A Circadian Rhythm in the Activity of Superoxide Dismutase in the Photosynthetic Alga Gonyaulax polyedra

The activity of superoxide dismutase in cell-free extracts of Gonyaulax made at different times of day and night was found to be three to four times higher during the day. This rhythm continued in cells kept in constant light, indicating that the regulation can be attributed to the cellular circadian clock.     

Effects of Indoleamines and Short Photoperiods on the Encystment of Gonyaulax polyedra

At a temperature of 15^oC, Gonyaulax polyedra responds to short days (light ≤ 10 h) by transition to the stage of a resting cyst. At 20^oC, even an lightdark (LD) cycle of 6:18 is incapable of inducing this process. In otherwise cyst-inducing conditions (15^oC; 10 h of light per day), an interruption of the scotophase by 2 h of light (LDLD 8:2:2:12 or 2:2:8:12) prevented encystment. Cyst induction is, therefore, initiated by a photoperiodic mechanism rather than by light deficiency. In Gonyaulax, photoperiodism may be mediated by the action of indoleamines. Melatonin, which exhibits a circadian rhythmicity in this organism, leads to encystment when given 1 h before lights-off in LD 11:13 at 15^oC, i.e., under otherwise noninducing conditions. Again, at 20^oC, melatonin is inefficient. Some analogues of melatonin, in particular, 5-methoxytryptamine and N,N-dimethyl-5-methoxytryptamine, and, at high concentrations, their respective precursors, serotonin and bufotenin, are capable of inducing cyst formation at 20^oC and in LD 12:12, whereas A'-acetyl-serotonin does not show this effect.     

The Function of Circadian RNA‐Binding Proteins and Their cis‐Acting Elements in Microalgae

An endogenous clock regulates the temporal expression of genes/mRNAs that are involved in the circadian output pathway. In the bioluminescent dinoflagellate Gonyaulax polyedra circadian expression of the luciferin‐binding protein (LBP) is controlled at the translational level. Thereby, a clock‐controlled RNA‐binding protein, called circadian controlled translational regulator (CCTR), interacts specifically with an UG‐repeat, which is situated in the lbp 3^′ UTR. Its binding activity correlates negatively with the amount of LBP during a circadian cycle. In the green alga Chlamydomonas reinhardtii, a clock‐controlled RNA‐binding protein (CHLAMY 1) was identified, which represents an analog of the CCTR from the phylogenetically diverse alga G. polyedra. CHLAMY 1 binds specifically to the 3^′ UTRs of several mRNAs and recognizes them all via a common cis‐acting element, composed of at least seven UG‐repeats. The binding strength of CHLAMY 1 is strongest to mRNAs, whose products are key components of nitrogen metabolism resulting in arginine biosynthesis as well as of CO₂ metabolism. Since temporal activities of processes involved in nitrogen metabolism have an opposite phase than CHLAMY 1 binding activity, the protein might repress the translation of the cognate mRNAs.     

Combining Theoretical and Experimental Approaches to Understand the Circadian Clock

This review is intended as a summary of our work carried out as part of the German Research Association (DFG) Center Program on Circadian Rhythms. Over the last six years, our approach to understanding circadian systems combined theoretical and experimental tools, and Gonyaulax and Neurospora have proven ideal for these efforts. Both of these model organisms demonstrate that even simple circadian systems can have multiple light input pathways and more than one rhythm generator. They have both been used to elaborate basic circadian features in conjunction with formal models. The models introduce the “zeitnehmer,” i.e., a clock‐regulated input pathway, to the conceptual framework of circadian systems, and proposes networks of individual feedbacks as the basis for circadian rhythmicity.     

Correlation between the presence of Gonyaulax fragilis (Dinophyceae) and the mucilage phenomena of the Emilia-Romagna coast (northern Adriatic Sea)

The formation of massive amounts of suspended mucilaginous organic matter which periodically affects the Adriatic Sea, has been regarded as a complex physico-chemical phenomenon resulting from the production of extracellular material by phytoplankton. Although the exact cause has remained obscure, the mechanism of its formation has usually been considered to be a long-term process, starting after the late winter-early spring blooms, and involving the participation of various algal species, mainly within the diatom group. In this paper we report on the results of a phytoplankton monitoring programme in northern Adriatic seawaters off the Emilia-Romagna coast of Italy which revealed the constant concomitant presence of the dinoflagellate Gonyaulax fragilis (Schütt) Kofoid and mucilaginous formations. In the early stages of the phenomenon the dinoflagellate was clearly observable by microscopic examination in the mucilage, but as the mucilage aged this alga almost completely decomposed and diatom cells increased in number and became predominant. Although characterized by a slow growth rate in culture, in natural seawater G. fragilis was observed to reach cell densities of up to 7.0×10⁶ cells l⁻¹. The results of this study lead us to propose the hypothesis that the appearance of mucilage in the water column of the Adriatic Sea is the consequence of a seasonal growth of this dinoflagellate favoured by specific environmental circumstances.     

Mass accumulation of mucilage caused by dinoflagellate polysaccharide exudates in Tasman Bay, New Zealand

At about 20-year intervals, since at least the 1860s, there have been accounts of the accumulation of large quantities of mucilage in the waters off the northern coast of the South Island of New Zealand. On a few occasions these events have been associated with harmful effects, such as the mass mortality of marine fauna and the impediment of fishing activities, though previous attempts to identify the causative organism(s) or the environmental conditions which promote its development have been unsuccessful. In January 2000, there was a moderate re-occurrence of mucilage accumulation in Tasman Bay that led to the identification of the primary origin of this material as the planktonic, thecate, dinoflagellate Gonyaulax hyalina (Ostenfeld et Schmidt). Macro-aggregate accumulation was occurring in the water column when dinoflagellate cell numbers were relatively low. Experimental work on cultures of this organism showed that the dinoflagellate produced transparent exo-polymers (TEPs) composed primarily of galactose and glucose monomers (44.8 and 29.6 mol%, respectively). Analysis of natural and cultured mucilage showed this had a high inorganic content (>60% (w/w)). A substantial proportion (40% (w/w)) of this inorganic fraction was composed of calcium that apparently played an important role in stabilizing the gel. Phosphorus was also enriched in the mucilage. It is hypothesized that the high inorganic N/P ratio observed in the water column at the time of mucilage formation was an effect rather than a cause of this event, which resulted in the scavenging of particulate material from the water column and enrichment of sediments and bottom waters with organic material and phosphorus.     

SEXUALITY AND CYST FORMATION IN PACIFIC STRAINS OF THE TOXIC D1NOFLAGELLATE GONYAULAX TAMARENSIS1,2

Sexuality has been established for a culture of Gonyaulax tarnarensis Lebour (strain NEPCC–71). The addition of a thick inoculum to a nitrogen–deprived medium results in the occurrence of anisogamous sexual fusion within the first three days in the new culture. Planozygotes, large “lumpy” cells recognizable by their four flagella, may persist up to 2 wk before forming a smooth–walled, oval hypnozygote. The latter resembles cysts released asexually by ecdysis but has a slightly thicker wall. Viable cysts resembling hypnozygotes (zygotic cysts), but with reduced photosynthetic pigmentation, have been isolated from natural murine sediments in Hidden Basin, British Columbia, and a culture (strain NEPCC–254) was initiated from excysted individuals. Zygotic cysts of NEPCC–71 remained encysted in the light at 17 C for 8 wk before excysting. The presence of a ventral pen with toxicity in the latter strain indicates that the taxonomy of G. tamarensis-like organisms is still in a stale of flux and the criteria for recognition of G. excavata (Braarud) Balech as a separate species are not satisfactory as presently formulated.     

Hydrogen peroxide and nitric oxide trigger redox-related cyst formation in cultures of the dinoflagellate Lingulodinium polyedrum

The dinoflagellate Lingulodinium polyedrum is a toxin producer that shows the ability of turning to resting cysts as a survival strategy when exposed to environmental unfavorable conditions, such as nitrogen and phosphorus depletion, abrupt changes in temperature or light, and chemical or mechanical stress. Algal adaptation to all these conditions involves hydrogen peroxide (H₂O₂) and nitric oxide (NO) as key redox signals for housekeeping cellular processes. Thus, we aim here to shed light on the role of H₂O₂ and NO (from aqueous decomposition of sodium nitroprusside, SNP) as prooxidant agents and putative redox signals for encystment of the dinoflagellate L. polyedrum. Harsh oxidative stress imposed by 500 μM H₂O₂ treatment forced L. polyedrum cells to rapidly encyst, in less than 30 min, whereas slower cyst formation was observed upon lower H₂O₂ doses. L. polyedrum encystment was marked by a significant increase in the antioxidant carotenoid peridinin, although other photosynthetic pigments (chlorophyll a and β-carotene) and light-harvesting complexes (peridinin complex protein, PCP) were all diminished in cyst forms. Although SOD activity (a frontline antioxidant enzyme) was severely inhibited by increasing doses of H₂O₂, a theoretical compensatory effect was provided by the dose-dependent increase of ascorbate peroxidase activity (APX), which resulted in significant lower levels of lipid peroxidation during cyst formation. Although SNP data cannot be fully compared to those found with H₂O₂ treatments, changes in APX activity and in biomarkers of lipid and protein oxidation matched the dose–responses found in H₂O₂ experiments, revealing similar biochemical and morphological responses against increasing oxidative conditions during cyst formation. Our data significantly contribute to a better understanding of the relationship between encystment, photosynthesis, and antioxidant responses triggered by H₂O₂ and NO in L. polyedrum, a harmful diarrhetic shellfish poisoning toxin (DSPs) producer.     

POTENTIAL IMPORTANCE OF BENTHIC CYSTS OF GONYAULAX TAMARENSIS AND G. EXCAVATA IN INITIATING TOXIC DINOFLAGELLATE BLOOMS1,2,3

Thick-walled, nonmotile cysts (termed hypnocysts) of two dinoflagellates were isolated from estuarine sediments in Cape Cod, Massachusetts, and germinated to produce their respective motile, thecate stages. Hypnocysts from Orleans district were identified as Gonyaulax excuvata (Braarud) Balech sensu Loeblich & Loeblich. Visually identical hypnocysts from Falmouth district were provisionally identified as Gonyaulax tamarensis Lebour. Both species were toxic. A geographic survey in September detected hypnocysts in only the sediments of locations where toxic blooms developed the preceding and following Spring. Laboratory incubation (16 C) of hypnocysts from sediment samples stored in the dark (5 C) for 6 mo initiated excystment by the temperature increase, with no appreciable effect from light regime, nutrient, or chelator concentrations. Motility of excysted germlings was optimum in highly chelated medium and in the presence of light. We conclude that hypnocysts of both tasa are important in seeding recurrent annual blooms, synchronizing early bloom development with vernal warning of seawater and increasing the geographic range of the species. We suggest that many red tides in New England and eastern Canadian waters are initiated through the displacement of motile estuarine populations into nearshore area by tidal advection and surface runoff, although the potential existence and importance of offshore cyst reservoirs cannot be discounted. Evidence is presented that hypnocysts are probable sexual zygotes whereas the thin-walled cysts readily formed in laboratory cultures (pellicle cyst) are asexual. Pellicle cysts are of limited durability, do not overwinter in nature, and therefore do not play a significant role in initiating toxic blooms.