The life history and cell cycle of Kryptoperidinium foliaceum, a dinoflagellate with two eukaryotic nuclei.

Kryptoperidinium foliaceum is a binucleate dinoflagellate that contains an endosymbiont nucleus of diatom origin. However, it is unknown whether the binucleate condition is permanent or not and how the diatom nucleus behaves during the life history processes. In this sense, it is also unknown if there is a sexual cycle or a resting stage during the life history of this species, two key aspects necessary to understand the life history strategy of this dinoflagellate. To answer these questions, life history and cell cycle studies were performed with the following results: (i) Kryptoperidinium foliaceum has a sexual cycle and in the dinoflagellate strains studied, the binucleate condition is permanent. Sexuality in the host was confirmed by the presence of fusing gamete pairs and planozygotes in clonal cultures (revealing homothallism), but signs of meiosis in the endosymbiont were not observed. The endosymbiont nucleus likely fuses first, because fusing gamete pairs were found to have two dinoflagellate nuclei but only one endosymbiont nucleus. After complete gamete fusion, the planozygotes had apparently normal endosymbiont and dinoflagellate nuclei. (ii) Asexual division studies using flow cytometry showed that the S phase in the endosymbiont (diatom) nucleus starts 6-8h later than in the host nucleus, but there was no evidence of mitosis in the former. (iii) Sexual and asexual cysts were formed in culture. Neither cysts from natural samples nor those formed in culture exhibited a dormancy period before germination.

CELL CYCLE AND CELL MORTALITY OF ALEXANDRIUM MINUTUM (DINOPHYCEAE) UNDER SMALL-SCALE TURBULENCE CONDITIONS(1).

Decreased net population growth rates and cellular abundances have been observed in dinoflagellate species exposed to small-scale turbulence. Here, we investigated whether these effects were caused by alterations in the cell cycle and/or by cell mortality and, in turn, whether these two mechanisms depended on the duration of exposure to turbulence. The study was conducted on the toxic dinoflagellate Alexandrium minutum Halim, with the same experimental design and setup used in previous studies to allow direct comparison among results. A combination of microscopy and Coulter Counter measurements allowed us to detect cell mortality, based on the biovolume of broken cells and thecae. The turbulence applied during the exponential growth phase caused an immediate transitory arrest in the G2/M phase, but significant mortality did not occur. This finding suggests that high intensities of small-scale turbulence can alter the cell division, likely affecting the correct chromosome segregation during the dinomitosis. When shaking persisted for >4 d, mortality signals and presence of anomalously swollen cells appeared, hinting at the activation of mechanisms that induce programmed cell death. Our study suggests that the sensitivity of dinoflagellates to turbulence may drive these organisms to find the most favorable (calm) conditions to complete their division cycle.

Use of vitellogenin mRNA as a biomarker for endocrine disruption in feral and cultured fish.

The presence of the female-specific yolk protein precursor vitellogenin in blood and liver from male fish is widely used as an indicator of endocrine disruption. We studied the induction of vitellogenin mRNA in liver from several species of fish, both maintained in fish tanks or captured in the wild. Our procedure requires minute amounts of liver samples (down to 50 mg), and can be applied to field samples if the appropriate RNA-stabilisation agent is used. We used reverse-transcriptase PCR and quantitative real-time PCR for detection and precise quantitation of vitellogenin mRNA levels. Male mummichog (Fundulus heteroclitus) exposed to 17 beta-estradiol contained levels of vitellogenin mRNA up to 30 times higher than in untreated females and treatment with nonylphenol resulted in a weak but consistent induction of this transcript. We also studied levels of vitellogenin mRNA in a population of common carp (Cyprinus carpio) from the Anoia river, a river known for its high levels of estrogenic alkylphenols. The results were consistent with recorded data for fish from this sampling site. Finally, we also detected vitellogenin mRNA in barbs (Barbus graellsi), a species for which no vitellogenin sequence was available. The use of mRNA quantitation techniques for analysis of feral and cultured fish of different species opens the possibility of more precise detection and further control of the noxious effects of contaminants on the local fauna exposed to them.