antibody-FITC, both flagella appear to be weakly stained except for a region at the base of the tinsel flagellum which was stained intensely. A similar staining pattern was also detected in isolated flagella labelled with anti-calmodulin. To identify the calmodulin rich region of the tinsel flagellum, we labelled sections of zoospores embedded in Lowicryl K4M with anti-calmodulin followed by a second antibody gold probe. In the tinsel flagellum, the gold labelling was restricted to a paraxonemal swelling close to the base. Very little gold labelling was detected elsewhere. The swelling extends for 1.5–2.0 n from the base of the tinsel flagellum and is hook shaped in cross section. Immunoblot analysis confirmed that the staining was specific for calmodulin.     

Characterising adhesiveness ofPhytophthora cinnamomi zoospores during encystment

During encystment,Phytophthora cinnamomi zoospores bind firmly to the host surface. We have developed a microassay to study adhesion of the zoospores to solid surfaces, both biological and non-biological. The results show that timing of the acquisition of adhesiveness during encystment correlates closely with the secretion of high molecular weight glycoproteins. The adhesive phase is short lived, occurring between 1 and 4 min after induction of encystment. During this period, cells that come into contact with a variety of surfaces (glass, plastic, and onion epidermis) become firmly attached, while cells that come into contact with one of these substrata after this period are unable to bind. Our results also show that EGTA inhibits cyst adhesion, while addition of calcium promotes cyst adhesion, especially of cysts more than 4 min old. To help identify the cyst surface component involved in adhesion we tested a number of lectins for their ability to block cyst adhesion. Soybean agglutinin andHelix pomatia agglutinin, lectins which bind to the secreted high molecular weight glycoproteins, both inhibit adhesion in the presence and absence of the hapten sugar, indicating that inhibition was non-specific. Wheatgerm agglutinin, a lectin which does not bind to the cyst surface, also blocked adhesion non-specifically.     

Encystment of zoospores of the fungus,Phytophthora cinnamomi,is induced by specific lectin and monoclonal antibody binding to the cell surface

Summary Only two of a number of macromolecules that bind to the surface of zoospores of the dieback fungus,Phytophthora cinnamomi, induce encystment when added to a suspension of actively swimming zoospores. One, the lectin Concanavalin A (ConA), binds to the entire surface of the zoospores including the surface of both flagella. Within 10 minutes more than 70% of the cells have encysted in the presence of 5 g/ml ConA. This encystment is inhibited by preincubation of the lectin with its hapten sugar, -methyl-D-mannoside. The other effective molecule, a monoclonal antibody designated Zf-1, is one of 35 that have been raised to components on the surface of zoospores and cysts ofP. cinnamomi. The antigen for Zf-1 occurs only on the surface of the two flagella. Purified Zf-1 at 15 g/ml causes encystment of 75% of the zoospores in 13minutes. To show that the induction of encystment by these two probes is not due simply to the presence of protein either in solution or bound to the zoospore a number of other proteins were tested, including other antibodies that bind to the zoospore surface. None of these other molecules caused encystment even at concentrations greater than 200 g/ml. The results are consistent with the surface components that bind ConA and Zf-1 being involved in the critical step of triggering encystment at the surface of a potential host during infection.     

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 absolute configuration of the flagellar apparatus in zoospores from two species ofLaminariales (Phaeophyceae

Summary We examined the zoospores produced by the unilocular sporangia ofLaminaria digitata (L.) Lamour. andNereocystis luetkeana Post. & Rupr. by serial sectioning to determine the absolute configuration of their flagellar apparatuses. The basal bodies, which are interconnected by three striated bands, lie parallel to the ventral face of the zoospore, and the posterior basal body always is found to the right of the anterior basal body when the cell is viewed from the ventral face, anterior end up. The four rootlets associated with the basal bodies include a major anterior rootlet of about seven microtubules extending from the anterior basal body along the ventral face towards the apex, a five-membered bypassing rootlet that passes ventral to the basal bodies and is connected to the posterior basal body by a posterior fibrous band, and two short rootlets having a single member each, the minor anterior and posterior rootlets. We consider the configuration observed here to be typical of most phaeophycean motile cells. The flagellar apparatus features suggest a considerable phylogenetic difference between thePhaeophyceae and other classes of chlorophyll c-containing organisms.     

Transformation and development of the flagellar apparatus ofCryptomonas ovata (Cryptophyceae) during cell division

Summary InCryptomonas ovata, long, dorsal flagella are produced which transform during the following cell division into short, ventral flagella. At division there is a reorientation in cell polarity, and the parental basal apparatus, which comprises the basal bodies and associated roots, is distributed to the daughter cells via a complex sequence of events. Flagellar apparatus development includes the transformation of a four-stranded microtubular root into a mature root of different structure and function. Each newly formed basal body nucleates new microtubular roots, but receives a striated fibrous root from a parental basal body. The striated roots are originally produced on the transforming basal body and are transferred to the new basal bodies at each successive division. The development of the asymmetric flagellar apparatus throughout the cell cycle is described.     

The Golgi apparatus ofPhytophthora cinnamomi makes three types of secretory or storage vesicles concurrently

Summary The formation of three types of vesicles in the oomycetePhytophthora cinnamomi was investigated using ultrastructural and immunocytochemical techniques. All three vesicles are synthesised at the same time; one type serves a storage role; the others undergo regulated secretion. A monoclonal antibody Lpv-1 that is specific for glycoproteins contained in the storage vesicles labelled the endoplasmic reticulum (ER), elements in the transition region between ER and Golgi stack, and cis, medial and trans Golgi cisternae. Cpa2, a monoclonal antibody specific for glycoproteins contained within secretory dorsal vesicles labelled the transition region, cis cisternae and a trans-Golgi network. Vesicles possessing a structure characteristic of mature secretory ventral vesicles were observed in close association with the trans face of Golgi stacks. The results suggest that all three vesicles are formed by the Golgi apparatus. Double immunogold labelling with Lpv-1 and Cpa-2 showed that these two sets of glycoproteins occurred within the same Golgi cisternae, indicating that both products pass through and are sorted concurrently within a single Golgi stack.     

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.     

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.     

Vischeria stellata (Eustigmatophyceae): ultrastructure of the zoospores,with special reference to the flagellar apparatus

Summary Ultrastructure of the zoospores ofVischeria stellata (R. Chodat ex Poulton) Pascher is investigated, with particular reference to the system of flagellar roots. Microtubular roots and a rhizoplast are present and a model showing their distribution is proposed. Four microtubular roots attach to the basal bodies in a system basically similar to that displayed by the heterokont algae and fungi. The rhizoplast is also similar to that of other heterokont algae. We conclude from these observations that the class Eustigmatophyceae should be placed within the division Heterokontophyta.Abbreviations C chloroplast - B basal body of the emergent flagellum - B' second basal body - E eyespot - F emergent flagellum - FS flagellar swelling - LV lamellate vesicle - M mastigonemes - MTs microtubules - N nucleus - R 1–R 4 microtubular roots - Rh rhizoplast - SB striated band - SV spiral vesicle     

Phytophthora cinnamomi in Shanghai and its possible origin

Camellia leaves were most effective for recoveringPhytophthora cinnamomi from soils followed by azalea leaves and cedar needles. A total of 131 isolates ofP. cinnamomi was obtained from soils and roots collected in Shanghai. Among them 125 were A¹ and 6 were A² type. There was little variation in morphological and physiological characteristics among 82 isolates tested. It is suggested that the fungus may have been a recent settler in Shanghai.     

The flagellar apparatus and cytoskeleton of the dinoflagellates

Summary Modern microscopical approaches have allowed more accurate investigations of the three-dimensional nature of the dinoflagellate flagellar apparatus (FA) and several other cytoskeletal protein complexes. Our presentation overviews the nature of the dinoflagellate FA and cytoskeleton in a number of taxa and compares them with those of other protists. As with other protists, the FA of the dinoflagellates can be characterized by the presence of fibrous and microtubular components. Our studies and others indicate that the dinoflagellate FA can be expected to possess a striated fibrous root on the basal body of the transverse flagellum and a multimembered microtubular root on the basal body of the longitudinal flagellum. Two other features that appear widespread in the group are the transverse striated root associated microtubule (tsrm) and the transverse microtubular root (tmr). The tsrm extends at least half the length of the transverse striated root while the tmr extends from the transverse basal body toward the exit aperture of the transverse flagellum. In most cases, the tmr gives rise to several cytoplasmic microtubules at a right angle. The apparent conserved nature of these roots leads us to the conclusion that the dinoflagellate FA can be compared to the FA of the cryptomonads, chrysophytes, and the ciliates for phylogenetic purposes. Of these groups, the chrysophytes possess an FA with the most structures in common with the dinoflagellates. Our immunomicroscopical investigations of the microtubular, actin and centrin components of the dinoflagellate cytoskeleton point to the comparative usefulness of these cytological features.Abbreviations aptb apical transverse microtubular band - FA flagellar apparatus - Imr longitudinal microtubular root - mls multilayered structure - tmr transverse microtubular root - tmre transverse microtubular root extension - tsr transverse striated fibrous root - tsrm transverse striated root associated microtubule     

An ultrastructural comparison of the mitotic apparatus,feeding apparatus,flagellar apparatus and cytoskeleton in euglenoids and kinetoplastids

Summary The euglenoids and kinetoplastids form a diverse assemblage of organisms which show no obvious phylogenetic relationship with other flagellates. An ultrastructural examination and comparison of the flagellar apparatus, the feeding apparatus, and mitotic nucleus indicate a number of shared morphological features which support a common ancestry for the two groups. Of particular interest is the euglenoid,Petalomonas cantuscygni, which shares many of the ultrastructural features common to both groups. Based on the data presented, we hypothesize that a euglenoid with features similar to those now present inP. cantuscygni was ancestral to both the euglenoid and kinetoplastid lines.Abbrevation MTR complex of reinforcing microtubules     

Transformation of the flagella and associated flagellar components during cell division in the coccolithophoridPleurochrysis carterae

Summary Immunofluorescence microscopy, conventional and high voltage transmission electron microscopy were used to describe changes in the flagellar apparatus during cell division in the motile, coccolithbearing cells ofPleurochrysis carterae (Braarud and Fagerlund) Christensen. New basal bodies appear alongside the parental basal bodies before mitosis and at prophase the large microtubular (crystalline) roots disassemble as their component microtubules migrate to the future spindle poles. By prometaphase the crystalline roots have disappeared; the flagellar axonemes shorten and the two pairs of basal bodies (each consisting of one parental and one daughter basal body) separate so that each pair is distal to a spindle pole. By late prometaphase the pairs of basal bodies bear diminutive flagellar roots for the future daughter cells. The long flagellum of each daughter cell is derived from the parental basal bodies; thus, the basal body that produces a short flagellum in the parent produces a long flagellum in the daughter cell. We conclude that each basal body in these cells is inherently identical but that a first generation basal body generates a short flagellum and in succeeding generations it produces a long flagellum. At metaphase a fibrous band connecting the basal bodies appears and the roots and basal bodies reorient to their interphase configuration. By telophase the crystalline roots have begun to reform and the rootlet microtubules have assumed their interphase appearance by early cytokinesis.Abbreviations CR1, CR2 crystalline roots 1 and 2 - CT cytoplasmic tongue microtubules - DIC differential interference contrast light microscopy - H haptonema - HVEM high voltage transmission electron microscopy - IMF immunofluorescence microscopy - L left flagellum/basal body - M metaphase plate - MT microtubule - N nucleus - R right flagellum/basal body - R1, R2, R3 roots 1, 2, and 3 - TEM transmission electron microscopy     

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.     

Microtubules,protoplasts and plant cell shape

Indirect immunofluorescence has been used to study the function of cytoplasmic microtubules in controlling the shape of elongated carrot cells in culture. Using a purified wall-degrading preparation, the elongated cells are converted to spherical protoplasts and the transverse hoops of bundled microtubules are disorganised but not depolymerised in the process. Since microtubules remain attached to fragments of protoplast membrane adhering to coverslips and are still seen to be organised laterally in bundles, it would appear that re-orientation of the transverse bundles is due to loss of cell wall and not to the cleavage of microtubule bridges. After 24 h treatment in 10^-3 M colchicine, microtubules are depolymerised in elongated cells but, at this time, the cells retain their elongated shape. This suggests that wall which was organised in the presence of transverse microtubule bundles can retain asymmetric shape for short periods in the absence of those tubules. However, after longer periods of time the cells become spherical in colchicine. Neither wall nor tubules therefore exert individual control on continued cellular elongation and so we emphasize the fundamental nature of wall/microtubule interactions in shape control. It is concluded that the observations are best explained by a model in which hooped bundles of microtubules—which are directly or indirectly associated with molecules involved with cellulose biosynthesis at the cell surface—act as an essential template or scaffolding for the orientated deposition of cellulose.     

Development of the flagellar apparatus during the cell cycle in unicellular algae

Summary Recent evidence has shown that algal cells acquire different flagella and a heterogeneous basal apparatus through the prolonged development of these structures over more than one cell cycle. A system for numbering algal flagella and basal bodies, which is based on developmental studies, is discussed along with the various means by which the flagellar/basal body developmental cycle can be determined. We review the information now available on development of the separate components of the flagellar apparatus-this comes particulary from the Chlorophyta and the Chromophyta-and attempt to elucidate any information which may help in phylogenetic comparisons. New data is provided on developmental changes in the cartwheel part of the basal body and basal body-associated connecting fibrils in green algae.Abbreviations Bb basal body - d right (dexter) root - df right fibrils connecting Bb triplets to microtubular and/or fibrous roots - EM electron microscopy - F flagellum - IMF immunofluorescence microscopy - LM light microscopy - NBBC nucleus-basal body connector - s left (sinister) root - sf 3left fibrils connecting Bb triplets to microtubular and/or fibrous roots. See Nomenclature section of Introduction for the numbering of basal bodies and their flagella; the same numbers apply to Bb-associated d and s roots, and df and sf fibrils