PHYLOGENETIC POSITION OF CRUSTOMASTIX STIGMATICA SP. NOV. AND DOLICHOMASTIX TENUILEPIS IN RELATION TO THE MAMIELLALES (PRASINOPHYCEAE,CHLOROPHYTA)1

A new marine microalga from the Mediterranean Sea, Crustomastix stigmatica Zingone, is investigated by means of LM, SEM, TEM, and pigment and molecular analyses (nuclear‐encoded small subunit [SSU] rDNA and plastid‐encoded rbcL). Pigment and molecular information is also provided for the related species Dolichomastix tenuilepis Throndsen et Zingone. Crustomastix stigmatica has a bean‐shaped cell body 3–5 μm long and 1.5–2.8 μm wide, with two flagella four to five times the body length. The single chloroplast is pale yellow‐green, cup‐shaped, and lacks a pyrenoid. A small bright yellow stigma is located in the mid‐dorsal part of the cell under the chloroplast membrane. An additional accumulation of osmiophilic globules is at times seen in a chloroplast lobe. Cells lack flat scales, whereas three different types of hair‐like scales are present on the flagella. The main pigments of C. stigmatica are those typical of Mamiellales, though siphonein/siphonaxanthin replaces prasinoxanthin and uriolide is absent. The pigment pool of D. tenuilepis is more similar to that of Micromonas pusilla (Butcher) Manton et Parke and of other Mamiellales. The nuclear SSU rDNA phylogeny shows that the inclusion of C. stigmatica and D. tenuilepis in the Mamiellales retains monophyly for the order. The two species form a distinct clade, which is sister to a clade including all the other Mamiellales. Results of rbcL analyses failed to provide phylogenetic information at both the order and species level. No unique morphological or pigment characteristics circumscribe the mamiellalean clade as a whole nor its two daughter clades.     

Cytological evidence for cytoplasmic volume control in Platymonas subcordiformis after osmotic stress

Abstract. Platymonas subcordiformis , a marine phytoplankton flagellate, shows partial control of cell volume in response to osmotic stress. Electron micrographs of samples taken at short intervals after application of a hypo-osmotic stress revealed that a large vacuolar system is formed by fusion of vesicles originating from the Golgi apparatus. The chloroplast is swollen and the thylakoid stacking is transiently disturbed for 1 to 5 min after the osmotic shock. It then regains the original size and stacked organization of the thylakoids, while the vacuoles remain permanently. It is assumed that mainly the cytoplasmic compartment is under volume control rather than the whole cell, as has been found in other wall-less micro-algae.     

PIGMENTS OF BATHYCOCCUS PRASINOS (PRASINOPHYCEAE): METHODOLOGICAL AND CHEMOSYSTEMATIC IMPLICATIONS1,2

Bathycoccus prasinos Eikrem et Throndsen exhibited a complex carotenoid distribution pattern including the carotenes β,β-carotene (0.8% of total carotenoids) and β, ° Carotene (0.4%) and several xanthophylls. These were prasinoxanthin (49% of total carotenoids), micromonal (16%), neoxanthin (14%), uriolide (7%), violaxanthin (0.8%), 3¹-dehydrouriolide (0.8%), dihydrolutein (0.1%), two partly characterized esterified carotenols (together 10%), and five minor unidentified carotenols (together 2%). The identifications were based on high-performance liquid chromatography (HPLC), thin-layer chromatography (TLC), visible spectroscopy (VIS), and mass spectra (MS) and in part on ¹H nuclear magnetic resonance (NMR), circular dichroism (CD), and chemical derivatization. The carotenoid composition of B. prasinos was related to that of other prasinoxanthin / uriolide / micromonal-producing prasinophytes (Mantoniella squamata, Micromonas pusilla, and Pseudoscourfieldia marina). The relative distribution of chlorophylls (w/w) were chlorophyll a (chl a; 63%), chl b (31%), and an unknown chl c-like chlorophyll (7%) with spectral characteristics similar to magnesium 2,4-divinylphaeoporphyrin a, monomethyl ester, compatible with other prasinophytes. The chemosystematic data and ultrastructural characteristics for the order Mamiellales are discussed. We conclude that HPLC studies alone are insufficient for the identification and characterization of the carotenoids, including the minor carotenoids essential for biosynthetic/chemosystematic considerations.     

The Existence of Chlorophyll c in the Chl b-Containing,Light-Harvesting Complex of the Green Alga Mantoniella squamata (Prasinophyceae)

The prasinophycean alga Mantoniella contains, in addition to Chl a and b, at least a third green pigment which is functionally active in the light-harvesting antenna. This third Chl was isolated in order to elucidate its chemical structure. The absorption and fluorescence spectra were measured not only from the purified pigment but also from its pheophytin and its methylpheophorbide. The spectra were compared with those of authentic Chl c-1 and c-2, which were isolated from the diatom Nitzschia sp. and with Mg-DVPP (purified from Rhodobacter). The results show that the pigment from Mantoniella compares best with Chl c-1. In order to clarify the spectral data, Chl c-1 and c-2, Mg-DVPP, and the pigment from Mantoniella were subjected to a chromatographic system that is able to separate these porphyrins. The chromatographic analysis clearly shows that the pigment from Mantoniella co-migrates with Chl c-1 and not with the bacterial pigment. Mantoniella is the first organism which has been demonstrated to contain Chl a, b, and authentic c.     

RHYTHMIC SETTLING BEHAVIOR IN PYRAMIMONAS PARKEAE (PRASINOPHYCEAE)1

Pyramimonas parkeae Norris et Pearson was examined for evidence of a settling rhythm while growing in laboratory culture. The alga settled rhythmically in a diet cycle when kept in a regularly alternating light-dark cycle. Cells moved out of suspension when settling and attached themselves to the sides and base of the culture vessel. Although rhythmic settling was inhibited in constant dim light (LL), it continued in constant darkness for 4 days with a period of approximately 24 h. The settling rhythm was temperature-compensated and could be reset by 6-h exposures to light. These observations demonstrate that the settling behavior of P. parkeae is controlled by an endogenous circadian oscillator. Regular low temperature pulses every 12 h removed the inhibition caused by LL and this points to the possible role of temperature changes as stimuli entraining the circadian settling rhythm of P. parkeae.