GLYCOCONJUGATE ORGANIZATION OF ENTEROMORPHA (=ULVA) FLEXUOSA AND ULVA FASCIATA (CHLOROPHYTA) ZOOSPORES1

Ecologically successful algae that colonize natural and artificial substrates in the marine environment have distinct strategies for opportunistic dispersal and settlement. The objective of this research was to visualize molecular architecture of zoospores from Enteromorpha (=Ulva) flexuosa (Wulfen) J. Agardh and Ulva fasciata Delile that coexist but alternate in dominance on an intertidal bench. Multiple fluorescent lectins were used to stabilize and probe for diverse zoospore glycoconjugates (GC) that could be involved in cell and substrate interactions. Results from epifluorescence microscopy showed distinct cellular and extracellular polymeric substance (EPS) domains of GC relative to settlement morphologies. Glycoconjugates were similar for both species with (1) α‐d mannose and/or glucose moieties localized on flagella, the anterior domes and anterior regions, the plasma membranes, and EPS; (2) α‐fucose localized on flagella and anterior regions; (3) N or α,ß‐N acetylglucosamine localized on flagella, the anterior regions, and EPS; and (4) varied N‐acetylgalactosamine and/or galactose moieties localized on each domain for both species excluding the plasma membranes. Some differences in lectin binding were observed for each species at the flagella, the anterior domes, and the plasma membranes. Glycoconjugate distributions shifted with morphological changes that followed initial adhesion. TEM of E. flexuosa zoospore stages following carbohydrate‐stabilizing fixations and gold‐conjugated lectin probes resolved GC with α‐d mannose and/or glucose, and/or N‐acetylglucosamine at the plasma membrane, ER and diverse vesicles of the anterior pole, EPS, and discontinuous regions or knobs associated with flagellar surfaces. The distinct distribution and diversity of zoospore GC may be central to recognition and attachment on diverse substrata by these algae.     

Morphology of <Emphasis Type="Italic">Mastigamoeba aspera</Emphasis> schulze, 1875 (Archamoebae,Pelobiontida)

The morphology of Mastigamoeba aspera, a typical species of the genus Mastigamoeba Schulze, 1875, was studied at the optical and electron microscopy level. During movement, M. aspera has an oval or pyriformic shape, with the motile flagella being located at the anterior end of mononuclear forms. In the process of movement, the mastigamoeba surface forms numerous conical or finger-shaped hyaline pseudopodia, whereas thel caudal cell end is usually transformed into a bulboid uroid. In M. aspera micropopulations, there are noted both mononuclear cells with flagella and multinuclear flagella-free individuals. The M. aspera plasma membrane has at its outer surface a hypertrophied glycocalix layer inhabited by numerous rod-shaped bacteria-ectobionts. The M. aspera nucleus is of vesicular type, with a large central spherical nucleolus. The flagellar apparatus is closely connected morphologically with the M. aspera nucleus. The basal flagella part is represented by a single kinetosome, from which radial microtubules and a lateral rootlet pass out into the cytoplasm. At the base of the kinetosome, there is located a compact center of organization of microtubules (COMT), in which there are immersed bases of the nuclear cone microtubules participating in formation of karyomastigont. The structure of the flagella axoneme corresponds to the formula 9(2)+2. The main volume of the M. aspera cytoplasm is occupied with digestive vacuoles. In addition, the cells contain numerous light-reflecting granules, as well as glycogen granules. Mitochondria, dictyosomes of the Golgi apparatus, and microbodies in the M. aspera cell cytoplasm are not revealed.     

Glycoconjugates of the human sperm surface: Distribution and alterations that accompany capacitation in vitro

We have studied changes in the binding of fluoresceinated lectins to human sperm during in vitro capacitation. We first determined the surface labeling pattern of viable sperm obtained by the swim-up procedure. Sperm were labeled with 100 μg/ml FITC-conjugated lectin at 4°C for 30 min. We simultaneously used Hoechst stain 33258 as a supravital stain to help differentiate surface from intracellular lectin labeling. Of 14 lectins studied, six (phytohemagglutinin-E, concanavalin A, Ricinus communis agglutinin-I, and the lectins of wheat germ, Lens culinaris, and Pisum sativum) bound to the entire surface of sperm, sometimes with minor local heterogeneity. Three lectins (from peanut, Maclura pomifera, and soybean) usually bound in a punctate manner, with more label on the tail than on the head. Five lectins (Ulex europaeus, Dolichos biflorus, Helix pomatia, and Vicia villosa lectins, and lectin II of Griffonia simplicifolia) bound very poorly or not at all to the sperm surface. Sperm were also inspected for changes in surface lectin binding patterns after 0, 5, and 23 hr of incubation in a capacitating medium. Two lectins showed reproducible changes. The labeling by Maclura pomifera agglutinin decreased by 5 hr in eight of ten experiments, and among sperm labeled with concanavalin A, the incidence of sperm with a highly fluorescent anterior margin of the sperm head increased by about 3.5-fold between 0 and 5 hr. The labeling pattern of the other lectins did not change.     

IDENTIFICATION OF MARINE DINOFLAGELLATES USING FLUORESCENT LECTINS1

Toxic and nontoxic species of marine dinoflagellates were characterized using fluorescent lectins. Lectin binding was detected by epifluorescence as well as spectrofluorometry. The binding assay of fluorescent lectins readily differentiated between morphologically similar species (i.e the toxic dinoflagellate Gymnodinium catenatum and the nontoxic Gymnodinium sp.). Lectins appear to be a useful tool to distinguish among different clones of the same species and, thus, possibly as a tool in dinoflagellate identification. Moreover, the lectins used show that thecate species have more binding sites and diversity in glycan moieties than athecate species.     

Ciliary beat and cell motility of Dunaliella: computer analysis of high speed microcinematography

A high-speed microcinematographic study was performed on the biflagellate unicellular alga Dunaliella. A frame-by-frame analysis has shown that the two flagella never beat at the same frequency. For a better characterization of the bending pattern of the two flagella, a new automated method of image analysis has been developed. The method allowed an automatic acquisition of a line characterizing the Dunaliella flagellum and its mathematical modelling. From this model, some binding parameters could be automatically measured, which have permitted determination of the velocities of formation and propagation of flagellar waves and the variation of the curvature radius of the bends between the two flagella. Both flagella showed a similar pattern of ciliary beat. The most important difference was the lengthening of the initiation phase for the slower flagella.     

The wound-healing responses of Antithamnion nipponicum and Griffithsia pacifica (Ceramiales, Rhodophyta) monitored by lectins

The binding of FITC labeled lectins to repair cells of Antithamnion nipponicum Yamada et Inagaki and Griffithsia pacifica Kylin, and their physiological effects on somatic cell fusion have been studied. Results indicate that repair cells strongly bind the lectins ConA and LCA, whereas other lectins did not bind to the cell, The binding of these lectins to the dead cell wall shows ConA and LCA specific substances are secreted from the tip of the repair cells. When fluorescently labeled ConA or LCA was added at various time intervals after wounding, it firstly bound (3 h post-wounding) as a thin layer at the tips of the adjacent cells. Later (4–5 h post-wounding) labeling also appeared at the tips of the repair ceils. Intense labeling at these sites continued throughout the wound-healing process until repair cell fusion, at which time the lectin labeling was reduced to a narrow ring around the area of fusion, When added to plants prior to wounding and with continued monitoring, these same lectins were found to act as inhibitors to the wound-healing response. Other control lectins showed no inhibitory effects. These results suggest that a signal glycoprotein with α-D-mannosyl residues is involved in the wound-healing process of Antithamnion nipponicum. Lectins conjugated with visible tags can be used as a very fast and useful tool to monitor these signal substances.     

CHARACTERIZATION OF PHOTOSYSTEM I-ASSOCIATED POLYPEPTIDES FROM THE CHLOROPHYLL b-RICH ALGA TETRASELMIS SPP. (PLEURASTROPHYCEAE) AND OTHER CHLOROPHYTE ALGAE1

The phylogenetic distribution of photosystem I-associated polypeptides was assessed by immunoblotting algal thylakoid membrane polypeptides with antisera generated against the P700-chlorophyll a protein (CC I) and a photosystem I light-harvesting chlorophyll-protein (LHC Ib). Polypeptides cross-reacting with the CC I apoprotein were found in 20 species representing four classes of unicellular algae. Polypeptides sharing antigenicity with spinach LHC Ib were observed only in algal species containing chlorophyll b. Tetraselmis spp. (Pleurastrophyceae), rich in chlorophyll b (Chl a:b 1.2), exhibited marked heterogeneity in the composition of their CC I and LHC Ib cross-reactive polypeptides. When immunoblotted with antisera against CC I, all Tetraselmis clones examined exhibited a 25-kD polypeptide in greater abundance than the 58-kD CC I apoprotein characteristic of higher plants and other green algal thylakoids. Three Tetraselmis clones (RG 6, RG 11, and RG 12) exhibited an 81-kD polypeptide with strong antigenicity toward the LHC Ib antisera, in contrast to the 17- to 24-kD cross-reactive polypeptides found in spinach, green algae, and one Tetraselmis clone (RG 5). Associated with the unique photosystem I polypeptide composition in Tetraselmis spp., Chl: P700 ratios for the group are 2–5 times greater than those observed for higher plants or other green algae. The chlorophyll b enrichment, unusual composition of photosystem I cross-reactive polypeptides, and heterogeneity of these polypeptides within isolates of Tetraselmis might make this genus useful for investigations of the functional organization of chlorophyll b in light-harvesting systems. These features also support the view of an alternative phyletic origin for the Pleurastrophyceae.     

ULTRASTRUCTURE OF THE FLAGELLAR APPARATUS OF PYROBOTRYS (CHLOROPHYCEAE)1

The flagellar apparatus of Pyrobotrys has a number of features that are typical of the Chlorophyceae, but others that are unusual for this class. The two flagella are inserted at the apex, but they extend to the side of the cell toward the outside of the colony, here designated as the ventral side. Four basal bodies are present, two of which extend into flagella. Four microtubular rootlets alternate between the functional and accessory basal bodies. In each cell, the two ventral rootlets are nearly parallel, but the dorsal rootlets are more widely divergent. The rootlets alternate between two and four microtubules each. A striated distal fiber connects the two functional basal bodies in the plane of the flagella. Two additional, apparently nonstriated, fibers connect the basal bodies proximal to the distal fiber. Another striated fiber is associated with each four-membered rootlet near its insertion into the flagellar apparatus. A fine periodic component is associated with each two-membered rootlet. A rhizoplast-like structure extends into the cell from each of the functional basal bodies. The arrangement of these components does not reflect the 180° rotational symmetry that is usually present in the Chlorophyceae, but appears to be derived from a more symmetrical ancestor. It is suggested that the form of the flagellar apparatus is associated with the unusual colony structure of Pyrobotrys.     

CHARACTERIZATION OF MORPHOSPECIES AND STRAINS OF MICROCYSTIS (CYANOBACTERIA) FROM NATURAL POPULATIONS AND LABORATORY CLONES USING CELL PROBES (LECTINS AND ANTIBODIES)1

The genus Microcystis (cyanobacteria) includes toxic and bloom-forming morphotypes which are usually arranged into species based on morphological features. Immunofluorescence assays using polyclonal and preadsorbed antibodies, as well as FITC-labebd lectins were used to characterize three morphospecies of Microcystis (M. viridis, M. wesenbergii, and M. aeruginosa) from natural populations (several lakes/reservoirs in Denmark and Spain) and laboratory clones. The cell probes used were unaffected by the different phases of the cell division cycle, growth phase, or environmental factors, such as culture medium, light, or temperature. Anhbody and lectin binding patterns were specific to each clone. In nature, the cell probes were useful tools to characterize Microcystis populations. Antibodies and lectins revealed geographic differentiation within the same morphospecies. Differentiation was moderate among nearby locales and intensified among areas distant from one another. Microcystis aeruginosa from Spain has very different cell surface antigens and lectin binding sites than M. aeruginosa from Denmark. A taxonomy of Microcystis based on cell probes reveals some discrepancies with classical morphospecies. The binding affinities were more closely related to the geographic origin of the tested material than to the morphospecies identification. Different morphospecies from the same lake in some cases were more similar than the same morphospecies from different lakes. Microcystis viridis and M. aeruginosa from Danish lakes appeared to be closely related species, whereas M. wesenbergii emerged as a different species.     

An ultrastructural comparison betweenSpermatozopsis andDunaliella (Chlorophyceae)

The ultrastructure of the type species of the genusDunaliella, D. salina, has been reinvestigated in an attempt to clarify the relationships betweenDunaliella andSpermatozopsis. Dunaliella salina differs in the following ultrastructural characters fromSpermatozopsis (as exemplified byS. similis Preisig etMelkonian): presence of a distinctive surface coat covering the plasmalemma; presence of a prominent pyrenoid (with pairs of thylakoids partially entering the pyrenoid matrix); dictyosomes parabasal; endoplasmic reticulum closely underlying the plasmalemma around most of the cell; contractile vacuoles absent; cell form ovoid to elongated and not spirally twisted; mitochondrial profiles near the flagellar apparatus. Differences in the ultrastructure of the flagellar apparatus: basal body angle more or less fixed; distal connecting fibre cross-striated; system II fibre (rhizoplast) present, associated with mitochondrial profile; system I fibre underlying two-stranded microtubular root; mating structure present. These ultrastructural differences justify distinction between the two taxa at generic level. The problematical status of freshwater species ofDunaliella is briefly discussed.     

An immunofluorescence study on lectin binding sites in gametes of Ectocarpus siliculosus (Ectocarpales, Phaeophyceae)

The distribution of binding sites for the lectins WGA, DSA. RCA I, PNA, AAA, MAA. SNA, GNA. and Con A in gametes of both sexes of the brown alga, Ectocarpus siliculosus (Dillw.) Lyngbye, was investigated by fluorescence microscopy. Digoxigenin-conjugated lectins and an FITC-anti-digoxigenin antibody were used as a high sensitivity detection system. Organelles and other distinct cellular domains could be distinguished by their binding specificities. Glycoconjugates associated with one flagellum were found to be associated with the axoneme by lectin binding to isolated flagellar apparatuses. In addition, changes in the distribution of carbohydrate epitopes during the attachment of gametes to the substratum were revealed by differential lectin binding.     

The Golgi apparatus of the scaly green flagellate Scherffelia dubia: uncoupling of glycoprotein and polysaccharide synthesis during flagellar regeneration

The flagella of the green alga Scherffelia dubia are covered by scales which consist of acidic polysaccharides and glycoproteins. Experimental deflagellation results in the regeneration of flagella complete with scales. During flagellar regeneration, scales are newly synthesized in the Golgi apparatus, exocytosed and deposited on the growing flagella. Flagellar regeneration is dependent upon protein synthesis and N-glycosylation, as it is blocked by cycloheximide and partially inhibited by tunicamycin. Metabolic labeling with [³⁵S]methionine/cysteine demonstrated that scale-associated proteins were not newly synthesized during flagellar regeneration, suggesting that the proteins deposited on regenerating flagella were drawn from a pool. Quantitative immunoelectron microscopy using a monospecific antibody directed against a scale-associated protein of 126 kDa (SAP126) revealed that the pool of SAP126 was primarily located at the plasma membrane, with minor labeling of the scale reticulum and trans-Golgi cisternae, both before deflagellation and during flagellar regeneration. Since SAP126 was sequestered during flagellar regeneration into secretory vesicles together with newly synthesized scales, it is concluded that the persistent presence of SAP126 in the trans-Golgi cisternae during scale biogenesis requires retrograde transport of the protein from the plasma membrane to the Golgi apparatus. Received: 3 July 1999 / Accepted: 21 August 1999     

High density of transmembrane glycoproteins on the flagellar surface of boar sperm cells

Membrane halves of boar sperm flagella were produced by freeze-fracture and labeled in situ with concanavalin A and wheat germ agglutinin; the lectins were visualized with protein-gold complexes. Concanavalin A and wheat germ agglutinin binding sites partition with both protoplasmic and exoplasmic halves of the membrane. A high density of lectin marking was found on protoplasmic membrane halves; we conclude that the label corresponds to transmembrane glycoproteins that, on freeze-fracture, are dragged across the outer (exoplasmic) half of the phospholipid bilayer. Our demonstration of numerous transmembrane proteins in sperm flagella offers the structural setting for previous models on flagellar surface motility that postulate accessibility of motile membrane components to the submembranous cytoskeleton.     

SOMATIC CELL FLAGELLAR APPARATUSES IN TWO SPECIES OF VOLVOX (CHLOROPHYCEAE)1

The somatic cell flagellar apparatuses of Volvox carteri f. weismannia (Powers) Iyengar and V. rousseletii G. S. West have parallel or nearly parallel basal bodies which are separated at their proximal ends. The four microtubular rootlets alternate between two and four members, and all are associated with a striated microtubular associated component (SMAC) that runs between the basal bodies. In addition, each half of the flagellar apparatus apparently rotates during development and loses the 180° rotational symmetry characteristic of most unicellular chlorophycean motile cells. All of these features appear necessary for efficient motion of a colony composed of numerous radially arranged cells. However, the structural details of the flagellar apparatuses of these two species differ. The distance between flagella is greater in V. rousseletii than in V. carteri. One distal striated fiber and two proximal striated fibers connect the basal bodies in V. carteri, but both types of fibers are absent from V. rousseletii. In the latter species, a striated fiber wraps around each of the basal bodies and attaches to the rootlets and the SMAC. No such fiber is present in V. carteri. Since the similarities in the flagellar apparatuses can be explained as a result of adaptation for efficient colonial motion in organisms with similar colonial morphology, the differences suggest a wider phylogenetic distance than previously believed.     

Seasonal lectin binding variations of thumb pad in the frog (Pelophylax ridibundus)

The thumb pad is one of the most common secondary sexual characteristics in frogs. Although it is known that amphibian skin has affinity for several lectins, there is no report regarding lectin‐binding affinity of the thumb pad or its structural components. This study investigated localization and seasonal variation of specific carbohydrate moieties of glycoconjugates in both the epidermal and dermal components of the frog thumb pad at the light microscopic level using lectin histochemistry. The study consisted of four seasonal groups of the frog species, Pelophylax ridibundus (Synonym of Rana ridibunda): active, prehibernating, hibernating and posthibernating. Four horseradish peroxidase conjugated lectins were employed. It was found that dolichos biflorus agglutinin (DBA), wheat germ agglutinin (WGA), and ulex europaeus (UEAI) gave positive reactions in both epidermal layers and breeding glands. These three lectins bound specific secretory cells in the breeding glands, and the distribution of the cells and epithelial lectin reactions exhibited seasonal changes. In addition, UEA‐I and peanut agglutinin (PNA) showed an affinity in granular glands and the granular zone of mixed glands. Generally, epidermal lectin binding showed dense affinity during the posthibernation period. DBA, UEA‐I, and WGA‐specific cells in the mucous gland decreased gradually until the posthibernation period. These findings suggest that differences of lectin binding in the thumb pad may be related to functional activities and, thus, seasonal adaptations. Moreover, the presence of specific lectin‐binding cells in the breeding glands indicated that they consisted of heterogeneous secretory cell composition or that the cells were at different secretory stages. J. Morphol. 275:76–86, 2014. © 2013 Wiley Periodicals, Inc.     

LIGHT AND ELECTRON MICROSCOPY OF A PUNCTATE SPECIES OF PYRAMIMONAS,P. MUCIFERA SP. NOV. (PRASINOPHYCEAE)1

Pyramimonas mucifera sp. nov., a punctate species of the genus, is unusual both behaviorally and at the fine structural level. It forms two distinct populations in culture, one benthic and one planktonic. Planktonic forms are more conventional for the genus, but benthic forms are found in loosely packed mucilage, have flagellar rather than ciliary beating of the flagella, and display a higher degree of metaboly. Ultrastructurally this species is unusual in that it has a unique scale complement and the cells contain numerous muciferous vesicles, leaving only small pockets of cytoplasm containing the usual organelles. This species has a 3–1 type flagellar apparatus but has an additional fibrillar band, a 4–3-2–3 microtubular root system and a flexible synistosome. The discovery of a mucilage-producing species of Pyramimonas draws attention to possible links with other prasinophytes (Halosphaera) and green algae of questionable affiliation (Oltmannsiellopsis and Hafniomonas). It also provides a model of the primitive pyramimonad.     

Electron Microscopic Studies on the Basal Apparatus of the Flagellum in the Protozoon, Leishmania donovani

SYNOPSIS. The basal apparatus of the flagella and kinetoplast in Leishmania donovani have been studied with the electron microscope. The flagellar fibrils extend into the body of the protozoan to form the kinetosome. At the point of origin of the flagellum, the pellicle invaginates to form a kinetosomal vacuole around the kinetosome. The kinetoplast is formed by a transversely elongated banded structure, surrounded at some distance by a double layered kinetoplast membrane. There is no apparent connection between the kinetosome and the kinetoplast.     

DEVELOPMENT OF THE FLAGELLAR APPARATUS AND FLAGELLAR POSITION IN THE COLONIAL GREEN ALGA PLATYDORINA CAUDATA (CHLOROPHYCEAE)1

The ultrastructure of the flagellar apparatus in pre-inversion and inversion stages of Platydorina resembles that of Chlamydomonas in having 180° rotational symmetry and clockwise absolute orientation. Basal bodies are in a “V” configuration and connected by one distal and two proximal fibers. Alternating two- and four-membered microtubular rootlets are cruciately arranged. During maturation, the basal bodies rotate and separate, and 180° rotational symmetry is lost. Simultaneously, each proximal fiber detaches from one of the functional basal bodies, and the distal fiber detaches from both. The mature apparatus has widely separated and nearly parallel basal bodies. Flagellar orientation in Platydorina is completed just after inversion and a flattening of the colony called intercalation, resulting in the pairs of flagella of neighboring cells extending from the colony in opposite directions in an alternating fashion. Flagellar orientation and separated basal bodies minimize the interference between the flagella of neighboring cells. Basal bodies and rootlets of the two intercalated halves of a colony rotate, resulting in the effective strokes of the flagella of every cell being towards the colonial posterior. The flagella of each cell beat with an effective stroke in the direction of the two inner rootlets. The flagella have an asymmetrical ciliary type beat. The rotated, separated, and parallel basal bodies, together with the nearly parallel rootlets probably are adaptations for movement of this colonial volvocalean alga. The flagellar apparatus in immature stages of Platydorina lends support to the suggestion that the alga has evolved from a Chlamydomonas-like ancestor.     

Interactions of galactose-binding lectins with plant protoplasts

Summary Protoplasts isolated from cell suspension cultures of carrot (Daucus carota L.) and leaves of tobacco (Nicotiana tabacum L.) were treated with three lectins specific for galactosyl residues. After incubation with RCA I (Ricinus communis agglutinin, molecular weight 120,000) conjugated to ferritin or fluorescein, freshly isolated protoplasts displayed heavy labeling of their surfaces. Moreover, they agglutinated rapidly when exposed to low concentrations of RCA I. In parallel studies, PNA (peanut agglutinin) also bound extensively to the protoplast plasma membranes whileBandeiraea simplicifolia lectin I attached relatively weakly. When protoplasts were cultured for two days and then incubated with conjugates of RCA I and PNA, additional binding sites were revealed on the regenerating walls.The results indicate that galactosyl residues are distributed densely over the surface of plant protoplasts. They also allow inferences to be made regarding the positions and linkages of the galactose groups being recognized by the lectins. Moreover, they open up the question whether the galactosyl moieties detected in the wall derive from those labeled on the plasma membrane. To conclude, we make comparisons with binding by concanavalin A, and predict that galactose-recognizing lectins will join and in certain respects prove superior to concanavalin A as probes of the plant cell surface.     

POLYPHYLETIC ORIGIN OF PARALLEL BASAL BODIES IN SWIMMING CELLS OF CHLOROPHYCEAN GREEN ALGAE (CHLOROPHYTA)1

The evolutionary affinities of Heterochlamydomonas Cox and Deason and Dictyochloris Vischer ex Starr were investigated using phylogenetic analyses of a combined data set of 18S and 28S rDNA sequences with those from 38 additional green algae. Previous ultrastructural studies have shown that motile cells of Heterochlamydomonas and Dictyochloris have an unusual flagellar apparatus organization in that the two flagella are of unequal length and the basal bodies are persistently parallel. Because of this similarity these taxa, along with Bracteacoccus Tereg, a third taxon with this same flagellar apparatus arrangement, are hypothesized to be closely related. We show, with maximum parsimony and Bayesian analyses, that the parallel basal bodies are not homologous in the three genera. Rather, Heterochlamydomonas is most closely related to Chlamydomonas baca in the clockwise flagellar apparatus clade, and Dictyochloris and Bracteacoccus are nested within the Sphaeropleales, which has the directly opposite flagellar absolute orientation. Surprisingly, Dictyochloris and Bracteacoccus are not supported as closest relatives. These relationships are supported by morphological features such as the presence or absence of a walled motile cell but not by the orientation of the basal bodies. In addition, our data are derived from multiple isolates of each study genera, and the analyses show that Heterochlamydomonas and Dictyochloris are each monophyletic.