Behavior of flagella and flagellar root systems in the planozygotes and settled zygotes of the green alga Bryopsis maxima Okamura (Ulvophyceae,Chlorophyta) with reference to spatial arrangement of eyespot and cell fusion site

Behaviors of male and female gametes, planozygotes and their microtubular cytoskeletons of a marine green alga Bryopsis maxima Okamura were studied using field emission scanning electron microscopy, high‐speed video microscopy, and anti‐tubulin immunofluorescence microscopy. After fusion of the biflagellate male and female gametes, two sets of basal bodies lay side by side in the planozygote. Four long female microtubular roots extended from the basal bodies to the cell posterior. Four short male roots extended to nearly half the distance to the posterior end. Two flagella, one each from the male and female gametes, become a pair. Specifically, the no. 2 flagellum of the female gamete and one male flagellum point to the right side of the eyespot of the female gamete, which is located at the cell posterior and which is associated with 2s and 2d roots of the female gamete. This spatial relationship of the flagella, microtubular roots, and the eyespot in the planozygote is retained until settlement. During forward swimming, the planozygote swings the flagella backward and moves by flagellar beating. The male and female flagella in the pair usually beat synchronously. The cell withdraws the flagella and becomes round when the planozygote settles to the substratum 20 min after mixing. The axoneme and microtubular roots depolymerize, except for the proximal part and the basal bodies. Subsequently, distinct arrays of cortical microtubules develop in zygotes until 30 min after mixing. These results are discussed with respect to the functional significance of the spatial relationships of flagellar apparatus‐eyespot‐cell fusion sites in the mating gametes and planozygote of green algae.     

Ultrastructure of the biflagellate gametes of Collinsiella cava (Ulvophyceae, Chlorophyta)

The fine structure of the biflagellate gametes of Collinsiella cava (Yendo) Printz was investigated in detail to clarify the species's taxonomic and phylo‐genetic position. Gametes are covered by small square scales with no distinct substructure. The chloroplast of the gamete includes an eyespot comprised of two layers of globules, and a pyrenoid that is traversed by one or a few thylakoids. Basal bodies overlap at their proximal ends and are offset in a counterclockwise orientation. Each basal body has a small bipartite terminal cap, a prominent proximal sheath comprised of two unequal subunits and a circular element situated at the cartwheel portion. A distal fibre, a connecting fibre and linkage between proximal sheaths connect the two basal bodies. Microtubular roots are comprised of two dexter (d) roots, subtended by the system I fibre, and two sinister (s) roots. Gametes have a single rhizoplast which extends parallel to one of the two d roots and extends to the mating structure. The ultrastructure of Collinsiella gametes is very similar to that of Mono‐stroma and other members of the Ulotrichales, Ulvophyceae, and we concluded that the genus Collinsiella should be treated as a member of the Monostromat‐aceae. The planozygote has four basal bodies, eight microtubular roots and two eyespots always situated at the same face of the cell. From observations of the planozygotes, the position of the mating structure relative to the flagellar apparatus is not consistent, but converse, between two mating types. A comparison of the location of the mating structure in Chlamydomonas and other green algae is presented.     

Sexual agglutination in Chlamydomonas eugametos before and after cell fusion

A new study of sexual agglutination between Chlamydomonas eugametos gametes and between vis-à-vis pairs has been made using techniques that allow one to distinguish between the flagella or cell bodies of individual mating types (mt⁺ or mt^-). It is shown that before mt⁺ and mt^- gametes fuse in pairs, their flagella, which adhere over their whole length, are maintained in a particular conformation around the mt^- cell body. In clumps of agglutinating gametes the cells are asymmetrically distributed with the mt⁺ gametes constituting the outer surface of the clumps with the mt^- gametes on the inside. The flagella are then all directed towards the middle of the clump. This orientation of the flagella is maintained for approx. 8 min after cell fusion before the vis-à-vis pair becomes motile. At this stage, all the flagellar tips are activated. The original mt⁺ flagellar tips then deactivate and swimming is resumed. The original mt^- flagella remain immotile and activated after cell fusion and eventually shorten by a third, but only 30 min or more after fusion. Motile vis-à-vis pairs eventually settle to the substrate when the gamete bodies fuse completely to form a zygote. Settling vis-à-vis pairs are attracted to those that have already settled, to glutaraldehyde-fixed pairs and to flagella isolated from mt^- gametes. They are not chemotactically attracted, rather they are weakly agglutinated. Living vis-à-vis pairs can be shown to aggregate in rows with the cell bodies lying side by side. It is argued that the flagellar agglutination sites involved in gamete recognition are also involved in vis-à-vis pair aggregationAbbreviations mt^+/- mating type plus or minus - FTA flagellar tip activation     

ASYMMETRY OF EYESPOT AND MATING STRUCTURE POSITIONS IN ULVA COMPRESSA (ULVALES,CHLOROPHYTA) REVEALED BY A NEW FIELD EMISSION SCANNING ELECTRON MICROSCOPY METHOD1

Gametes of the marine green alga Ulva compressa L. are biflagellate and pear shaped, with one eyespot at the posterior end of the cell. The species is at an early evolutionary stage between isogamy and anisogamy. In the past, zygote formation of green algae was categorized solely by the relative sizes of gametes produced by two mating types (+ and ?). Recently, however, locations of cell fusion sites and/or mating structures of gametes have been observed to differ between mating types in several green algae (asymmetry of cell fusion site and/or mating structure positions). To use this asymmetry for determining gamete mating type, we explored a new method, field emission scanning electron microscopy (FE‐SEM), for visualizing the mating structure of U. compressa. When gametes were subjected to drying stress in the process of a conventional critical‐point‐drying method, a round structure was observed on the cell surfaces. In the mating type MGEC‐1 (mt⁺), this structure was located on the same side of the cell as the eyespot, whereas it was on the side opposite the eyespot in the mating type MGEC‐2 (mt^?). The gametes fuse at the round structures. TEM showed an alignment of vesicles inside the cytoplasm directly below the round structures, which are indeed the mating structures. Serial sectioning and three‐dimensional construction of TEM micrographs confirmed the association of the mating structure with flagellar roots. The mating structure was associated with 1d root in the MGEC‐1 gamete but with 2d root in the MGEC‐2 gamete.     

Synthesis and turnover of cell body-agglutinin as a pool of flagellar surface-agglutinin inChlamydomonas reinhardii gamete

Chlamydomonas reinhardii cells were broken in a French press and the soluble fraction was tested for agglutination activity. Deflagellated cell bodies ofmt ⁺ andmt ^- gametes yielded soluble fractions that were able to isoagglutinate gametes of the opposite mating type. When the wild-type gametes of opposite mating types were mixed, the cell body-agglutinins were used up during flagellar agglutination and subsequent cell fusion. When thefus mt ⁺ andmt ^- gametes agglutinated without successive fusion, the amount of cell body-agglutinins sharply decreased, then increased and reached the premixing level: the recovery was blocked by cycloheximide. When cells were treated with EDTA or trypsin, the cell body-agglutinins as well as flagellar surface-agglutinins were completely lost without apparent loss of motility. The EDTA extract contained the same amount of agglutinins as observed in the cell bodies before extraction, and this amount was about 100 times higher than that in the EDTA extract of isolated flagella. By the addition of trypsin inhibitor, the trypsinized gametes resynthesized the cell body-agglutinins. The process was sensitive to cycloheximide in both mating type gametes and to tunicamycin inmt ⁺ gametes.Abbreviations mt ^+/- mating type plus or minus - CHI cycloheximide - TI trypsin inhibitor - TM tunicamycin     

Two tunicamycin-sensitive components involved in agglutination and fusion ofChlamydomonas reinhardtii gametes

To find out glycoproteins involved in the mating reaction ofChlamydomonas reinhardtii, the effect of tunicamycin (TM), a potent inhibitor of glycosylation of proteins, was studied. TM, when present during gametogenesis, blocked the acquisition of agglutinability ofmt ⁺ cells. TM also inhibited the recovery of agglutinability ofmt ⁺ gamete after trypsin treatment. On the contrary, TM blocked neither the acquisition of agglutination during gametogenesis ofmt ^- cells nor the recovery of their agglutinability after trypsinization. It was found, however, that the TM-treatedmt ^- gametes can agglutinate but do not fuse with non treatedmt ⁺ gametes at all. When gametes of gam-1mt ^-, a conditional mutant strain for cell fusion, were induced at non permissive temperature of 35°C and then transferred to 25°C, the ability of cell fusion was acquired after about 5 h incubation. Presence of TM completely blocked this acquisition. Based on these evidence, we conclude that at least two TM-sensitive glycoproteins are included in the mating reaction. The first component is located on the flagellar surface ofmt ⁺ gamete and responsible for agglutination withmt ^- flagella. The second component occurs on the surface ofmt ^- gamete and plays a role in the fusion withmt ⁺ gamete.Abbreviations CHI cycloheximide - mt mating type - TM tunicamycin     

Light dependence of sexual agglutinability in Chlamydomonas eugametos

The mating activity of mating-type plus gametes of Chlamydomonas eugametos depends on light. Cells lost their ability to agglutinate with mating-type minus gametes after a dark period of 30 min. They regained their agglutinability after 10 min exposure to light. Other mating reactions, such as tipping and flagellar tip activation, were not dependent upon light. Since cycloheximide and tunicamycin did not affect the light-induced activation of flagellar agglutinability, no protein synthesis or glycosylation is involved in this process. Equal amounts of biologically active agglutination factor could be extracted from cells placed either in light or in darkness. A minor portion of the active material was found to be located on the flagellar surface of illuminated cells. No active material was found on the flagellar surface of dark-exposed cells, whereas their cell bodies contained the same amount of active material as the cell bodies of illuminated cells. Since a light-induced flow of agglutination factors from the cell body to the flagella could not be detected and dark-exposed cells could be slightly activated by amputation or fixation by glutaraldehyde, we propose that light affects flagellar agglutinability by an in-situ modification of the agglutination factor on the flagella. When mt ⁺ and mt ^- strains were crossed and the progeny examined for light-sensitivity, it was apparent that this phenomenon is not mating type-linked.Abbreviations and symbols FTA flagellar tip activation - mt ^+/- mating type plus or minus - WGA wheat-germ agglutinin     

Eyespot behavior during the fertilization of gametes in Ulva arasakii Chihara (Ulvophyceae, Chlorophyta)

Behavior of the eyespots during the fertilization of Ulva arasakii Chihara was studied using field emission scanning electron microscopy (FE‐SEM). FE‐SEM enabled the visualization of the eyespot of biflagellate male and female gametes. The smaller male gamete has one protruded smaller (1.3 ± 0.15 μm× 1.0 ± 0.29 μm) eyespot and the larger female gamete has a larger (1.6 ± 0.2 μm× 1.1 ± 0.13 μm) one on a posterior position of the cell. The cell membrane over the eyespot region is relatively smooth compared to other parts of the cell body and exhibits hexagonal arranged lipid globules. Because the size of the cell and the morphology of the eyespot are different between male and female gametes, we could follow the fate of the eyespots during the fertilization. The initial cytoplasmic contact and fusion of the gametes takes place at their anterior end, slightly posterior to the flagellar base. The morphology of the fusing gametes followed two clearly distinguishable patterns. About half the gamete pairs lie side‐by‐side with their longitudinal axes nearly parallel, while the rest are oriented anti‐parallel to each other. In all cases, the larger female gamete fused along the same side as the eyespot, while the smaller male gamete fused along the side away from its eyespot. As fusion proceeds, the gamete pair is transformed into the quadriflagellate planozygote, in which the eyespots are positioned side‐by‐side on the region of cell fusion. These observations indicated that the opposite positioning of the eyespot relative to the cell fusion site in male and female gametes is important for the proper arrangement of the eyespots in the planozygote. The significance of this feature in advanced green algae is briefly discussed.     

–SH and S–S involvement in Chlamydomonas mating

Reagents that block or cross-link sulfhydryl (–SH) groups and those that reduce disulfide (S–S) bonds have been tested for their effects on mating in Chlamydomonas reinhardii. Wild-type (wt) gametes of mating type + (mt⁺) and mt^?, and a fusion-defective mt^? mutant, gam-11, were studied. Differential sensitivities of mt⁺ vs mt^? and of wt mt^? vs gam-11 mt^? were analyzed. Concentrations of reagents that did not disrupt flagellar agglutination, the first stage of the mating reaction, were generally used. Pretreatment of mt⁺ gametes with the membrane permeable –SH reducing agent dithiothreitol (DTT) inhibits flagellar sexual signaling at concentrations that do not inhibit any part of the mating reaction of mt^? gametes. Wt mt^? is more sensitive than wt mt⁺ to inhibition by low concentrations of p-chloromercuribenzoate sulfonate (pCMBS), an organic mercurial. The membrane-impermeable reducing agent, reduced glutathione (GSH), also preferentially inhibits wt mt^?. Gam-11 mt^?, a fusion-defective mutant, which has been used to study the sensitivity of the adhesion of the plasma membrane-associated mating structures, is less sensitive to GSH and pCMBS inhibition that is wt mt^?. DDT and pCMBS cause an increase in mating structure adhesion in pretreated gam-11. The differential inhibition of pair and group formation during gam-11 × wt mt⁺ matings has suggested a possible mechanism for mating structure adhesion.     

Sexual agglutination factor from Chlamydomonas eugametos

Chlamydomonas eugametos gametes can sexually agglutinate via their flagellar surfaces whereas vegetative cells cannot. Therefore, flagellar glycoproteins, present in gamete cells but absent from vegetative cells, were investigated as prospective mt ^-agglutination factors. They were identified as periodic acid Schiff (PAS) stained bands separated in sodium dodecyl sulphate-polyacrylamide electrophoresis gels. Gamete-specific bands were determined by comparison with equivalent gels of vegetative flagella and by immunological techniques using antisera raised against isolated mt ^- gamete flagella. Four high molecular weight flagellar glycoproteins proved to be gamete specific (PAS-1.2, PAS-1.3, PAS-3 and PAS-4). They were extracted from flagella by 3 M guanidine thiocyanate, separated in a column of Sepharose 2B, and tested for in vitro agglutination activity on mt ⁺ gametes. A single peak of activity was found to be correlated with the presence of the PAS-1.2 band. It is shown that mt ^- agglutination activity is related to the concentration of this glycoprotein in flagellar membranes.Abbreviations SDS sodium dodecyl sulphate - PAS periodic acid Schiff - GTC guanidine thiocyanate - mt ^-/+ mating type plus or minus     

SEXUALITY AND UNIPARENTAL INHERITANCE OF CHLOROPLAST DNA IN THE ISOGAMOUS GREEN ALGA ULVA COMPRESSA (ULVOPHYCEAE)1

Ulva compressa L. is a heterothallic macroalga considered to be in the early evolutionary stage between isogamy and anisogamy. Two genetic lines of this species, each consisting of gametophytes with opposite mating types, were collected on the coasts of Ehime and Iwate prefectures: MGEC‐1 (mt⁺) and MGEC‐2 (mt^?) from Ehime, and MGEC‐5 (mt⁺) and MGEC‐6 (mt^?) from Iwate. Their relative gamete sizes (i.e., cell volumes) do not correspond to their mating types: MGEC‐6 (19.8 μm³) > MGEC‐1 (18.6 μm³) > MGEC‐5 (17.0 μm³) > MGEC‐2 (10.1 μm³). The pattern of organelle inheritance is an important sexual characteristic in many eukaryotes. We therefore investigated the relationship between gamete size and the inheritance of chloroplast DNA (cpDNA). Polymorphisms between the cpDNA of the two lines were used as markers. We found a 24 bp insertion between psbF and psbL, and the substitution of a StyI site (from C CAAGG to T CAAGG) in the intergenic region between petD and accD. Two interline crosses (MGEC‐1 × MGEC‐6 and MGEC‐2 × MGEC‐5) produced 42 and 38 zygotes, respectively. PCR and PCR–RFLP analyses showed that the cpDNA of the mt⁺ gametes was consistently inherited in both crosses. The cpDNA is inherited from one parent only, and it depends not on gamete size but on being mt⁺. The cpDNA was observed during crossing and in the zygotes 6 h after mating. In 6% of the zygotes, the cpDNA derived from the mt^? gametes disappeared 3–4 h after mating. Preferential digestion of the cpDNA in the zygote’s mt^? gamete may form the basis for uniparental inheritance of cpDNA.     

Study of the release of cell wall degrading enzymes during adhesion of Chlamydomonas gametes

A quantitative assay for cell wall release in Chlamydomonas has been used to study the timing of release of cell wall degrading enzyme (lysin) during adhesion. Lysin activity, which shows a broad pH range and requires divalent cations, is released as a pulse within 1–2 min after mixing of mt^? and mt⁺ gametes. Thereafter, there is no further lysin release. Gametes of both mating types release the activity during aggregation with isolated gametic flagella of the opposite mating type, although mt⁺ gametes appear to release more lysin activity than mt^? gametes. Electrophoretic analysis of cell wall proteins before and after lysin degradation indicate that the major wall proteins are unchanged after wall breakdown.     

Agglutination factor in the cell body of Chlamydomonas eugametos

Chlamydomonas eugametos gametes agglutinate via the surfaces of their flagella. The mating-type minus (mt ^-) agglutination factor is a high-molecular-weight glycoprotein called PAS-1.2, present on the exterior surface of the flagellar membrane. During flagellar regeneration, mt ^- gametes were able to agglutinate as soon as the flagella protruded as short stumps. This was also observed when protein synthesis was blocked, indicating that gametes possess a pool of PAS-1.2. When the exterior surface of flagella-less gametes was extracted and the proteins were subjected to gel electrophoresis, large quantities of PAS-1.2 were detected. Using anti-PAS-1.2 serum, the presence of PAS-1.2-like material was visualized on the plasma membrane of mt ^- gamete cell bodies. By assaying the biological activity of extracts of the cell bodies and of isolated flagella, it was calculated that the plasma membrane of the cell bodies contains 25 times the activity present in the flagella and could, therefore, represent a large pool of mt ^- agglutination factor.     

Light Affects Flagellar Agglutinability in Chlamydomonas eugametos by Modification of the Agglutinin Molecules

The effect of light on the sexual competence of a light-sensitive mating type minus strain (mt⁻) of Chlamydomonas eugametos obtained by crossing a light-sensitive mating type plus strain (mt⁺) with a light-insensitive mt⁻ strain is described. As previously demonstrated for the mt⁺ parent, this study of one of the mt⁻ offspring shows that (a) a light-sensitive mechanism affects flagellar agglutinability in a rapid process that does not require protein synthesis; (b) only the activity of the flagellar agglutinins (glycoproteins responsible for agglutination) is susceptible to light while agglutinins on the cell body surface are not affected by light. We further demonstrate that (a) membrane vesicles naturally released from nonagglutinable dark gametes remain inactive. Extracts of these vesicles also remain inactive even though they contain agglutinin-like components; (b) inactive mt⁻ agglutinin is present in extracts of flagella from nonagglutinable dark gametes by comparison of its chromatographic, electrophoretic, and immunogenic properties with those of active agglutinin. When purified of all other flagellar proteins, it remains inactive; (c) a monoclonal antibody directed against the sexual agglutination site of the mt⁻ agglutintin discriminates between active and inactive agglutinins when present in a native state on the flagellar surface, but is unable to discriminate between them when they are denatured in sodium dodecyl sulfate-electrophoresis gels and blotted onto nitrocellulose. Taken collectively these observations suggest that light activation involves the chemical modification of the agglutinins in situ on the flagellar surface.     

Cyclic AMP is one of the intracellular signals during the mating of Chlamydomonas eugametos

Chlamydomonas eugametos gametes of opposite mating type make cell-cell contact via their flagellar surfaces. This contact triggers an increase in the intracellular level of cyclic AMP (cAMP) and several cellular responses which are necessary for cell fusion. Here, we show that wheat-germ agglutinin, which binds to the flagellar surface and induces all mating responses, also increased the intracellular cAMP level. Dibutyryl-cAMP added to non-mating gametes induced flagellar twitching, cell-wall lysis, mating-structure activation, flagellartip activation and an increase in agglutinability. It did not induce agglutinin transport to the flagellar tip (tipping) and may not be the direct cause of flagellar twitching and flagellar-tip activation. In non-illuminated cells, dibutyryl-cAMP was far more effective in evoking mating reactions than in illuminated cells. Light induced a 50% decrease in the cAMP level within 1 min. Adenylate cyclase was found to be associated with cell membranes but only 8% of the total was present in the gamete flagella.Abbreviations db-cAMP dibutyryl-cAMP - FTA flagellar tip activation - Mab monoclonal antibody - mt ^–/mt⁺ mating-type minus/plus - WGA wheat-germ agglutinin We gratefully acknowledge the fruitful discussions with Dr. Rainer Gilles of the Department of Biochemistry at the University of Cologne (FRG), and the advice generously given by Dr. Roel van Driel of the Department of Biochemistry at the University of Amsterdam (The Netherlands).     

An inhibitor of cell fusion in Chlamydomonas eugametos

By a short treatment with acid of mt ^- gametes of Chlamydomonas eugametos, a factor is released which prevents gametic cell fusion, without affecting the viability of the cells. It has a very rapid action. By means of scanning electron microscopy it is shown that the factor has no influence on flagellar adhesion nor on the formation of a plasma papilla by cells of either mating type, but that it specifically inhibits the fusion of these papillae. Evidence is presented suggesting that this inhibitor has a predominant effect on mt ⁺ gametes. In cell pairs which are blocked with respect to papillar fusion, no flagellar disengagement occurs, which indicates that loss of agglutinability is a direct consequence of cell fusion.     

FINE STRUCTURE OF THE MALE AND FEMALE GAMETES OF ATRACTOMORPHA PORCATA (SPHAEROPLEACFAE,CHLOROPHYTA) WITH EMPHASIS ON THE DEVELOPMENT AND ABSOLUTE CONFIGURATION OF THE FLAGELLAR APPARATUS1

Gametogenesis in Atractomorpha porcata Hoffman was initiated b the synchronous mitotic division of nuclei within a multinucleate gametangium. Uninucleate gametes were subsequently produced following two series of cytokinetic divisions. The first series involved the formation of phycoplast microtubules (phycoplastic cytokinesis), whereas the second series did not (nonphycoplastic cytokinesis). Centrioles were connected by a rudimentary striated distal fiber by the time they migrated to the planes of division preceding the first series of cytokinetic division. These first divisions produced binucleate gametocytes. A well-developed flagellar apparatus lay near the cell surface in close proximity to each nucleus of the gametocyte prior to the second series of cytokinetic divisions that produced the uninucleate gametes. As seen in apical view, the paired basal bodies were directly opposed, with no lateral displacement of their longitudinal axes. In lateral view, the paired basal bodies diverged from one another at an angle of 130–180° (female) or 170–180° (male) and were connected by an arched, distal striated fiber about 670–750 nm long and 600 nm at its widest part. Four electron-opaque, pyramid-shaped lateral bodies flanked the basal bodies in close contact with their undersurfaces. The flagellar roots demonstrated a cruciate arrangement, with s = 6–9 over 1 (female gametes) or 7–10 over 1 (male gametes) microtubules and d= 2 microtubules. In male gametes, one of the multistranded roots was located close to the eyespot, and a second system of cytoskeletal microtubules was detected internally. Based on gamete ultrastructure, Atractomorpha porcata appears to be the most undifferentiated member of the genus.     

The relationship of flagellar length to sexual signalling in Chlamydomonas

The flagella of Chlamydomonas reinhardi are required for the initiation of mating between opposite mating type gametes. It has been suggested that flagellar length is a crucial factor in a cell's ability to transmit and receive the sexual signals necessary for fusion. Mating type + (mt⁺) cells of gam-5, a mutant which is characterized by variable length, paralyzed flagella, were mated with wild-type, mt⁻ cells. Activation of the mating structures of the gam-5 gametes, and therefore successful signalling, was demonstrated for cells with flagella as short as 1.5 μm (less than 1/6 normal length). Because this mutant displays aberrant axonemal structures, and because various mutants with other defects in axonemal structure are also able to mate, it seems likely that the flagellar membrane may provide the main conduit for gametic sexual signals.     

Sexual reproduction and sex determination in green algae

The sexual reproductive processes of some representative freshwater green algae are reviewed. Chlamydomonas reinhardtii is a unicellular volvocine alga having two mating types: mating type plus (mt⁺) and mating type minus (mt^?), which are controlled by a single, complex mating-type locus. Sexual adhesion between the gametes is mediated by sex-specific agglutinin molecules on their flagellar membranes. Cell fusion is initiated by an adhesive interaction between the mt⁺ and mt^? mating structures, followed by localized membrane fusion. The loci of sex-limited genes and the conformation of sex-determining regions have been rearranged during the evolution of volvocine algae; however, the essential function of the sex-determining genes of the isogamous unicellular Chlamydomonas reinhardtii is conserved in the multicellular oogamous Volvox carteri. The sexual reproduction of the unicellular charophycean alga, Closterium peracerosum-strigosum-littorale complex, is also focused on here. The sexual reproductive processes of heterothallic strains are controlled by two multifunctional sex pheromones, PR-IP and PR-IP Inducer, which independently promote multiple steps in conjugation at the appropriate times through different induction mechanisms. The molecules involved in sexual reproduction and sex determination have also been characterized.     

Evidence for a functional membrane barrier in the transition zone between the flagellum and cell body of Chlamydomonas eugametos gametes

Evidence is presented which supports the concept of a functional membrane barrier in the transition zone at the base of each flagellum of Chlamydomonas eugametos gametes. This makes it unlikely that agglutination factors present on the surface of the cell body can diffuse or be transported to the flagellar membrane. The evidence is as follows: 1) The glycoprotein composition of the flagellar membrane is very different to that of the cell-body plasma membrane. 2) The flagella of gametes treated with cycloheximide, tunicamycin or , -dipyridyl become non-agglutinable but the source of agglutination factors on the cell body is not affected. 3) Even under natural conditions when the flagella are non-agglutinable, for example in vis-à-vis pairs or in appropriate cell strains that are non-agglutinable in the dark, the cell bodies maintain the normal complement of active agglutinins. 4) When flagella of living cells are labeled with antibodies bound to fluorescein, the label does not diffuse onto the cell-body surface. 5) When gametes fuse to form vis-à-vis pairs, the original mating-type-specific antigenicity of each cell body is slowly lost (probably due to the antigens diffusing over both cell bodies), while the specific antigenicity of the flagellar surface is maintained. Even when the flagella of vis-à-vis pairs are regenerated from cell bodies with mixed antigenicity, the antigenicity of the flagella remains matingtype-specific. 6) Evidence is presented for the existence of a pool of agglutination factors within the cell bodies but not on the outer surface of the cells.Abbreviations and symbols CHI cycloheximide - GTC guaniline thiocyanate - mt ⁺/mt ^- mating type plus or minus - PAS Periodic-acid-Schiff reagent - SDS sodium dodecyl sulphate