SxtA and sxtG gene expression and toxin production in the Mediterranean Alexandrium minutum (Dinophyceae).

The dinoflagellate Alexandrium minutum is known for the production of potent neurotoxins affecting the health of human seafood consumers via paralytic shellfish poisoning (PSP). The aim of this study was to investigate the relationship between the toxin content and the expression level of the genes involved in paralytic shellfish toxin (PST) production. The algal cultures were grown both in standard f/2 medium and in phosphorus/nitrogen limitation. In our study, LC-HRMS analyses of PST profile and content in different Mediterranean A. minutum strains confirmed that this species was able to synthesize mainly the saxitoxin analogues Gonyautoxin-1 (GTX1) and Gonyautoxin-4 (GTX4). The average cellular toxin content varied among different strains, and between growth phases, highlighting a decreasing trend from exponential to stationary phase in all culture conditions tested. The absolute quantities of intracellular sxtA1 and sxtG mRNA were not correlated with the amount of intracellular toxins in the analysed A. minutum suggesting that the production of toxins may be regulated by post-transcriptional mechanisms and/or by the concerted actions of alternative genes belonging to the PST biosynthesis gene cluster. Therefore, it is likely that the sxtA1 and sxtG gene expression could not reflect the PST accumulation in the Mediterranean A. minutum populations under the examined standard and nutrient limiting conditions.

Unique toxin profile of a Mediterranean Ostreopsis cf. ovata strain: HR LC-MS(n) characterization of ovatoxin-f, a new palytoxin congener.

Currently, the benthic dinoflagellate Ostreopsis cf. ovata represents a serious concern to human health in the whole Mediterranean basin due to the production of palytoxin congeners, a putative palytoxin and ovatoxins (ovatoxin-a, -b, -c, -d/-e), listed among the most potent marine toxins. High resolution liquid chromatography-mass spectrometry (HR LC-MS) based investigation of a North Western Adriatic strain of Ostreopsis cf. ovata collected at Portonovo (Italy) in 2008 is reported herein. Toxin profile was different from those previously reported for other O. cf. ovata, both qualitatively and quantitatively. For the first time, ovatoxin-a did not dominate the toxin profile, and a new palytoxin congener, here named ovatoxin-f, was detected. Ovatoxin-f and its elemental formula present C(2)H(4) more than ovatoxin-a. HR CID MS(n) experiments allowed us to restrict structural differences between ovatoxin-a and -f to the region between C-95 and C-102, a region not previously been described to be modified in other palytoxins. Ovatoxin-f represents the major component of the toxin profile of the analyzed strain accounting for 50% of the total toxin content, while ovatoxin-a, the dominant toxin in most of the Mediterranean O. cf. ovata strains we have analyzed so far, is the second major component of the toxin profile (23%). Thus, the presence of ovatoxin-f should be taken into account when monitoring programs for palytoxin-like compounds in microalgae and/or seawater are carried out.

Characterization of 27-hydroxy-13-desmethyl spirolide C and 27-oxo-13,19-didesmethyl spirolide C. Further insights into the complex Adriatic Alexandrium ostenfeldii toxin profile.

Alexandrium ostenfeldii is a widespread toxic dinoflagellate that has recently bloomed across the Adriatic Sea, seriously threatening both shellfish consumers and aquacultures. In 2007 we reported on preliminary studies carried out on field samples and cultures of A. ostenfeldii. At the time, along with three major spirolides - among which 27-hydroxy-13,19-didesmethyl spirolide C (3) proved to be a novel compound - a number of new minor spirolides were detected. Unfortunately, for all of them only Mass Spectrometry-based structural hypotheses could be ventured due to their very small amount. In the present paper we report on isolation and High Resolution Mass Spectrometry- and NMR-based structural elucidation of two of those minor spirolides detected in our previous study.