ANALYSIS OF GAMETIC PROTOPLAST RELEASE IN THE CLOSTERIUM PERACEROSUM-STRIGOSUM-LITTORALE COMPLEX (CHLOROPHYTA)1

A biologically active glycoprotein (protoplast-release-inducing protein; PR-IP), which induces the release of gametic protoplasts from mating type minus (mt^-) cells of the Closterium peracerosum-strigosum-littorale complex, was prepared from a medium in which mt^- and mt⁺ cells had been previously incubated together. The process of PR-IP-inducing protoplast release was analyzed. Induction of protoplast release was dependent upon the duration of both PR-IP treatment and preincubation in nitrogen-deficient mating medium before PR-IP treatment. Low cell density in the preculture stage had a significant stimulative effect upon the induction of protoplast release. Light was necessary for protoplast release, especially just before PR-IP treatment. Chloramphenicol and 3-(4-chlorophenyl)-1,1-dimethylurea (CMU) exerted inhibitory effects on protoplast release, especially when they were applied to the preculture stage but not when they were applied to the protoplast-releasing stage after the PR-IP treatment. We suggest that preculture at a low cell density under continuous light conditions that may cause metabolic changes in the chloroplast is a very important stage for gametic protoplast release in this Closterium.     

Analysis of binding of biotinylated protoplast-release-inducing protein that induces release of gametic protoplasts in the Closterium peracerosum-strigosum-littorale complex

A protoplast-release-inducing protein (PR-IP) which is released from mating-type plus (mt⁺) cells and induces the release of gametic protoplasts from matingtype minus (mt⁻) cells of Closterium was biotinylated and then used to examine the interaction of this protein with mt⁻ cells. The protoplast-release-inducing activity of PR-IP was not altered after the biotinylation. When mt⁻ cells that had been pre-cultured for 24 h were incubated with biotinylated PR-IP for 6 h in nitrogen-deficient medium that contained 1% (w/v) bovine serum albumin, and then washed with the same medium, only a 19-kDa polypeptide, the smaller subunit of PR-IP, was detected in cells by the avidin and biotinylated horseradish-peroxidase macromolecular complex system. The amount of bound 19-kDa polypeptide increased with increasing doses of PR-IP and reached a maximum at around 10 nM, reflecting the protoplast-release-inducing activity. From a Scatchard plot, the dissociation constant of the polypeptide was calculated to be 2.7 · 10⁻⁸ M. The binding of the polypeptide proceeded only after an appropriate period of pre-culture in the light, and the polypeptide was competitively displaced by non-biotinylated PR-IP. From these results, it appears that the PR-IP induces the release of protoplasts from mt⁻ cells by binding of a polypeptide of relative molecular mass 19000 to the receptor on the cell surface in a manner analogous to the binding of peptide hormones in animals.     

Detection and Evaluation of an Inducer of a Diffusible Mating Pheromone of the Heterothallic Closterium peracerosum-strigosum-littorale Complex

When mating-type plus cells of the Closterium peracerosum-strigosum-littoralecomplex were incubated in nitrogen-deficient medium obtainedfrom a 24-h-old mixed culture of mating-type plus and mating-typeminus cells, protoplast-release-inducing activity specific formating-type minus cells was detected in the medium. When mating-typeplus cells were incubated in the medium from a culture of exclusivelymating-type minus cells, protoplast-release-inducing activitywas also detected. These results suggested the existence ofa substance, released from mating-type minus cells, that hasthe ability to make mating-type plus cells release protoplast-release-inducingprotein (PR-IP). We designated it PR-IP Inducer. The PR-IP Inducerwas constitutively released from mt^– cells in the light.The PR-IP Inducer was heat-labile and had a relative molecularweight of 10,000 on gel filtration. We suggest that the PR-IPInducer is also a pheromonal substance that plays a role inthe initial events in the sexual communication of this Closteriumcomplex. (Received April 26, 1993; Accepted July 15, 1993)     

Biochemical and physiological properties of a protein inducing protoplast release during conjugation in theClosterium peracerosum-strigosum-littorale complex

When mating-type minus (mt⁻) and plus (mt⁺) cells of theClosterium peracerosum-strigosum-littorale complex were mixed together in a nitrogen-deficient mating medium, cells of both types released protoplasts, this release being the first step in the process of conjugation. Release of protoplasts by mt⁻ cells also proceeded without pairing in a medium in which mt⁻ and mt⁺ cells had previously been cultured together. A protein with the ability to induce the release of protoplasts was purified from this medium by sequential column-chromatographic steps, and named PR-IP (protoplast-release-inducing protein). The PR-IP had an apparent molecular mass (M_r) of 95000 on gel filtration and could be separated into several isoforms by anion-exchange chromatography. Each isoform consisted of two glycopolypeptides of M_rs 42000 and 19000, while the deglycosylated polypeptides had M_rs of 34000 and 18000, respectively. From an analysis of dose-response curves, the numbers of PR-IP molecules required for the release of a protoplast by a single cell was calculated as 1.5·10⁹ and the concentration required for 50% of the maximum response (ED₅₀) as 4.1·10⁻⁹M. We suggest that the PR-IP is a biologically active glycoprotein which induces the release of gametic protoplasts from mt⁻ cells of thisClosterium complex.     

Production and secretion of a biologically active Closterium sex pheromone by Saccharomyces cerevisiae

The cDNA fragment coding for the Closterium sex pheromone (protoplast-release-inducing protein inducer, PR-IP inducer) was inserted into a Saccharomyces cerevisiae–Escherichia coli shuttle vector, under the control of the glucose-repressible alcohol dehydrogenase (ADH2) promoter of yeast. The yeast cells transformed by this construct produced and secreted recombinant PR-IP inducer into the surrounding culture medium. The release of PR-IP from mt⁺ cells was induced by the recombinant pheromone, whereas amino- and carboxy-terminal truncated forms did not show any biological activity. High levels of asparagine-linked glycosylation in the recombinant pheromone were also confirmed after the treatment by deglycosylation enzymes.     

Mucilage secretion regulated by sex pheromones in Closterium peracerosum-strigosum-littorale complex

When mating-type plus (mt+) and minus (mt-) cells of the Closterium peracerosum-strigosum-littorale complex were mixed in nitrogen-depleted mating medium, secretion of mucilage containing uronic acid from cells was markedly activated and the mucilage accumulated around the cells. Substances with the ability to stimulate mucilage secretion from mt+ and mt- cells were detected in media in which mt- and mt+ cells had been separately cultured, respectively. We designated the active substances secreted from mt+ and mt- cells mucilage secretion-stimulating pheromone (MS-SP)-plus and MS-SP-minus, respectively. Activity of MS-SP-plus and MS-SP-minus decreased to 20% level by incubation at 80 degrees C for 10 min. Light was indispensable for the secretion of mucilage. The secretion of MS-SP-plus and MS-SP-minus decreased with dark treatment. MS-SP-plus eluted at around 95 k from a gel filtration column, and reacted with antibodies against two subunits of protoplast-release-inducing protein (PR-IP), which induces protoplast release from mt- cells. MS-SP-minus eluted at around 20 k from a gel filtration column, and reacted with an antibody against the PR-IP inducer, which induces the secretion of PR-IP from mt+ cells. In addition, purified PR-IP and PR-IP inducer stimulated mucilage secretion from mt- and mt+ cells, respectively. These results strongly suggested that MS-SP-plus and MS-SP-minus were the same molecules as the PR-IP and the PR-IP inducer, respectively.     

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.     

Identification of a new mating group and reproductive isolation in the <Emphasis Type="Italic">Closterium peracerosum–strigosum–littorale</Emphasis> complex

Reproductive isolation is essential for the process of speciation. In order to understand speciation, it is necessary to compare one mating group with other phylogenetically related but reproductively isolated groups. The Closterium peracerosum–strigosum–littorale (C. psl.) complex is a unicellular isogamous zygnematophycean alga, which is believed to share a close phylogenetic relationship with the land plants. In this study, we identified a new mating group, named group G, of C. psl. complex and compared its physiological and biochemical characteristics with the mating group I-E, which was closely related to the mating group G. Zygospores are typically formed as a result of conjugation between mating-type plus (mt⁺) and mating-type minus (mt^?) cells in the same mating group during sexual reproduction. Crossing experiments revealed mating groups G and I-E were reproductively isolated from each other, but the release of lone protoplasts from mt^? cells of mating group G was induced in the presence of mt⁺ cells of mating group I-E. In fact, the sex pheromone, protoplast-release-inducing protein of mating group I-E induced the release of protoplasts from mt^? cells of mating group G. When mt⁺ and mt^? cells of both mating groups I-E and G were co-cultured (multiple-choice matings), the zygospore formation of mating group G, but not that of mating group I-E, was inhibited. Based on these results, we propose a possible mechanism of reproductive isolation between the two mating groups and suggest the presence of sexual interference between mating group G and mating group I-E.     

Prasinoxanthin is absent in the green-colored dinoflagellate Lepidodinium chlorophorum strain NIES-1868: pigment composition and 18S rRNA phylogeny

Green-colored plastids in the dinoflagellates Lepidodinium chlorophorum and L. viride have been widely believed as the remnant of an endosymbiotic prasinophyte. This hypothesis for the origin of the Lepidodinium plastids is solely based on an unpublished result quoted in Elbr?chter and Schnepf (Phycologia 35:381–393, 1996) hinting at the presence of a characteristic carotenoid in prasinophytes, prasinoxanthin, in the L. chlorophorum cells. On the other hand, a recent work failed to detect prasinoxanthin in a culture of L. chlorophorum. Unfortunately, we cannot conduct any additional experiments to examine whether the two strains considered in the previous studies are truly of L. chlorophorum, as neither of the two strains is publicly available. We here investigated the pigment composition of L. chlorophorum strain NIES-1868 maintained as a mono-algal culture under laboratory conditions, and detected no sign of prasinoxanthin. The pigment composition of strain NIES-1868 is consistent with previous phylogenetic analyses based on plastid-encoded genes of the same strain, which successfully excluded prasinoxanthin-containing algae from the origin of the L. chlorophorum plastid. We also determined nucleus-encoded 18S ribosomal RNA (rRNA) genes from four Lepidodinium strains (including strain NIES-1868). Analyses of 18S rRNA sequences showed an extremely close relationship among strain NIES-1868 and other Lepidodinium cells/strains originating from different geological locations, suggesting that the cells/strains corresponding to these rRNA sequences lack prasinoxanthin.     

Effect of zinc deficiency on the appearance of two immunodominant protein antigens (32 kDa and 65 kDa) in culture filtrates of mycobacteria

After growth of six strains of mycobacteria on Sauton medium in the absence of added Zn2+, cell yields were lowered, to between 22% and 67% of the yields obtained when Zn2+ (5 microM) was added. Two immunodominant proteins, named P64 and P32 (antigens of 62-65 kDa and 29-33 kDa, respectively) were abundant in culture filtrates after growth of mycobacteria. P64 was present at elevated concentrations (showing a 9- to 16-fold increase as a percentage of the total protein released) after Zn2+-deficient growth of five of the six strains studied; in Mycobacterium tuberculosis it represented 25% of all released proteins. However, little P64 was detected in culture filtrates of M. fortuitum and of M. phlei grown under Zn2+ deficiency, and in the latter there was no increase of P64 during Zn2+ deficiency.     

Multiple growth-associated nuclear proteins immunoprecipitated by antisera raised against human c-myc peptide antigens.

Different antisera raised against various regions of the human c-myc protein were used to identify four human c-myc proteins with apparent molecular masses in sodium dodecyl sulfate-polyacrylamide gels ranging from 64 to 68 kilodaltons (phosphoproteins pp64 and pp67 and nonphosphorylated proteins p65 and p68). pp64 and p65 were the major detectable c-myc proteins, and pp67 and p68 were minor but specific components of the immunoprecipitates. The c-myc proteins were all localized in the cell nucleus. Accumulation of [35S]methionine-labeled p65 was observed after pulse-labeling and chase, suggesting that the stable p65 c-myc protein is generated posttranslationally from short-lived precursors. pp64, pp67, and p68 possessed short half-lives and may therefore be precursors of the stable p65. Confirmation of the nuclear localization of the human c-myc proteins was obtained by immunofluorescent staining. The human c-myc proteins were revealed as a pattern of punctate nuclear staining with, particularly for p65, nucleolar enhancement that left an unstained annulus surrounding the nucleolus.     

Sexual Interaction in Heterothallic Strains of Closterium peracerosum-strigosum-littorale: Partial Characterization of a Male-Specific Sexual Pheromone, Protoplast-Releasing Substance

A sexual pheromone, named the protoplast releasing substance (PRS), was formed by mating type minus cells. PRS activates mating type plus cells and results in the release and fusion of protoplasts within distended conjugation-papilla in paired cells and in the release and disruption of protoplasts in unpaired mating type plus cells. In an agar barrier system, the activation of mating type plus cells was markedly inhibited by treatment with pronase (5-10 micrograms per milliliter), proteinase (100 micrograms per milliliter), and α-mannosidase (10 micrograms per milliliter). Trypsin (10-100 micrograms per milliliter) had no effect on the activation in the agar barrier system. The results suggest that PRS is a glycoprotein with pronase-sensitive and trypsin-insensitive structure.     

Protoplast fusion in Streptomyces fradiae strains producing neomycin and tylosin]

Interspecies fusion of protoplasts of the Streptomyces fradiae strains producing neomycin (an aminoglycoside antibiotic) and tylosin (a macrolide antibiotic) was performed with a view to isolate strains producing novel antibiotics. Fusion of the protoplasts of the neomycin- and tylosin-producing strains labelled by the resistance to monomycin and lincomycin, respectively, caused no formation of stable strains producing antibiotics differing in chromatographic mobility from the antibiotics produced by the initial strains. In fusion of the protoplasts of the unlabelled strains, heat-inactivated protoplasts of the active line of one strain (donor) and native protoplasts of the inactive line of the other strain (recipient) were used. When the neomycin-producing culture was used as a recipient the fusion led to formation of strain 195-34 producing antibiotics of the benzo(a)anthraquinone group. One of these antibiotics, i.e. antibiotic 34-I, proved to be a novel biologically active substance. After regeneration of the protoplasts of the initial strains, no stable strains producing antibiotics differing from neomycin and tylosin were isolated.     

A sex pheromone, protoplast release-inducing protein (PR-IP) inducer, induces sexual cell division and production of PR-IP in Closterium

The sex pheromone protoplast release-inducing protein (PR-IP) inducer and a sexual cell division-inducing pheromone-minus (SCD-IP-minus) that mediates the sexual reproduction of the heterothallic Closterium peracerosum-strigosum-littorale (C. psl) complex were investigated in this study. Recombinant PR-IP inducer produced by yeast cells was prepared and assayed for production of PR-IP and induction of SCD. Both biological activities were observed after treating mating-type plus (mt+) cells with the recombinant pheromone. SCD was induced by exposure to a lower concentration of the same pheromone and by a shorter treatment period with the pheromone than was production of PR-IP. This indicates that the previously characterized PR-IP inducer has both PR-IP-inducing and SCD-inducing activities with mt+ cells, although the inducing mechanisms of the two pheromones differ.     

Oil palm (Elaeis guineensis) protoplasts: isolation, culture and microcallus formation

Procedures are deseribed for the efficient isolation of protoplasts from a variety of oil palm (Elaeis guineensis Jacq.) tissues. Various factors including donor source, composition of enzyme mixture and culture medium affected the yield and viability of the protoplasts Polyembryogenic cultures of oil palm were the most suitable starting material in terms of yield, viability and metabolic competence. Pectolyase Y-23 in association with cellulase and hemicellulase was required for the efficient release of protoplasts from the oil palm tissues. Limited cell division to form microcallus was observed at very low frequency (<0.01%) when glutathione and catalase were incorporated in the culture medium.Abbreviations 2,4-d dichlorophenoxyacetic acid - DTT dithiothreitol - MES 2[N-morpholino] ethanesulphonic acid - NAA 1-naphthalene acetic acid - PVP polyvinylpyrrolidone     

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.