Qualitative and quantitative composition of pigments in Phaeodactylum tricornutum (Bacillariophyceae) stressed by iron

The effect of Fe(III) deficiency on qualitative and quantitative changes in pigment composition in Phaeodactylum tricornutum Bohlin was demonstrated by HPLC and AAS. Maximum content of pigments showed the diatom cells incubated at the optimum iron concentration, i.e., 10 M. The contents of chlorophyll a, chlorophyll c ₁+c ₂, fucoxanthin, diadinoxanthin and ,-carotene were 109.99, 20.16, 40.39, 1.29 and 1.48 fg per cell, respectively. The results obtained showed that Fe(III) affected qualitative and quantitative pigment composition in P. tricornutum. The content of individual pigments, proportions between accompanying pigments and their ratios to chlorophyll a were important indicators of phytoplankton response to iron stress. The strong reduction in ,-carotene content, several times (2–5) increase in diadinoxanthin level as compared to ,-carotene, and high amount of diadinoxanthin in relation to chlorophyll a were observed in algae growing at very low Fe(III) concentrations, 0.001 and 0.01 M. The data suggested that phytoplankton pigments could be a potential physiological marker.     

On the relationship between the non-photochemical quenching of the chlorophyll fluorescence and the Photosystem II light harvesting efficiency. A repetitive flash fluorescence induction study

Plants respond to excess light by a photoprotective reduction of the light harvesting efficiency. The notion that the non-photochemical quenching of chlorophyll fluorescence can be reliably used as an indicator of the photoprotection is put to a test here. The technique of the repetitive flash fluorescence induction is employed to measure in parallel the non-photochemical quenching of the maximum fluorescence and the functional cross-section (sigma(PS II)) which is a product of the photosystem II optical cross-section a(PS II) and of its photochemical yield Phi(PS II) (sigma (PS II) = a(PS II) Phi(PS II)). The quenching is measured for both, the maximum fluorescence found in a single-turnover flash (F(M) (ST)) and in a multiple turnover light pulse (F(M) (MT)). The experiment with the diatom Phaeodactylum tricornutum confirmed that, in line with the prevalent model, the PS II functional cross-section sigma (PS II) is reduced in high light and restored in the dark with kinetics and amplitude that are closely matching the changes of the F(M) (ST) and F(M) (MT) quenching. In contrast, a poor correlation between the light-induced changes in the PS II functional cross-section sigma (PS II) and the quenching of the multiple-turnover F(M) (MT) fluorescence was found in the green alga Scenedesmus quadricauda. The non-photochemical quenching in Scenedesmus quadricauda was further investigated using series of single-turnover flashes given with different frequencies. Several mechanisms that modulate the fluorescence emission in parallel to the Q(A) redox state and to the membrane energization were resolved and classified in relation to the light harvesting capacity of Photosystem II.     

PROTEINACEOUS AND IMMUNOCHEMICAL DISTINCTIONS BETWEEN THE OVAL AND FUSIFORM MORPHOTYPES OF PHAEODACTYLUM TRICORNUTUM (BACILLARIOPHYCEAE)1

Two morphotypes, fusiform and oval, were isolated from a single clone of the diatom Phaeodactylum tricornutum Bohlin and maintained as subclones by culturing in liquid and solid substrates, respectively. Salinity of the medium, from brackish to marine, had no effect on expression of the phenotypes. The oval cell is generated endogenously within a “transformed”fusiform cell upon transfer from liquid medium to agar plates. With the light microscope, normal and “transformed”fusiform cells, prior to giving rise to oval cells, can be discriminated by means of their staining response to toluidine blue. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of protein extracts from lysed cells revealed slight differences in polypeptide composition between fusiform and oval types. A phenotype-restoration experiment from oval to fusiform demonstrated that the oval type readily reestablished not only fusiform morphology but also the protein pattern characteristic for the fusiform type. Immunochemical analyses (western blots) using antisera raised against whole and lysed cells of both morphotypes revealed antigenic alterations of the oval morphotype. Several antigenic determinants restricted mainly to the surface of oval cells were detected. Results indicate that environmentally induced phenotypes of Phaeodactylum may be not only the consequence of specific gene expression but also the result of significant, general post-translational modifications.     

Limitations on microalgal growth at very low photon fluence rates: the role of energy slippage

The lower limits of photosynthetically useable radiation at which growth and photosynthesis can occur establish the lower boundaries for the extent of photolithotrophy in the biosphere. Photolithotrophic growth denotes the capacity to grow with photons as the sole energy input. Slippage in terms of photosynthetic energy conversion implies a less than theoretical stoichiometry of energy-transduction process(es) such as the dissipation of intermediates of O₂ evolution and of ATP synthesis (H⁺/e⁻ and H⁺/ATP ratios). Slippage is particularly important in limiting the growth of photolithotrophic organisms at very low photon fluence rates. We found that Dunaliella tertiolecta and Phaeodactylum tricornutum avoid such reductions in photon use efficiency by increasing the size and number of their photosynthetic units, respectively, and by altering Q_A reduction kinetics on the reducing side of PS II. P. tricornutum is also less susceptible to slippage in terms of the breakdown of intermediates in its O₂ evolution pathway than D. tertiolecta. Minimizing H⁺ leakage through the CF₀–CF₁ ATP synthetase (and other H⁺ porters) is also discussed briefly. In combination, strategies employed by P.␣tricornutum effectively allow it to grow and photosynthesize at lower rates of energy input than D. tertiolecta, consistent with our observations. Differences in the responses of the photosynthetic apparatus of these two marine microalgae are mechanistic and probably representative of evolutionary divergences associated with strategies for dealing with environmental perturbations.     

The metabolic blueprint of Phaeodactylum tricornutum reveals a eukaryotic Entner-Doudoroff glycolytic pathway

Diatoms are one of the most successful groups of unicellular eukaryotic algae. Successive endosymbiotic events contributed to their flexible metabolism, making them competitive in variable aquatic habitats. Although the recently sequenced genomes of the model diatoms Phaeodactylum tricornutum and Thalassiosira pseudonana have provided the first insights into their metabolic organization, the current knowledge on diatom biochemistry remains fragmentary. By means of a genome‐wide approach, we developed DiatomCyc, a detailed pathway/genome database of P. tricornutum. DiatomCyc contains 286 pathways with 1719 metabolic reactions and 1613 assigned enzymes, spanning both the central and parts of the secondary metabolism of P. tricornutum. Central metabolic pathways, such as those of carbohydrates, amino acids and fatty acids, were covered. Furthermore, our understanding of the carbohydrate model in P. tricornutum was extended. In particular we highlight the discovery of a functional Entner–Doudoroff pathway, an ancient alternative for the glycolytic Embden–Meyerhof–Parnas pathway, and a putative phosphoketolase pathway, both uncommon in eukaryotes. DiatomCyc is accessible online ( http://www.diatomcyc.org ), and offers a range of software tools for the visualization and analysis of metabolic networks and ‘omics’ data. We anticipate that DiatomCyc will be key to gaining further understanding of diatom metabolism and, ultimately, will feed metabolic engineering strategies for the industrial valorization of diatoms.     

Protein turnover in relation to maintenance metabolism at low photon flux in two marine microalgae

Acclimation to very low photon fluxes involves adjusting a suite of physiological characteristics that collectively elicit a physiological response. Facilitating such changes is pro‐tein turnover. Dunaliella tertiolecta (Butcher) and Phaeodactylum tricornutum (Bohlin) were grown in turbidostats at a range of photon fluxes between 2 and 300 µmol photons m^?2 s^?1. The kinetics of pulse‐chase labelling of the protein with ³H showed that (1) two protein pools were present, one of which turned‐over rapidly (hours), and a second which turned over more slowly (days); and (2) protein turnover rates were slower in P. tricornutum than in D. tertiolecta. Phaeodactylum tricornutum had a lower maintenance coefficient for protein turnover than D. tertiolecta, and correspondingly a smaller proportion of its respiratory demands (30%) were associated with protein turnover than in D. tertiolecta (36%). There appears to be a correlation between lower metabolic activity, requiring lower protein concentrations, and an associated decreased cost of maintenance processes in P. tricornutum compared to D. tertiolecta. Differences between protein turnover rates and maintenance metabolic costs may be one of the photo‐acclimation strategies that determine which photon niches microalgae can successfully exploit.     

Production of 13C polyunsaturated fatty acids from the microalga Phaeodactylum tricornutum

An integrated process for the indoor production of ¹³C labelled PUFA from Phaeodactylum tricornutum is presented. The core of the process is a bubble column photobioreactor from which the exhaust gas from the reactor is returned to the culture by a low pressure compressor. To avoid accumulation of dissolved oxygen in the culture medium, the exhaust gas is bubbled through a sodium sulphite solution before returning it to the reactor. Carbon is removed from the medium before inoculating the alga, then labelled ¹³CO₂ is injected for pH control and carbon supply. The reactor has been operated in semicontinuous mode at a dilution rate of 0.01 h^–1, a biomass productivity of 0.1 g L^–1 d^–1 being obtained. Under this conditions both pH and dissolved oxygen were correctly controlled and the adequacy of the system for autotrophic production of labelled biomass was demonstrated. Analysis by GC-MS revealed that the fatty acids content of the biomass obtained was 10% d.wt., the content of eicosapentaenoic acid was 2.5% d.wt. All the fatty acids were labelled, more that 90% of the carbon present in these fatty acids was ¹³C. Element analysis of biomass and supernatant showed that 59.5% of injected carbon was assimilated into the biomass whereas 33% remained in the supernatant, and 7.5% remained undetected. Due to the high cost of ¹³CO₂ different strategies for the optimisation of labelled carbon use are proposed.     

ISOLATION OF ALGAL GENES BY FUNCTIONAL COMPLEMENTATION OF YEAST1

Algal cDNAs were isolated and characterized by functional complementation of yeast auxotrophs. Two cDNA libraries, one derived from the diatom Phaeodactylum tricornutum Bohlin and the other from the dinoflagellate Crypthecodinium cohnii Biecheler, were constructed using the Saccharomyces cerevisiae expression vector pFL‐61. These libraries were used for functional complementation of auxotrophic markers in two yeast strains. Yeast tryptophan auxotrophs, complemented by the P. tricornutum library, contained a plasmid that encoded a two‐domain protein associated with tryptophan synthesis, indole‐3‐glycerol phosphate synthase‐N‐(5′‐phosphoribosyl) anthranilate isomerase. Another cDNA originating from the C. cohnii library rescued S. cervisiae from a defect in adenine biosynthesis. This cDNA encoded a fusion of phosphoribosylamidoimidazole‐succinocarboxamide synthetase and phosphoribosylaminoimidazole carboxylase, which correspond to the yeast ade1 and ade2 genes, respectively. These results demonstrate that heterologous functional complementation can be used to identify algal genes and may provide advantages over other gene discovery methods.     

Effects of Metal Combinations on the Production of Phytochelatins and Glutathione by the Marine Diatom Phaeodactylum tricornutum

Copper, Cd and Zn can be found at elevated concentrations in contaminated estuarine and coastal waters and have potential toxic effects on phytoplankton species. In this study, the effects of these metals on the intracellular production of the polypeptides phytochelatin and glutathione by the marine diatom Phaeodactylum tricornutum were examined in laboratory cultures. Single additions of Cu and Cd (0.4 μM Cu² and 0.45 μM Cd²⁺) to the culture medium induced the production of short-chained phytochelatins ((γ-Glu-Cys)_n-Gly where n = 2–5), whereas a single addition of Zn (2.2 μM Zn²⁺) did not stimulate phytochelatin production. Combination of Zn with Cu resulted in a similar phytochelatin production compared with a single Cu addition. The simultaneous exposure to Zn and Cd led to an antagonistic effect on phytochelatin production, which was probably caused by metal competition for cellular binding sites. Glutathione concentrations were affected only upon exposure to Cd (85% increase) or the combination of Cd with Zn (65% decrease), relative to the control experiment. Ratios of phytochelatins to glutathione indicated a pronounced metal stress in response to exposures to Cu or Cd combined with Zn. This study indicates that variabilities in phytochelatin and glutathione production in the field can be explained in part by metal competition for cellular binding sites.     

氯化铁和聚丙烯酰胺絮凝剂WT652对三角褐指藻的絮凝作用

生物柴油是清洁的可再生能源, 是优质的石油柴油代用品, 但生物柴油产业受原料供给和成本的制约。硅藻富含油(占细胞干重40%-60%)1, 且短链脂肪酸(C14 和C16)占细胞中总脂肪酸的67%-70%左右2,3。三角褐指藻作为硅藻研究的模式种类之一, 细胞壁含硅较少, 利于破碎, 可作为优良的生物柴油生产原料。