SEXUAL PROCESSES AND PHYLOGENETIC RELATIONSHIPS OF A HOMOTHALLIC STRAIN IN THE CLOSTERIUM PERACEROSUM–STRIGOSUM–LITTORALE COMPLEX (ZYGNEMATALES,CHAROPHYCEAE)1

Members of the Closterium peracerosum–strigosum–littorale (C. psl.) complex are unicellular charophycean algae in which there are two modes of zygospore formation, heterothallic and homothallic. A homothallic strain of Closterium (designation, kodama20) was isolated from a Japanese rice paddy field. Based on alignment of the 1506 group‐I introns, which interrupt nuclear SSU rDNAs, homothallic kodama20 is most closely related to the heterothallic mating group II‐B, which is partially sexually isolated from group II‐A. Time‐lapse photography of the conjugation process in kodama20 revealed that most of the observed zygospores originated from one vegetative cell. The sexual conjugation process consisted of five stages: (1) cell division resulting in the formation of two sister gametangial cells from one vegetative cell, (2) formation of a sexual pair between the two sister gametangial cells (or between gametangial cells of another adjoined individual), (3) formation of conjugation papillae, (4) release of gametic protoplasts from both members of a pair, and (5) formation of the zygospore by protoplast fusion. For conjugation to progress, the cell density and light condition in the culture was critical. We suggested the presence of a conjugation promotion factor.     

Zygospore formation between homothallic and heterothallic strains of Closterium

Zygospore formation in different strains of the Closterium peracerosum-strigosum-littorale complex was examined in this unicellular isogamous charophycean alga to shed light on gametic mating strains in this taxon, which is believed to share a close phylogenetic relationship with land plants. Zygospores typically form as a result of conjugation between mating-type plus (mt⁺) and mating-type minus (mt⁻) cells during sexual reproduction in the heterothallic strain, similar to Chlamydomonas. However, within clonal cells, zygospores are formed within homothallic strains, and the majority of these zygospores originate as a result of conjugation of two recently divided sister gametangial cells derived from one vegetative cell. In this study, we analyzed conjugation of homothallic cells in the presence of phylogenetically closely related heterothallic cells to characterize the reproductive function of homothallic sister gametangial cells. The relative ratio of non-sister zygospores to sister zygospores increased in the presence of heterothallic mt⁺ cells, compared with that in the homothallic strain alone and in a coculture with mt⁻ cells. Heterothallic cells were surface labeled with calcofluor white, permitting fusions with homothallic cells to be identified and confirming the formation of hybrid zygospores between the homothallic cells and heterothallic mt⁺ cells. These results show that at least some of the homothallic gametangial cells possess heterothallic mt⁻-like characters. This finding supports speculation that division of one vegetative cell into two sister gametangial cells is a segregative process capable of producing complementary mating types.     

SEX PHEROMONES THAT INDUCE SEXUAL CELL DIVISION IN THE CLOSTERIUM PERACEROSUM–STRIGOSUM–LITTORALE COMPLEX (CHAROPHYTA)1

Sexual cell division (SCD) that produces two gametangial cells from one vegetative mother cell is the first step observed morphologically in the sexual reproduction in the Closterium peracerosum–strigosum– littorale complex. SCD‐inducing activities specific for each mating‐type cells were detected in the medium in which both mating type cells has been cocultured. Mating‐type minus (mt ^? ) cells released SCD‐inducing substance specific for mating‐type plus (mt ⁺ ) cells and were designated as SCD‐ inducing pheromone (IP)‐minus, whereas mt ^? specific substances released from mt ⁺ cells were designated as SCD‐IP‐plus. Culture medium was subjected to gel filtration, and then SCD‐IP‐plus and SCD‐IP‐minus chemical were found to have the molecular masses of 90–100 kDa and 10–20 kDa, respectively. It was evident that light was imperative for this type of signaling. Gametangial cells of both mating types were obtained from vegetative cells by treatment with SCD‐IPs. Gametangial mt ⁺ cells showed high competency for conjugation with vegetative mt ^? cells, whereas gametangial mt ^? cells showed low competency for conjugation with vegetative mt ⁺ cells. These results indicate that SCD in both mating type cells is induced by high molecular weight sex pheromones and that the roles of gametangial cells in the process of conjugation differ by sex.     

Improved mating efficiency inAcetabularia acetabulum: recovery of 48–100% of the expected zygotes

Summary We have improved zygote recovery 11–1,000 fold by optimizing the physiology of gamete release and mating inAcetabularia acetabulum. Gamete release was affected by agar purity, concentration, and volume/gametangial pair. Cold pre-treatment of gametangia (14–30 d at 10°C in the dark) synchronized subsequent gamete release at 21°C in the light. Cold pre-treatment was nearly twice as effective in synchronizing subsequent gamete release when intact, gametangia-bearing caps rather than isolated gametangia were pretreated. Synchronizing gamete release doubled mating efficiency. In a wild-type laboratory strain ofA. acetabulum, there were 1,561±207 gametes/gametangium which had half-lives of 14.5 d in 0.1% seawater-agar. We recovered 48–93% of the expected numbers of zygotes from a mass mating of 8 to 1,226 gametangia and 11–128% of the expected numbers of zygotes from mating single gametangial pairs: the large range in the calculated mating efficiency may be attributable to the variation in the numbers of gametes made per gametangium. Zygote recovery from single gametangial pairs was highly dependent on the volume of mating matrix. In addition, most zygotes recovered were unattached to any other zygotes in the subsequent generation (> 95% single cells from matings of 1–500 gametangial pairs). Our improvements in mating conditions and zygote recovery (1) have facilitated cell manipulation and culture ofA. acetabulum in the laboratory; and (2) have made controlled crosses for selection and genetic analysis of mutants feasible. These advances have removed a major barrier to genetic analysis of development inAcetabularia.Abbreviations LB Luria-Bertani bacteriological broth - SE standard error of the mean - T_g agar gelling temperatures - DAPI 4,6-diamidino-2-phenylindole     

TIME LAPSE ANALYSES OF SEXUAL REPRODUCTION IN CLOSTERIUM EHRENBERGII (CONJUGATOPHYCEAE)1

The process of sexual differentiation was studied using heterothallic clones of Closterium ehrenbergii Meneghini. The first visible sign of sexual reproduction was agglutination of two or more cells in a group and this was followed by gametangiogenic division and conjugation of gametangial cells. Movements of gametangial cells were carefully studied. Gametangial cells occasionally participated again in gametangiogenesis instead of proceeding directly to the formation of conjugation papilla. The whole process of sexual differentiation from vegetative cell to zygospore was considered to be basically similar in both of the two closely related mating groups, A and B, of C. ehrenbergii. Nevertheless, there were some differences between the two groups in patterns of the sexual differentiation. In Group A, vegetative cell division was completely suppressed by mixing the two complementary mating type clones together into the same medium with high light illumination. This suppression was not caused by the nitrogen depletion in the medium, but by the presence of cells of opposite mating type. In Group B, vegetative cell division and sexual reproduction occurred side by side repeatedly for several days.     

Dissection of conjugants and mating type plus and minus cells in selfing clones of the isogamous green alga Closterium ehrenbergii

In the sexual reproduction of the green alga Closterium ehrenbergii, two sexually competent cells that are morphologically indistinguishable from the vegetative cells first come close to each other to form a sexually interacting pair. Each then divides into two gametangial cells. Isogamous conjugation occurs between nonsister gametangial cells of the two resulting pairs. With unusual selfing clones derived from a certain cross of heterothallic strains, we dissected apart a pair of gametangial cells that had already been united together by a delicate transparent tube, into which each gametangial cell was going to develop its conjugation papilla. In spite of such a degree of differentiation, when each was cultured in fresh medium, individual gametangial cells could dedifferentiate into vegetative cells and form subclones. By crossing such subclones with standard stable heterothallic mating-type strains, we show that each selfing clone of this alga actually produces both stable mt ⁺ and stable mt ^- cells, in addition to unstable mt ^- cells with selfing potency, during its mitotic vegetative growth. Although the selfing in C. ehrenbergii studied here differs in certain points from true homothallism, the results of the present study provide insight into how homothallism might have evolved from heterothallism.     

Purification and characterization of a pheromone that induces sexual cell division in the unicellular green alga Closterium ehrenbergii

Closterium ehrenbergii is a unicellular charophycean alga consisting of two sexes: mating type plus (mt⁺) and minus (mt^–). The sexual reproductive process consists of five steps: formation of sexual pairs, cell division of each member of a pair, formation of conjugation papillae, release of protoplasts from gametangial cells, and fusion of protoplasts to form a zygote. The second step, called sexual cell division (SCD), produces two gametangial cells from one vegetative mother cell. The SCD of mt⁺ cell is mediated by a diffusible sex pheromone, named SCD-inducing pheromone (SCD-IP). This pheromone is released from mt^– cells in the light, and the presence of mt⁺ cells stimulates its secretion from mt^– cells. SCD-IP was purified by sequential column-chromatographic fractionation from culture medium in which both mating type cells had been co-cultured. Purified SCD-IP is a glycoprotein with an apparent molecular mass of 20 kDa. The molecular mass of the SCD-IP was estimated to be 18 kDa by mass spectrometry. Amino-terminal and two internal amino acid sequences of the pheromone revealed significant similarity to another Closterium pheromone, protoplast release-inducing protein (PR-IP) inducer of Closterium peracerosum-strigosum-littorale complex (C. pslc). These two pheromones induced different morphological reactions in each Closterium species. Based on these results, the diversity of sex pheromones is discussed.     

Studies on conjugation of <Emphasis Type="Italic">Spirogyra</Emphasis> using monoclonal culture

We succeeded in inducing conjugation of Spirogyra castanacea by incubating algal filaments on agar plate. Conjugation could be induced using clone culture. The scalariform conjugation was generally observed, while lateral conjugation was rarely. When two filaments formed scalariform conjugation, all cells of one filament behaved as male and those of other filament did as female. Very rarely, however, zygospores were formed in both of pair filaments. The surface of conjugation tube was stained with fluorescently labeled-lectins, such as Bandeiraea (Griffonia) simplicifolia lectin (BSL-I) and jacalin. BSL-I strongly stained the conjugation tubes, while weakly did the cell surface of female gamete first and then that of male gamete. Jacalin stained mainly the conjugation tubes. Addition of jacalin inhibited the formation of papilla, suggesting some important role of jacalin-binding material at the initial step of formation of the conjugation tubes.     

Sexual reproduction inEudorina elegans (chlorophyta,volvocales)

Sexual reproduction inEudorina elegans Ehr. was studied in detail in laboratory cultures, with particular regard to conjugation between gametes and gone colony formation. Male and female gametes fused after being induced by changing the medium. The anterior end, including the flagellar base, of the male gamete entered the anterior region of the female gamete. Fusion of the two protoplasts proceeded laterally and posteriorly. The male gamete bore a slender cytoplasmic protrusion at the base of the flagella. This structure has not been previously described in the male gamete ofEudorina, and may participate in plasmogamy. A biflagellate gone cell swam from the germinating zygote and secreted a gelatinous envelope. It then divided to form a gone colony within the gelatious envelope, which moved during colony formation by means of the two flagella which were retained intact from the original gone cell.     

Properties of cell surface carbohydrates in sexual reproduction of the Closterium peracerosum–strigosum–littorale complex (Zygnematophyceae,Charophyta)

The Closterium peracerosum–strigosum–littorale complex is a best characterized zygnematophycean green alga with respect to the process of sexual reproduction. Intercellular communication mediated by two sex pheromones has been well documented in this organism, but information concerning direct cell–cell recognition and fusion of cells involved in conjugation processes has not yet been clarified. In this study, we examined the properties of cell surface carbohydrates in vegetative and reproductive cells using a variety of fluorescein isothiocyanate labeled lectins as probes. Among 20 lectins tested, 10 bound to the Closterium cell surface, and eight of these were specific for the cells involved in sexual reproduction. In addition, some of the lectins inhibited the progress of zygote formation. In particular, Lycopersicon esculentum lectin (LEL) and ConcanavalinA (ConA) considerably inhibited zygote formation (23.6% and 0% of zygotes formed, respectively, compared with the control). LEL mainly accumulated on conjugation papillae and on the surface and lumens of empty cell walls remaining after zygote formation. ConA bound to both vegetative and sexually reproductive cells and strongly accumulated on the conjugation papillae of the latter, indicating ConA binding material(s) are non‐specifically present in Closterium cells but some of the material(s) would be essential for zygote formation. These results suggest that different carbohydrates specifically recognized by these lectins are involved in cell recognition and/or fusion during conjugation processes in the C. psl. complex.     

Physiological characterization of the sex pheromone protoplast-release-inducing protein from the Closterium peracerosum-strigosum-littorale complex (Charophyta)

In the unicellular charophycean alga Closterium peracerosum‐strigosum‐littorale complex, the protoplast‐release‐inducing protein (PR‐IP), a sex pheromone responsible for gametic protoplast release from mating‐type minus (mt^–) cells, was found to stimulate secretion of mucilage from the cells. Induction of sexual cell division by PR‐IP was also confirmed. Bioassays were used to determine the minimum doses required to induce these functions, revealing that 5 · 10^?16 M of PR‐IP stimulated mucilage secretion, and that 5 · 10^?10 M of PR‐IP were required for protoplast release. Exposure of the cells to 5 · 10^?11 M of PR‐IP resulted in the induction of sexual cell division as well as mucilage secretion. These results strongly suggest that PR‐IP is a multifunctional pheromone that independently promotes multiple steps in conjugation at the appropriate times through different induction mechanisms.     

Nuclear functions in postconjugational development of Paramecium caudatum: Ability to form food vacuoles analyzed by nuclear elimination and implantation

Paramecium caudatum loses the ability to form food vacuoles at the crescent stage of the micronucleus from 5 to 6 hr after the initiation of conjugation and regains it immediately after the third division of the zygotic nucleus. To assess the micronuclear function in the development of the oral apparatus after coniugation, prezygotic micronuclei was removed from cells at various stages of conjugation, and their ability to form food vacuoles were examined. (1) When all of the prezygotic micronuclear derivatives were eliminated before the stage of formation of the zygotic nucleus, the exconjugant did not regain its ability. (2) When a zygotic nucleus or postzygotic nuclei were removed, in some cases the cell formed as many food vacuoles as did nonoperated cells after conjugation, while in other operated cells the number of food vacuoles was subnormal. (3) When a micronucleus from a cell at vegetative phase (G1) was transplanted into a cell of an amicronucleate mating pair at the stage between 8 and 9 hr after the initiation of conjugation, the implanted cell regained the ability to form food vacuoles. However, no cell regained the ability when the implantation was carried out within 1 hr after the separation of the mates. The results show that the micronucleus plays an indispensable role in the development of the oral apparatus at the stages of exchange of gametic nuclei and fertilization and that the micronucleus transplanted from asexual cells can fulfill this function. On the other hand, removal of the macronucleus from exconjugants showed that the maternal macronucleus also has an indispensable function in regaining the ability to form food Vacuoles. © 1992 Wiley-Liss, Inc.     

Sexual auxosporulation of the marine diatom Navicula directa var. directa

Sexual auxosporulation was observed in a mixed culture of two strains of Navicula directa var. directa. Two gametes did not re‐arrange in their gametangium and each adhered to the inner surfaces of the gametangial theca. Each of the two gametes of one gametangium fused with a gamete of the other gametangium iso‐gamously. As a result, two zygotes and hence two auxo‐spores were produced per paired gametangia. As the gametangial thecae kept close to the gametes during fusion, the zygote became associated with two different thecae. The presence of type IB2a of Geitler's (1973) system was confirmed by the present observations.     

CULTURE STUDIES ON THE MARINE GREEN ALGA HALICYSTIS PARVULA—DERBESIA TENUISSIMA. II. SYNCHRONY AND PERIODICITY IN GAMETE FORMATION AND RELEASE

Unialgal cultures of the macroscopic, vesicular, coenocytic gametophyte (Halicystis parvula Schmitz) of Derbesia tenuissima (DeNotaris) Crouan fr. were grown under various environmental regimes to elucidate the cytology of gamete formation and the factors controlling synchronous gamete formation and release. No synchrony of nuclear division was observed in vegetative plants or during the early stages of gamete formation. In the later stages of gamete formation in plants in a light-dark cycle, nuclear divisions within any gametangium were synchronous, and the stages of gamete formation were synchronous for the population. This synchrony was not as great for plants in continuous light. Gametes of plants in a light-dark cycle were released explosively immediately following the dark-to-light transition. Release was random and much less forceful for plants in continuous light. After a certain stage of gamete formation, gamete release was timed to occur after a particular interval of darkness, but release could be triggered by light during the last portion of this interval. The length of the dark interval was shorter for male plants than for females, but the period of light sensitivity was longer for females. Formation of gametangia by series of isolated plants was also synchronous and sometimes periodic under certain conditions. Intervals between gametangia on the same plant varied from 2 to 14 days but were usually 4 or 5 days (unlike plants in nature, which show a bi- or tri-weekly periodicity). Male and female plants did not differ in synchrony or periodicity. Different media affected the number of gametangia formed over a period of time but not the synchrony of formation. Under some conditions changing the medium had a stimulating or synchronizing effect. Non-repeated temperature changes also synchronized gamete formation. Optimum temperature for continued gamete formation was about 21 C. Regular daily light and temperature variation together maintained synchronous and periodic gamete formation in populations of isolated plants. Reproduction diminished and became less synchronous at constant temperature either in continuous light or under a light-dark schedule, although in the light-dark regime steps in the formation of any given gametangium remained synchronous with the light-dark cycle. Length of times between gametangial formation on individual plants showed a tendency to occur in multiples of the usual period lengths; e.g., plants sometimes tend to “skip” intervals, thus maintaining the synchrony of the population. These results suggest that interaction between daily environmental cycles and an endogenous physiological cycle may maintain periodic reproduction.     

Changes in osmotic pressure and structure at the initial stages of zygote formation inClosterium ehrenbergii

Summary The behavior of gamete cells ofClosterium ehrenbergii in hypertonic solutions was observed and the significance of changes in osmotic pressure of the protoplasts is discussed in relation to zygote formation. The osmotic pressure of fusing gamete protoplasts was calculated to be 0.063 Osm at the original cell volume. The osmotic pressure of immature gamete protoplasts was 0.24 Osm at incipient plasmolysis. This lowering of cell osmotic pressure may serve to protect the rupture of the plasma membrane during migration of protoplasts in the conjugation tube after dissolution of cell walls. During maturation of gamete cells, chloroplasts and dictyosomes differed greatly in their ultrastructure from those of vegetative cells. These structural changes may be induced by changes of the physiological condition including osmotic pressure in the cells.     

PHYLOGENY OF SPIROGYRA AND SIROGONIUM (ZYGNEMATOPHYCEAE) BASED ON RBCL SEQUENCE DATA1

DNA sequence data were obtained for the gene encoding the large subunit of RUBISCO (rbcL) from 26 strains of Spirogyra and seven of Sirogonium, using as outgroups 10 genera in the Zygnematales and Desmidiales (Closterium, Cosmarium, Cylindrocystis, Gonatozygon, Mesotaenium, Netrium, Penium, Zygnema, Zygnemopsis, Zygogonium). Sequence data were analyzed using maximum parsimony (MP), maximum likelihood (ML), and Bayesian inference (BI), with bootstrap replication (MP, ML) and posterior probabilities (BI) as measures of support. MP, ML, and BI analyses of the rbcL data strongly support a single clade containing Spirogyra and Sirogonium. The Spirogyra taxa are monophyletic, with the exception of Spirogyra maxima (Hassall) Wittrock, which is nested within a clade with Sirogonium and shares with them the characters of loosely spiraled chloroplasts (<1 complete turn per cell) and anisogamy of gametangial cells; S. maxima differs from Sirogonium in displaying well‐defined conjugation tubes rather than a tubeless connection involving bending (genuflection) of filaments. The ML and BI analyses place this Sirogonium/Spirogyra maxima clade sister to the remaining Spirogyra. Morphological differences among strains of Spirogyra grouped together on the basis of rbcL data, including laboratory strains derived from clonal cultures (Spirogyra communis, S. pratensis), indicate that some characters (filament width, chloroplast number) used in the traditional taxonomy of this group are poor measures of species identity. However, some characters such as replicate end walls and loose spiraling of chloroplasts may be synapomorphies for Spirogyra clades.     

四膜虫S1有性生殖的电镜观察Ⅱ.接合区的形态与配子核的交换

四膜虫接合膜上的小孔是两接合体细胞质相连的通道。配子核形成后,按合膜由于增生而出现装有细胞器等的囊状折叠,并可脱离下来而落入另一细胞中,这可能是胞质交流的又一途径。配子核的交换不是从膜上原有小孔通过的,而是在溶酶体等作用下、使膜破裂,由核后方的微管推动进入对侧细胞中。 本文记述了四膜虫S1有性生殖过程中接合区的形态和配子核的交换。     

NUTRITIONAL REQUIREMENTS FOR SEXUAL REPRODUCTION IN MESOTAENIUM KRAMSTAI (CHLOROPHYTA) 1

Optimum conditions for conjugation in the heterothallic saccoderm desmid Mesotaenium kramstai Lemmer-mann have been determined. In culture, cells acquired the ability to form gamete pairs just prior to the onset of stationary phase after sufficient nitrate had been depleted from the medium. The appearance of potential gametes was delayed by increasing the concentration of KNO₃ When cells of both mating types were harvested from 15 to 18 day old cultures, washed, resuspended in fresh medium, and mixed, approximately 50 percent of the cells paired (measured three days after mixing) in a medium containing 0.13 mM or less KNO₃. At greater concentrations, fewer pairs formed; no pairs formed in medium containing 0.5 mM KNO₃. Conjugation was not inhibited by other macronutrients. Calcium and magnesium were essential for maximum conjugation. Although Ca²⁺ and Mg²⁺ contentrations of 0.05 mM and 0. I mM, respectively, were sufficient for optimum growth, maximum conjugation required more than 10 times these values. Few gamete pairs formed when either Ca²⁺ or Mg²⁺ was omitted from the medium, no pairing occurred when both Ca²⁺ and Mg²⁺ were omitted.     

THE ULTRASTRUCTURE OF DERBESIA TENUISSIMA (DE NOTARIS) CROUAN. I. ORGANIZATION OF THE GAMETOPHYTE PROTOPLAST,GAMETANGIUM, AND GAMETANGIAL PORE1,2,3

The fine structure of vegetative and reproductive gametophytes of Derbesia tenuissima is described. Development of the gametangium and release of the gametes progress as follows: (1) In initial stages of gametangium formation, prior to 24 hr before gamete release, there is an accumulation and proliferation of nuclei, chloroplasts, and other organelles. (2) This is followed by separation of the gametangium from the rest of the plant by a gametangial membrane; segregation of organelles into gametes has begun by 12 hr before release and the process is completed by 2.5 hr before release. (3) Enzymatic wall dissolution of the pore area occurs between 2.5 and, 12 hr before normal lights-on time. (4) The release mechanism appears to be an instantaneous light-induced increase in lurgor pressure rupturing the weakened pore area, of the wall and causing a forcible expulsion of the gametes. (5) Following release, the pore is sealed by organellar debris and the gametangial membrane. Additional wall layers are presumed to be laid down internal to the plugged pore by the vegetative protoplasm which migrates into the area.     

THE OOGONIA OF MACROALGA UNDARIA PINNATIFIDA ARE ALKALINE‐PHOSPHATASE POSITIVE AND CONTAIN GERMINAL BODY‐LIKE STRUCTURES1

It was observed that in the female gametophyte of Undaria pinnatifida (Harv.) Suringar (Phaeophyta, Laminariales) gametangial initials and maturing oogonia demonstrated different levels of alkaline‐phosphatase activity (APA). The oogonia exhibited a higher level of APA than in its initials. Electron‐dense granular ovoid structures ～0.5–0.6 μm were present in the cytoplasm of oogonia. These inclusions were not membrane bound and do not appear to be associated with any particular organelles. The number of the inclusions was 1 to 2 in a single section of the cell. In essential details, the specific APA and subcellular germinal body‐like structure of the developing female gamete in U. pinnatifida were very similar to those in metazoan oocytes.