INVESTIGATION OF 4‐METHYL STEROLS FROM CULTURED DINOFLAGELLATE ALGAL STRAINS

Abstract

The marine dinoflagellates Prorocentrum micans, Gonyaulax polyedra, Gymnodinium sp., and Alexandrium tamarense, collected from the Adriatic Sea during red‐tide blooms, were cultured to investigate the 4‐methyl sterol constituents. To ascertain a possible influence of cell age on the 4‐methyl sterol content, for one strain (Gymnodinium sp.)we investigated the composition of these constituents at exponential and stationary growing phases. The lipid material extracted with acetone from the lyophilized algal samples was fractionated by thin‐layer chromatography. The 4‐methyl sterols recovered from the layer were converted into the corresponding OTMS derivatives. Nine of 11 constituents were identified by gas chromatography and gas chromatography‐mass spectrometry; only two minor constituents were characterized by their gas chromatographic parameters. All free methyl sterols identified in the algal samples had been detected previously in various dinoflagellates. The 4‐methyl sterol fractions generally contained very few constituents. Except for the Gymnodinium sp. sample, collected at the exponential growing phase (GyD2 exp), which contains 4,24‐dimethylcholestan‐3‐ol as a unique constituent, dinosterol was the major component. Moreover, 4,24‐ethylcholestan‐3‐ol was also an important constituent of both Prorocentrum and Gonyaulax strains, whereas considerable amounts of dinostanol characterized all the Gymnodinium sp. strains. In addition, the latter contained several minor constituents such as 4‐methylcholestan‐3‐ol, 4,24‐dimethylcholesta‐22‐en‐3‐ol, and 4‐methyl‐24‐ethylcholestan‐3‐ol. 4‐Methyl‐24‐methylene‐cholestan‐3‐ol was a constituent of the Gymnodinium sp. sample, collected at the stationary growing phase (GyD2 stat)only, whereas 4‐methylgorgostanol was identified only in the Alexandrium tamarense Gt4 strain. Except for 4‐methyl‐24‐ethylcholesta‐8(14)‐en‐3‐ol, all the methyl sterol constituents from our algae show a saturated polynuclear system. The pathways by which side‐chain modifications occur in dinoflagellate 4‐methyl sterols are considered, and a map of the fragmentation pattern of the trimethylsilyl‐4‐methyl sterols under electronic impact is also reported.