Ethanol stimulates phospholipid turnover and inositol 1,4,5-trisphosphate production in Chlamydomonas eugametos gametes.

Alcohols induce mating-structure activation in Chlamydomonas eugametos gametes. From the effect of ethanol on the (32)P-labelling of polyphosphoinositides, we conclude that the synthesis of these lipids is stimulated. Biologically inactive concentrations of ethanol (<6%) had no effect on synthesis, but 6-8% ethanol stimulated synthesis for upto 60 min. The (32)P incorporated into polyphosphoinositides and phosphatidic acid during ethanol treatment was readily chased out when 1 mM unlabelled Na3PO4 was added. Using a binding assay for inositol 1,4,5-trisphosphate, we show that the production of this phospholipid constituent is dramatically increased after ethanol treatment. This effect, coupled to a rise in intracellular calcium concentration, could explain gamete activation. The significance of these results in explaining other ethanol-induced phenomena in algae is discussed.

Increase in calcium triggers mating structure activation in Chlamydomonas eugametos.

For mating Chlamydomonas eugametos gametes to fuse with their partners, they must first lyse part of the anterior cell wall and protrude their mating structures. These responses can be artificially induced by compounds that raise the Cai level, viz. InsP3, A23187, TFP and ethanol. We conclude that calcium should be considered with cAMP to be involved in signal transduction during C. eugametos mating.

Occurrence of O-methylated sugars in surface glycoconjugates in Chlamydomonas eugametos.

Previously, we have shown that the monomeric-sugar composition of cell-surface-associated glycoconjugates of two strains of Chlamydomonas eugametos, of different mating type, differs strikingly (Gerwig et al. 1984, Carbohydr. Res. 127, 245-251). Besides the common occurrence of various pentoses and hexoses, the glycoconjugates of one strain contain 4-O-methyl xylose, a 2-O-methyl pentose (probably 2-O-methyl arabinose) and 3-O-methyl galactose, whereas those of the other strain contain 6-O-methyl mannose and 3-O-methyl glucose. In order to investigate whether these differences are relevant to the mating process of this organism, the sugar composition of the sexual progeny of these strains was analyzed. The ability to produce 4-O-methyl xylose, 2-O-methyl pentose and 3-O-methyl galactose on the one hand, and the ability to produce 6-O-methyl mannose and 3-O-methyl glucose on the other hand, appear to be genetically linked. However, the ability to produce either set of O-methyl sugars was inherited independently of mating type. O-Methylated sugars do not occur in the cell wall of C. eugametos, or in the cell-free medium, but only in surface-membrane-associated glycoconjugates, extractable with salt or detergent solutions.

Monoclonal antibodies to surface glycoconjugates in Chlamydomonas eugametos recognize strain-specific O-methyl sugars.

Monoclonal antibodies are described that are directed against cell surface components of the unicellular green alga Chlamydomonas eugametos. These antibodies recognize strain-specific epitopes which occur at the surface of vegetative and gametic cells. Two different groups of epitopes are distinguished that are never detectable together in one clonal cell culture. Evidence is presented showing that the antigenicity of cell surface molecules is a consequence of the presence of particular O-methylated sugars. Monoclonal antibodies reacting with one group of epitopes were studied in more detail, and immunoprecipitation and Western-blot studies showed that these epitopes can be arranged into four classes. The use of these monoclonal antibodies as strain-specific markers in light- and electron-microscopical techniques is illustrated.

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.

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 aggregation.