DEVELOPMENT OF THE FLAGELLAR APPARATUS AND FLAGELLAR ORIENTATION IN THE COLONIAL GREEN ALGA GONIUM PECTORALE (VOLVOCALES)1

Vegetative cells of Gonium pectorale have a fine structure similar to that of Chlamydomonas. In addition, three zones comprise an extracellular matrix; a fibrillar sheath and tripartite boundary surround individual cells, and a fragile capsule zone surrounds the entire colony. Cytokinesis is accomplished by a phycoplast and cleavage furrow. The flagellar apparatus of the immature vegetative cell of this colonial alga is similar to that of Chlamydomonas, but the basal bodies are slightly separated at their proximal ends. The four microtubular rootlets alternate between two and four members. During development, the basal bodies become further separated and nearly parallel. The distal fiber is stretched, but it remains attached to both basal bodies. At maturity, the basal bodies of peripheral cells of the colony have rotated in opposite directions on their longitudinal axes resulting in a displacement of the distal fiber to one side, an asymmetrical orientation of the rootlets and loss of 180° rotational symmetry. Central cells remain similar to Chlamydomonas in that basal bodies do not rotate, rootlets are cruciate, the distal fiber remains medially inserted and 180° rotational symmetry is conserved. A “pin-wheel” configuration of flagellar pairs and the orientation of parallel rootlets toward the colony perimeter probably accounts for the rotation of the colonies during forward swimming. In addition, these ultrastructural features support the traditional placement of G. pectorale as an intermediate between the unicellular Chlamydomonas and the more complex colonial volvocalean genera.     

FINE STRUCTURE OF THE SNOW ALGA (CHLAMYDOMONAS NIVALIS) AND ASSOCIATED BACTERIA1

Chlamydomonas nivalis (Bau.) Wille is present in red snow as large spherical resting cells. Fine structural studies reveal an abundance of clear granules in the cytoplasm and occasional starch grains in the chloroplast. Individual cells display a thick cell wall with a smooth outer surface. Cells may be surrounded by a loose fibrous network in which encapsulated bacteria are seen. The bacteria have a characteristic Gram-negative cell wall and constrictive mode of division. The algal-bacterial association appears to be characteristic of red snow populations.     

DISINTEGRATION OF THE CELLS OF SIPHONOUS GREEN ALGA CODIUM EDULE (BRYOPSIDALES,CHLOROPHYTA) UNDER MILD HEAT STRESS1

The siphonous green alga Codium edule P. C. Silva (Bryopsidales, Chlorophyta) has the highest covering ratio among the macroalgae on the coral reef of Nanwan Bay in southern Taiwan, but its population in the subtidal region drastically decreases from July to September each year. The objective of this study was to determine whether the high temperature of summer could be the basis for this population decrease. Chlorophyll fluorescence measurements revealed that when the algae were incubated at 35°C (a temperature that can be reached in southern Taiwan during the summer), their photosynthetic activities were almost completely inhibited after about 8 h. The circadian rhythm of photosynthesis was disrupted at a temperature as low as 32°C. TEM studies showed that 4 h incubation at 35°C induced a decrease in turgidity accompanied by vacuole shrinkage and plasmolysis. The marked disintegrative changes, including damage to organelles, such as chloroplasts and nuclei, occurred after about 8 h, at which time central vacuoles collapsed and the cell interior was then filled with numerous small vesicles. Our results suggested that the rise in seawater temperature during the summer could be one of the major causes of the massive death of C. edule in the field.     

PURIFICATION AND CHARACTERIZATION OF PYRUVATE KINASE FROM THE GREEN ALGA CHLAMYDOMONAS REINHARDTII1

A single form of pyruvate kinase was isolated from the green alga Chlamydomonas reinhardtii Dang. (Chlorophyta) and partially purified over twentyfold, yielding a final specific activity of 2.68 μmol pyruvate produced-min^-1.mg^-1 protein. Studies of its physical characteristics reveal that the pyruvate kinase is heat stable, is partially inactivated by sulfhydryl reagent N-ethylmaleimide, and has a pH optimum at 6.8 and a native molecular mass of 224 kDa. Immunological precipitation and western blotting, using antibodies raised against Selenastrum minutum Naeg. (Chlorophyta) cytosolic pyruvate kinase, reveal that C. reinhardtii pyruvate kinase possesses a subunit molecular mass of 57 kDa, indicating a homo-tetrameric structure. This enzyme exhibits an absolute requirement for a divalent cation that can be fulfilled, by Mg²⁺. The monovalent cation K⁺ acts as a strong activator. The K_m values for phosphoenolpyruvate and adenosine diphosphate (ADP) are 0.16 mM and 0.18 mM, respectively. The enzyme is capable of using other nucleotides with V_max for UDP, GDP, IDP, and CDP of 70%, 55%, 53%, and 25% of that with ADP, respectively. Dihydroxyacetone phosphate, ribulose 1,5-bisphosphate, adenosine monophosphate (AMP), ribose-5-phosphate, and glyceraldehyde-3-phosphate are activators, whereas glutamate, orthophosphate, adenosine triphosphate (ATP), citrate, isocitrate, malate, oxalate, phosphoglycolate, and 2,3-diphosphoglycerate are potent inhibitors of this enzyme. Dihydroxyacetone phosphate can reverse the inhibition by glutamate and phosphate. These properties are discussed in light of pyruvate kinase regulation during anabolic and catabolic respiration. Substrate interaction and product inhibition studies indicate that ADP is the first substrate bound to the enzyme and pyruvate is the last product released (Ordered Bi Bi mechanism).     

PURIFICATION AND CHARACTERIZATION OF A LECTIN,BRYOHEALIN, INVOLVED IN THE PROTOPLAST FORMATION OF A MARINE GREEN ALGA BRYOPSIS PLUMOSA (CHLOROPHYTA) 1

When the coenocytic green alga Bryopsis plumosa (Huds.) Ag. was cut open and the cell contents were expelled, the cell organelles agglutinated rapidly in seawater to form protoplasts. Aggregation of cell organelles in seawater was mediated by a lectin–carbohydrate complementary system. Two sugars, N‐acetyl‐d ‐glucosamine and N‐acetyl‐d ‐galactosamine inhibited aggregation of cell organelles. The presence of these sugars on the surface of chloroplasts was verified with their complementary fluorescein isothiacyanate‐labeled lectins. An agglutination assay using human erythrocytes showed the presence of lectins specific for N‐acetyl‐d ‐galactosamine and N‐acetyl‐d ‐glucosamine in the crude extract. One‐step column purification using N‐acetyl‐d ‐glucosamine‐agarose affinity chromatography yielded a homogeneous protein. The protein agglutinated the cell organelles of B. plumosa, and its agglutinating activity was inhibited by the above sugars. Sodium dodecyl sulfate polyacrylamide gel electrophoresis results showed that this protein might be composed of two identical subunits cross‐linked by two disulfide bridges. Enzyme and chemical deglycosylation experiments showed that this protein is deficient in glycosylation. The molecular weight was determined as 53.8 kDa by matrix‐assisted laser desorption/ionization time‐of‐flight mass spectrometry. The N‐terminal 15 amino acid sequence of the lectin was Ser–Asp–Leu–Pro–Thr–X–Asp–Phe–Phe–His–Ile–Pro–Glu–Arg–Tyr, and showed no sequence homology to those of other reported proteins. These results suggest that this lectin belongs to a new class of lectins. We named this novel lectin from B. plumosa“bryohealin.”     

THE DEVELOPMENT AND POTENTIAL ROLES OF CELL‐WALL TRABECULAE IN CAULERPA MEXICANA (CHLOROPHYTA)1

Siphonous plants represent an alternate scheme to the way most macroscopic plants are constructed. They are single, often large (1–2 m), sometimes morphologically complex, multinucleate (coenocytic) cells where the whole of the cytoplasm is a continuum. Caulerpa mexicana Sond. ex Kütz. is a siphonous tropical marine green alga characterized by four morphologically distinct regions and, as with other members of the genus, by the presence of a dense network of anastomosing cylindrical cell wall in growths called trabeculae. Based on the results of this study, we propose several roles for trabeculae: (i) They are structural components, which likely add some small amount of support in compression but add considerable strength in tension. (ii) As extensions of the cell wall and plasma membrane, they act as diffusion channels from the cell exterior to the interior cytoplasm. It is possible that trabeculae also play a role in determining cell shape through developmental positioning and placement patterns, thus facilitating the diverse shapes found in the morphologically distinct regions of Caulerpa sp.     

PYRENOID FORMATION ASSOCIATED WITH THE CELL CYCLE IN THE BROWN ALGA,SCYTOSIPHON LOMENTARIA (SCYTOSIPHONALES,PHAEOPHYCEAE)1

Vegetative cells of the brown alga Scytosiphon lomentaria (Lyngbye) Link characteristically have only one chloroplast with a prominent protruding pyrenoid, whereas zygotes have both paternal and maternal chloroplasts. In zygotes, before cell and chloroplast division, each chloroplast has an old and a new pyrenoid. In this study, we raised a polyclonal antibody to RUBISCO and examined the distribution of RUBISCO by immunofluorescence microscopy, focusing on new pyrenoid formation in vegetative cells of gametophytes and zygotes in Scytosiphon. In interphase, only one old pyrenoid was positively indicated by anti‐RUBISCO antibody in vegetative cells of gametophytes. From mid‐S phase, small fluorescence aggregates reflecting RUBISCO localization started to appear at stroma positions other than adjacent to the old protruding pyrenoid. The fluorescent spots eventually coalesced into a protrusion into the adjacent cytoplasm. We also used inhibitors to clarify the relationship between the cell cycle and new pyrenoid formation, using zygotes after fertilization. When DNA replication was blocked by aphidicolin, new pyrenoid formation was also inhibited. Washing out aphidicolin permitted new pyrenoid formation with the progression of the cell cycle. When mitosis was prolonged by nocodazole, which disrupted the spindle microtubules, the fluorescent masses indicating RUBISCO localization continued to increase when compared with pyrenoid formation in untreated zygotes. During treatment with chloramphenicol, mitosis and cytokinesis were completed. However, there was no occurrence of new RUBISCO localization within the chloroplast stroma beyond the old pyrenoid. From these observations, it seems clear that new pyrenoid formation in the brown alga Scytosiphon depends on the cell cycle.     

POPULATION DYNAMICS OF GREEN NOCTILUCA SCINTILLANS (DINOPHYCEAE) ASSOCIATED WITH THE MONSOON CYCLE IN THE UPPER GULF OF THAILAND1

Population dynamics of Noctiluca scintillans (Macartney) Kof. et Swezy containing the photosynthetic endosymbiont Pedinomonas noctilucae (Subrahman.) Sweeney was investigated in relation to environmental conditions in the upper Gulf of Thailand. A clear association was observed between the abundance of N. scintillans and the monsoon cycle, with its blooms occurring during the southwest (SW) monsoon from May to September, and low abundance during the northeast (NE) monsoon from November to February. Nutrient concentrations were higher during the SW monsoon than during the NE monsoon due to the combined effect of increased river discharge into the northern upper gulf and the transport of the riverine inputs by the prevailing clockwise circulation of the water. These nutrient conditions favored the growth of both phytoplankton and the endosymbiont. Correlation analysis revealed that the higher abundance of N. scintillans in the SW monsoon was manifested primarily by higher growth through both sexual and asexual reproduction supported by phagotrophy. However, the dependence of N. scintillans on the nutrient concentration was not significant, probably because the nutrient supply for the endosymbiont was sufficient due to intracellular accumulation of nutrients within the host cells. Sexual reproduction occurred only during the SW monsoon, and its potential importance in population growth was suggested. These findings showed the bottom‐up control of the population dynamics of N. scintillans through growth of phytoplankton as prey. The seasonal shift in the circulation pattern associated with the monsoon cycle played a crucial role in blooming of N. scintillans by producing favorable food conditions.     

ACCUMULATION AND REDUCTION OF ARSENATE BY THE FRESHWATER GREEN ALGA CHLORELLA SP. (CHLOROPHYTA)

Arsenate accumulation and reduction kinetics at both high and low phosphate concentrations were investigated in the green alga Chlorella sp, isolated from the arsenic-contaminated Upper Mystic Lake near Boston, MA. Growth rate, accumulated cellular arsenic, and release of As(III) were determined over a range of arsenate concentrations. Arsenate inhibited growth and reduced final cell yield at high phosphate concentration. However, growth rate, final cell yield, and cellular arsenic content were all enhanced by higher arsenate concentrations in cultures grown at a low concentration of phosphate. The traditional view that phosphate-limited cells are necessarily more sensitive to As(V) toxicity may not be correct. The reduction rates of As(V) by Chlorella sp. obtained in our laboratory were similar to net reduction rates measured in epilimnetic water from the Upper Mystic Lake, demonstrating the importance of phytoplankton in arsenic reduction in freshwater.     

CELL WALL CARBOHYDRATE EPITOPES IN THE GREEN ALGA OEDOGONIUM BHARUCHAE F. MINOR (OEDOGONIALES,CHLOROPHYTA)1

Cell wall changes in vegetative and suffultory cells (SCs) and in oogonial structures from Oedogonium bharuchae N. D. Kamat f. minor Vélez were characterized using monoclonal antibodies against several carbohydrate epitopes. Vegetative cells and SCs develop only a primary cell wall (PCW), whereas mature oogonial cells secrete a second wall, the oogonium cell wall (OCW). Based on histochemical and immunolabeling results, (1→4)‐β‐glucans in the form of crystalline cellulose together with a variable degree of Me‐esterified homogalacturonans (HGs) and hydroxyproline‐rich glycoprotein (HRGP) epitopes were detected in the PCW. The OCW showed arabinosides of the extensin type and low levels of arabinogalactan‐protein (AGP) glycans but lacked cellulose, at least in its crystalline form. Surprisingly, strong colabeling in the cytoplasm of mature oogonia cells with three different antibodies (LM‐5, LM‐6, and CCRC‐M2) was found, suggesting the presence of rhamnogalacturonan I (RG‐I)–like structures. Our results are discussed relating the possible functions of these cell wall epitopes with polysaccharides and O‐glycoproteins during oogonium differentiation. This study represents the first attempt to characterize these two types of cell walls in O. bharuchae, comparing their similarities and differences with those from other green algae and land plants. This work represents a contribution to the understanding of how cell walls have evolved from simple few‐celled to complex multicelled organisms.     

STRUCTURE AND ASEXUAL REPRODUCTION OF THE ENIGMATIC CHAROPHYCEAN GREEN ALGA ENTRANSIA FIMBRIATA (KLEBSORMIDIALES,CHAROPHYCEAE)1

As the closest relatives of embryophytes, the charophycean green algae (sensu Mattox and Stewart) may reveal the evolutionary history of characters in this lineage. Recent molecular phylogenetic analysis indicates that the little‐known species Entransia fimbriata Hughes is a member of the charophycean order Klebsormidiales. In this study LM and EM were used to identify and describe additional structural characters of Entransia so that comparisons could be made with Klebsormidium and with other charophycean algae outside the order Klebsormidiales. Features that Entransia shares with various members of the genus Klebsormidium include cylindrical cells in unbranched filaments that may spiral, parietal chloroplasts that cover only part of the circumference of the cell, H‐shaped cross walls, and vegetative reproduction by both fragmentation and formation of zoospores or aplanospores. Among the characteristics that distinguish Entransia from Klebsormidium are a highly lobed chloroplast with multiple pyrenoids; a single large vacuole; short cells that die and collapse, apparently facilitating filament fragmentation; and germinating filaments with condensed adhesive at the base and a tapering spine at the tip. Although Entransia has sometimes been tentatively considered to be a member of the Zygnemataceae, the presence of a flagellate life history stage distinguishes Entransia from this group. The pyrenoids of Entransia are typical of those of charophycean algae in having traversing membranes and surrounding starch. Presence of multiple such pyrenoids in each chloroplast of Entransia supports the hypothesis that the common ancestor of charophycean algae and embryophytes had a single chloroplast with multiple pyrenoids.     

CHARACTERIZATION OF A RABE (RAS GENE FROM RAT BRAIN E) GTPASE EXPRESSED DURING MORPHOGENESIS IN THE UNICELLULAR GREEN ALGA MICRASTERIAS DENTICULATA (ZYGNEMATOPHYCEAE,STREPTOPHYTA)1

Rab GTPases are central regulators of cell shape in land plants by coordinating vesicle trafficking during morphogenesis. To date, relatively little is known about the role of these ubiquitous signaling proteins during cell growth in microalgae, in particular in the related charophyte algae. This article identifies the first charophyte Rab GTPase, MdRABE1, in Micrasterias denticulata Bréb., a convenient model organism for studying morphogenesis. Its expression correlated with the onset of morphogenesis, and structural analysis indicated that it belongs to the RABE (Ras gene from rat brain E) subclass. Confocal fluorescence and immunoelectron microscopy (IEM) of transiently GFP‐MdRABE1 overexpressing interphase cells demonstrated that the GFP‐MdRABE1 protein was localized to the endoplasmic reticulum, dictyosomes, exocytotic vesicles, the cell margin, the membranes of cell organelles, and in the isthmus zone around the nucleus. Although overexpression phenotyping of both N‐ and C‐terminal green fluorescent protein (GFP) fusions failed to indicate additional functional evidence of the MdRABE1 protein due to mortality of those transgenic cells, its expression profile, bioinformatics, and intracellular localization suggest a role in vesicle trafficking during morphogenesis.     

GROWTH AND POLYSACCHARIDE PRODUCTION BY THE GREEN ALGA CHLAMYDOMONAS MEXICANA (CHLOROPHYCEAE) ON SOIL1

The polysaccharide producing soil alga Chlamydomonas mexicana Lewin was grown on soil surfaces in a growth chamber, with cell number and total polysaccharide measured weekly. Cell growth was pronounced, reaching an excess of 10⁷ cells · cm^?2 within one week. Polysaccharide production was also pronounced, with similar amounts of polysaccharide synthesized whether or not the cells were continuously given nutrients. Polysaccharide synthesis increased once the cells slowed in their growth, as in previous work with the cells in liquid medium.     

FACTORS REGULATING THE SPATIAL DISTRIBUTION OF THE FILAMENTOUS ALGA PITHOPHORA OEDOGONIA (CHLOROPHYCEAE) IN AN INDIANA LAKE1

Pithophora oedogonia (Mont.) Wittr. biomass in Surrey Lake, Indiana was greater in the littoral than in the pelagial region. Although mean soluble reactive phosphorus concentrations did not differ between the two areas, nitrate concentrations were almost six times higher in the cove than in the open water. Using laboratory cultures of Pithophora, the half saturation constant (K_s at 20° C relating filament growth to external concentrations of nitrate-nitrogen was determined to be 1.23 mg L^?1 (=88 μM)and for phosphate-phosphorus, 0.1 mg L^?1 (=3.22 μM). These values were used to calculate a NO₃-N/PO₄-P atomic ratio of 27.6. Comparison of this value with NO₃-N/PO₄-P ratios in Surrey Lake showed that nitrogen limiting conditions were prevalent in the open water section of the lake. Alkaline phosphatase and dark ammonia uptake analyses on field collected filaments from the shallow and deep water sections confirmed the hypothesis that nitrate is the major factor limiting growth of Pithophora in Surrey Lake.     

MOLECULAR CHARACTERIZATION OF THE LECTIN,BRYOHEALIN, INVOLVED IN PROTOPLAST REGENERATION OF THE MARINE ALGA BRYOPSIS PLUMOSA (CHLOROPHYTA)1

When a coenocytic cell of the green alga Bryopsis plumosa (Hudson) C. Agardh was cut open and the cell contents expelled, the cell organelles agglutinated rapidly in seawater to form protoplasts. This process was mediated by a lectin, Bryohealin. The full sequence of the cDNA encoding Bryohealin was obtained, which consisted of 1,101 base pairs (bp), with 24 bp of 5′ untranslated region (UTR) and 201 bp of 3′ UTR. It had an open reading frame (ORF) of 771 bp encoding 257 amino acid residues. A signal peptide consisted of 22 amino acids presented before the start codon of Bryohealin, indicating that this lectin was a vacuolar (storage) protein. The C‐terminal sequence of Bryohealin was composed of antibiotic domains, suggesting that this lectin could perform two functions: (i) aggregation of cell organelles in seawater and (ii) protection from bacterial contamination for successful protoplast regeneration. The BLAST search result showed that Bryohealin had little sequence homology with any known plant lectins, but rather resembled animal lectins with fucolectin domains. The expression of recombinant Bryohealin (rBryohealin) was obtained in the Escherichia coli system.     

THE ULTRASTRUCTURE OF MEIOSPORES OF COLEOCHAETE PULVINATA (CHAROPHYCEAE)1

In view of the relative importance of reproductive cell ultrastructure in phylogenetic and systematic studies of green algae, we investigated the fine structure of germinating zygotes and meiospores of Coleochaete pulvinata Braun. Meiospores have a flagellar apparatus very similar to that of zoospores and spermatozoids of the same species. Meiospores differ from zoospores and spermatozoids of C. pulvinata in having pyramidal body scales similar to those present on zoospores of C. scutata. Meiospores of C. pulvinata had as many as twice the number of spline microtubules as zoospores, and four times the number present in splines of spermatozoids of the same species. Developing meiospores of C.pulvinata, like those of other Coleochaete species, are individually surrounded by chamber walls. These differed from vegetative cell walls in lacking plasmodesmata. Moreover, the chamber walls in germinating zygotes of C.pulvinata stained a cobalt blue color with resorcinal blue, and fluoresced yellow in the presence of aniline blue, thus exhibiting the staining characteristics of callose. In location, morphology and presence of callose, chamberwalls resemble “special walls” of land plants, they may represent a charophycean spore development preadaptation useful in the evolution of walled spores characteristic of land     

A PRELIMINARY COMPARISON OF RESTRICTION FRAGMENT PATTERNS IN THE GENUS CAULERPA (CHLOROPHYTA) AND THE UNIQUE STRUCTURE OF THE CHLOROPLAST GENOME OF CAULERPA SERTULARIOIDES1

Comparisons of chloroplast DNA restriction fragments in four species of Caulerpa revealed that patterns between the species were different, with few and possibly no homologous bands. Two forms of Caulerpa sertularioides also revealed different patterns, and it is possible that the forms are separate species. The chloroplast genome in Caulerpa sertularioides f sertularioides (S. G. Gmelin) Howe is 131.4 kb in size and lacks large repeat units. The discovery of another green-algal chloroplast genome that lacks an inverted repeat indicates that this feature is either not ancestral to the Chlorophyceae or has been lost several times. Several gene clusters commonly found in chloroplast DNAs were found to occur in Caulerpa chloroplast DNA, for example, psbD/C, atpF/H, and psaA/B. The 16S and 23s rRNA, which are typically adjacent, contained in an inverted repeat, and cotranscribed, are over 40 kb apart. Genes rps12 and tufA, members of the str operon in eubacteria, are over 50 kb in distance from each other in Caulerpa. The gene order in Caulerpa is unlike any other chloroplast genome characterized to date.     

GROWTH OF THE FILAMENTOUS GREEN ALGA CTENOCLADUS CIRCINNATUS (CHAETOPHORALES,CHLOROPHYCEAE) IN RELATION TO ENVIRONMENTAL SALINITY1

Clones of the filamentous green alga Ctenocladus circinnatus Borzi were isolated from algae collected at Abert Lake (Oregon) and Mono Lake (California). Stock cultures were exposed to varied salinities of natural lake water to examine the effects on growth rate, cell form, chlorophyll a, and water content. Growth rates were reduced in both clones with increased salinity over the range 25–100 g·L^?1 and were almost completely inhibited at 150 g·L^?1. Chlorophyll a increased between salinities of 25 and 100 g·L^?1, reflecting slower growth, higher proportions of akinetes, and smaller cell sizes as salinity increased. Tissue water content remained essentially constant from 25 to 100 g·L^?1 salinity. Shorter cell dimensions with increased salinity suggest that a lower surface-to-volume ratio may reduce the potential for passive loss of cell water. Prior acclimation of stock cultures to elevated salinity provided no enhancement of growth response at any salinity. The results indicate that environmental salinity can limit the productivity and distribution of Ctenocladus in nature.     

HEMIFLAGELLOCHLORIS KAZAKHSTANICA GEN. ET SP. NOV.: A NEW COCCOID GREEN ALGA WITH FLAGELLA OF CONSIDERABLY UNEQUAL LENGTHS FROM A SALINE IRRIGATION LAND IN KAZAKHSTAN (CHLOROPHYCEAE,CHLOROPHYTA)1

A coccoid green alga, Hemiflagellochloris kazakhstanica S. Watanabe, S. Tsujimura, T. Misono, S. Nakamura et H. Inoue, gen. et sp. nov., was described from soil samples of a saline irrigation land in Ili River basin, Kazakhstan. This alga had a parietal chloroplast with a pyrenoid, which was covered with starch segments and penetrated with thylakoid membranes. Reproduction occurred by the formation of aplanospores and zoospores. The aplanospores frequently formed tetrad aggregations in a mother cell. The zoospores were covered by a single‐layered cell wall and lacked stigmata. The zoospores had two flagella of considerably unequal lengths; the longer flagellum was 17–19 lm in length and the shorter one was 9–10 lm. The flagellar apparatus architecture was of the clockwise orientation group type in the Chlorophyceae. Molecular phylogenetic analysis using 18S and 28S rDNA sequence data resolved this organism in a separate clade from the green algae that had flagella of slightly unequal lengths. It was suggested that features such as inequality in flagellar lengths, parallel exsertion of basal bodies, and subapical position of the flagellar apparatus were sporadically evolved.