PHOTOSYNTHETIC PIGMENT COMPOSITION IN THE PRIMITIVE GREEN ALGA MESOSTIGMA VIRIDE (PRASINOPHYCEAE): PHYLOGENETIC AND EVOLUTIONARY IMPLICATIONS1

The photosynthetic pigment composition of Mesostigma viride Lauterborn, a primitive green alga, was determined. This alga contained chl a and b, lycopene, lutein, siphonaxanthin, γ‐carotene, β‐carotene, antheraxanthin, violaxanthin, neoxanthin, and two novel carotenoid fatty acid esters, siphonaxanthin C12:0 ester and siphonaxanthin C14:0 ester. The esters were saturated, whereas all previously identified siphonaxanthin and loroxanthin esters have been mono‐unsaturated (trans‐Δ2). Neoxanthin was the all‐trans form. This is the first such case detected in the chloroplasts of green plants. The 9′‐cis form of neoxanthin is believed to be universally present in the chloroplasts of green plants (Streptophyta and Chlorophyta) and is a precursor of abscisic acid. However, the 9′‐cis form was not found in M. viride. Based on these results, we discuss the phylogenetic implications and early evolution of the antenna pigment system in green plants.     

CHARACTERIZATION OF TWO UNIQUE CAROTENOID FATTY ACID ESTERS FROM PTEROSPERMA CRISTATUM (PRASINOPHYCEAE,CHLOROPHYTA)1

Carotenoid composition and spectroscopic characteristics were analyzed for Pterosperma cristatum Schiller, one of the most primitive known members of green algae. This alga contained a substantial amount of carotenoid esters, siphonaxanthin C14:1 trans‐Δ2 ester and 6′‐OH siphonaxanthin C14:1 trans‐Δ2 ester, but lacked lutein. This is the first report of carotenoid C14:1 trans‐Δ2 esters from phototrophic organisms. In vivo absorption spectra and excitation spectra of the cells revealed that these carotenoids absorbed blue‐green light and could transfer energy to chl a. These carotenoids were concluded to function as antenna pigments in P. cristatum.     

CAROTENOIDS OF SIPHONOUS GREEN ALGAE: A CHEMOTAXONOMICAL STUDY

The carotenoid pigments of 50 species of 9 siphonean orders were investigated. The algae of all orders contain the principal carotenoids known from other green algae: α- and β-carotene, lutein, lutein epoxide, violaxanthin, and neoxanthin. Additionally, in some Siphonodadales siphonaxanthin is present, in the Derbesiales, Codiales, and Caulerpales both siphonaxanthin and its ester siphonein are present, whereas in the Dichotomosiphonales only the ester siphonein can be found. The chemotaxonomical value of siphonaxanthin and siphonein is discussed.     

Stereoisomers of beta-Carotene and Phytoene in the Alga Dunaliella bardawil

Dunaliella bardawil, a halotolerant green alga, was previously shown to accumulate high concentrations of β-carotene when grown outdoors under defined conditions. The β-carotene of algae cultivated under high light intensity in media containing a high salt concentration is composed of approximately 50% all-trans β-carotene and 40% 9-cis β-carotene. We show here that the 9-cis to all-trans ratio is proportional to the integral light intensity to which the algae are exposed during a division cycle. In cells grown under a continuous white light of 2000 microeinsteins per square meter per second, the ratio reached a value of around 1.5, while in cells grown under a light intensity of 50 microeinsteins per square meter per second, the ratio was around 0.2. As previously shown, algae treated with the herbicide norflurazon accumulate phytoene in place of β-carotene. Electron micrographs showed that the phytoene is accumulated in many distinct globules located in the interthylakoid spaces of the chloroplast. Here too, two isomers are present, apparently all-trans and 9-cis phytoene, and their ratio is dependent upon the integral light intensity to which the algae are exposed during a division cycle. In the presence of norflurazon, Dunaliella bardawil grown under a light intensity of 2000 microeinsteins per square meter per second contained about 8% phytoene with a 9-cis to all-trans ratio of about 1.0. This ratio decreased to about 0.1 when the light intensity was reduced to 50 microeinsteins per square meter per second. These data suggest that the isomerization reaction which leads to the production of the 9-cis isomer occurs early in the path of carotene biosynthesis, at or before the formation of all-trans phytoene. The presence of the 9-cis isomer of β-carotene and the dependence of its preponderance on light intensity seem to be a common feature of many plant parts. Thus carrots which are exposed to minimal light contain no 9-cis isomer while sun-exposed leaves, fruits, and flowers contain 20 to 50% of the 9-cis isomer.     

Far-red light inhibits growth but promotes carotenoid accumulation in the green microalga Dunaliella bardawil

It has been demonstrated that far-red light reduces growth of marine phytoplankton and that light quality controls growth and photosynthetic metabolism in algae. The green halotolerant microalga, Dunaliella bardawil, accumulates high amounts of β-carotene (up to 10% of its dry weight) under conditions of high light or nutrient limitation. The influence of increasing irradiance and of far-red light in D. bardawil was studied. Continuous irradiance was provided by white fluorescent lamps alone (WL) or supplemented with far-red Linestra lamps (WL+FR). For both types of light, cultures were acclimatized at increasing irradiances (50-300 µmol m^?2 s^?1), and cell density, photosynthetic activity and pigment content were determined. Cell density increased with the photon irradiance, and was higher in WL than in WL+FR under the same irradiance, but the reverse occurred in respect of cell volume. Growth rate was higher under WL+FR. Far-red light induced faster growth but reduced the maximal cell density of the cultures. Chlorophyll a concentration was higher in white light, but total carotenoid content increased dramatically in both far-red light treatments (about 50% on a per cell basis) and with the increase of irradiance. Our results show that far-red light has a significant influence on growth and photosynthesis of D. bardawil, inducing a decrease in cell density, photosynthetic activity and chlorophyll concentration, and an increase in growth rate, cell volume and carotenoid content.     

Light-Related Photosynthetic Characteristics of Lotic Macroalgae

Photosynthetic characteristics in response to irradiance were analysed in 42 populations of 33 macroalgal species by two distinct techniques (chlorophyll fluorescence and oxygen evolution). Photosynthesis–irradiance (PI) curves based on the two techniques indicated adaptations to low irradiance reflected by low saturation values, high to moderate values of photosynthetic efficiency (α) and photoinhibition (β), for Bacillariophyta and Rhodophyta, which suggests they are typically shade-adapted algae. In contrast, most species of Chlorophyta were reported as sun adapted algae, characterized by high values of I _k and low of α, and lack of or low photoinhibition. Cyanophyta and Xanthophyta were intermediate groups in terms of light adaptations. Photoinhibition was observed in variable degrees in all algal groups, under field and laboratory conditions, which confirms that it is not artificially induced by experimental conditions, but is rather a common and natural phenomenon of the lotic macroalgae. Low values of compensation irradiance (I _c) were found, which indicate that these algae can keep an autotrophic metabolism even under very low irradiances. High ratios (>2) of photosynthesis/respiration were found in most algae, which indicates a considerable net gain. These two physiological characteristics suggest that macroalgae may be important primary producers in lotic ecosystems. Saturation parameters (I _k and I _s) occurred in a relatively narrow range of irradiances (100–400 μmol photons m^?2s^?1), with some exceptions (higher in some filamentous green algae or lower in red algae). These parameters were way below the irradiances measured at collecting sites for most algae, which means that most of the available light energy was not photochemically converted via photosynthesis. Acclimation to ambient PAR was observed, as revealed by lower values of I _k and I _cand higher values of α and quantum yield in algae from shaded streams, and vice versa. Forms living within the boundary layer (crusts) showed responses of shade-adapted species and had the highest values of P _max, α and quantum yield, whereas the opposite trend was observed in gelatinous forms (colonies and filaments). These results suggests adaptation to the light regime rather than functional attributes related to the growth form.     

Chlorophyll-protein complexes of a Codium species,including a light-harvesting siphonaxanthin-Chlorophylla ab-protein complex,an evolutionary relic of some Chlorophyta

Eight chlorophyll-protein complexes were isolated from thylakoid membranes of a Codium species, a marine green alga, by mild SDS-polyacrylamide gel electrophoresis. CP 1a¹, CP 1a², CP 1a³ and CP 1a⁴ were partially dissociated Photosystem (PS) I complexes, which in addition to the core reaction centre complex, CP 1, possessed PS I light-harvesting complexes containing chlorophyll (Chl) a, Chl b and siphonaxanthin. LHCP¹ and LHCP³ are orange-brown green chlorophyll $\text{a}\text{b-}\text{proteins}$ ($\text{Chl}\text{a}\text{Chl}\text{b}$ ratios of 0.66) that contain siphonaxanthin and its esterified form, siphonein. CP a and CP 1, the core reaction centre complexes of PS II and PS I, respectively, had similar spectral properties to those isolated from other algae or higher plants. These P-680- or P-700-Chl a-proteins are universally distributed among algae and terrestrial plants; they appear to be highly conserved and have undergone little evolutionary adaptation. Siphonaxanthin and siphonein which are present in the Codium light-harvesting complexes of PS II and PS I are responsible for enhanced absorption in the green region (518 and 538 nm). Efficient energy transfer from both xanthophylls and Chl b to only Chl a in Codium light-harvesting complexes, which have identical fluorescence emission spectra at 77 K to those of the lutein-Chl $\text{a}\text{b-}\text{proteins}$ ($\text{Chl}\text{a}\text{Chl}\text{b}$ ratios of 1.2) of most green algae and all higher plants, proved that the molecular arrangement of these light-harvesting pigments was maintained in the isolated Codium complexes. The siphonaxanthin-Chl $\text{a}\text{b-}\text{proteins}$ allow enhanced absorption of blue-green and green light, the predominant light available in deep ocean waters or shaded subtidal marine habitats. Since there is a variable distribution of lutein, siphonaxanthin and siphonein in marine green algae and siphonaxanthin is found in very ancient algae, these novel siphonein-siphonaxanthin-Chl $\text{a}\text{b-}\text{proteins}$ may be ancient light-harvesting complexes which were evolved in deep water algae.     

CAROTENOID COMPOSITIONS OF CLADOPHORA BALLS (AEGAGROPILA LINNAEI) AND SOME MEMBERS OF THE CLADOPHORALES (ULVOPHYCEAE,CHLOROPHYTA): THEIR TAXONOMIC AND EVOLUTIONARY IMPLICATION1

Photosynthetic pigments were analyzed by HPLC for 27 samples of the Cladophorales (Ulvophyceae, Chlorophyta). The carotenoid compositions of the examined algae were classified into three types based on the final compound of biosynthesis of the α‐carotene branch: lutein type, characterized by containing lutein as a major carotenoid and lacking loroxanthin and siphonaxanthin; loroxanthin type, characterized by containing loroxanthin and lacking siphonaxanthin; and siphonaxanthin type, characterized by containing siphonaxanthin. We constructed molecular phylogenetic tree of the species examined in the present study using 18S rRNA gene sequences and mapped the carotenoid types of the species onto the tree. The molecular phylogenetic analysis divided the Cladophorales into two major clades, clade 1 and Aegagropila‐clade (clade 2), and divided clade 1 into subclade 1‐1 and subclade 1‐2. All the examined species positioned in the Aegagropila‐clade and those of the subclade 1‐1 belonged to the loroxanthin type, whereas both lutein type and siphonaxanthin type appeared only in the subclade 1‐2. The clades delineated by molecular phylogenetic analysis were congruent with distribution of the carotenoid types, indicating that the carotenoid types are of taxonomic significance in the Cladophorales. Considering the distribution pattern of these carotenoid types and minimum state changes in the Cladophorales, we concluded that the loroxanthin type was the primitive (plesiomorphic) state and the siphonaxanthin type and lutein type appeared in the subclade 1‐2 as advanced (apomorphic) state within this order and suggested that the cladophoralean siphonaxanthin type would have been secondarily acquired.     

The Effect of Salt Stress on the Production of Canthaxanthin and Astaxanthin by Chlorella zofingiensis Grown Under Limited Light Intensity

The fresh water green microalga Chlorella zofingiensisis known to accumulate ketocarotenoids – primarily astaxanthin but also canthaxanthin – when grown under stress conditions of high light irradiance and low nitrogen. We found that salt stress can replace light stress with respect to inducing carotenoid production: cells of C. zofingiensis grown under low light irradiance and subjected to salt and low nitrogen stress accumulated higher amounts of total secondary carotenoids than those growing under high light and low nitrogen stress. Furthermore, C. zofingiensis growing under conditions of salt stress and low light accumulated higher amounts of canthaxanthin than astaxanthin. It is suggested that for canthaxanthin accumulation under salt stress, light is not a limiting factor, but for astaxanthin accumulation high light irradiance is mandatory. These results may be applied in the future for the commercial production of canthaxanthin by C. zofingiensis in systems in which light availability is poor.     

Effects of light intensity and quality on the growth rate and photosynthetic pigment content of Spirulina platensis

The quantitative and qualitative effects of light on carotenoid production by Spirulina were studied. Maximum total carotenoid production was measured in cells grown under white light at an irradiance of 432 μmol photon m^?2 s^?1, the onset of light saturation for this organism as determined by growth rates. A true maximum may exist at irradiances above 1500 μmol photon m^?2 s^?1 under white light. Individual carotenoids responded differently to light conditions. Under white light, β-carotene and echinenone were most abundant at the lowest and highest irradiance levels tested. Myxoxanthophyll and lutein/zeaxanthin did not change over the same irradiance range. Under red and blue light, we found decreased values of myxoxanthophyll, while β-carotene increased and lutein/zeaxanthin and echinenone showed little change. In general, maximum carotenoid production requires optimization of the culture conditions that favor growth.     

Enhancement of carotenoid biosynthesis in the green microalga Dunaliella salina with light-emitting diodes and adaptive laboratory evolution

There is a particularly high interest to derive carotenoids such as β-carotene and lutein from higher plants and algae for the global market. It is well known that β-carotene can be overproduced in the green microalga Dunaliella salina in response to stressful light conditions. However, little is known about the effects of light quality on carotenoid metabolism, e.g., narrow spectrum red light. In this study, we present UPLC-UV-MS data from D. salina consistent with the pathway proposed for carotenoid metabolism in the green microalga Chlamydomonas reinhardtii. We have studied the effect of red light-emitting diode (LED) lighting on growth rate and biomass yield and identified the optimal photon flux for D. salina growth. We found that the major carotenoids changed in parallel to the chlorophyll b content and that red light photon stress alone at high level was not capable of upregulating carotenoid accumulation presumably due to serious photodamage. We have found that combining red LED (75 %) with blue LED (25 %) allowed growth at a higher total photon flux. Additional blue light instead of red light led to increased β-carotene and lutein accumulation, and the application of long-term iterative stress (adaptive laboratory evolution) yielded strains of D. salina with increased accumulation of carotenoids under combined blue and red light.     

Carotenoid content in growing cells of Haematococcus pluvialis during a sunlight cycle

Under certain culture conditions, cells of the chlorophyte Haematococcus pluvialis accumulate significant amounts of astaxanthin. This study describes biomass and carotenoid production during a sunlight cycle in a continuous culture of growing cells of H. pluvialis and shows that these two parameters are under the control of irradiance. The hourly carotenoid production increases with light intensity and, in our culture conditions, carotenoid accumulation occurs in a few hours and without any morphological change in the algae. These carotenoids seem to be efficient in protecting algal cells against photoinhibition damage if their content is greater than 1% dry biomass. Below this concentration, that is to say in the early hours of high light intensity, dry biomass decreases due to cell lysis. The results demonstrate that secondary carotenoid accumulation in H. pluvialis may occur in the active growth phase and is stimulated from the first hours of sunlight illumination.     

Spectral and functional studies on siphonaxanthin-type light-harvesting complex of photosystem II from Bryopsis corticulans

Carotenoids with conjugated carbonyl groups possess special photophysical properties which have been studied in some water-soluble light-harvesting proteins (Polívka and Sundström, Chem Rev 104:2021–2071, 2004). However, siphonaxanthin-type light-harvesting complexes of photosystem II (LHCII) in siphonous green alga have received fewer studies. In the present study, we determined sequences of genes for several Bryopsis corticulans Lhcbm proteins, which showed that they belong to the group of major LHCII and diverged early from green algae and higher plants. Analysis of pigment composition indicated that this siphonaxanthin-type LHCII contained in total 3 siphonaxanthin and siphonein but no lutein and violaxanthin. In addition, 2 chlorophylls a in higher plant LHCII were replaced by chlorophyll b. These changes led to an increased absorption in green and blue-green light region compared with higher plant LHCII. The binding sites for chlorophylls, siphonaxanthin, and siphonein were suggested based on the structural comparison with that of higher plant LHCII. All of the ligands for the chlorophylls were completely conserved, suggesting that the two chlorophylls b were replaced by chlorophyll a without changing their binding sites in higher plant LHCII. Comparisons of the absorption spectra of isolated siphonaxanthin and siphonein in different organic solutions and the effect of heat treatment suggested that these pigments existed in a low hydrophobic protein environment, leading to an enhancement of light harvesting in the green light region. This low hydrophobic protein environment was maintained by the presence of more serine and threonine residues in B. corticulans LHCII. Finally, esterization of siphonein may also contribute to the enhanced harvesting of green light.     

A Yellow Marine Chiamydomonas: Morphology and Pigment Composition

A unicellular yellow marine microorganism was isolated fromwater samples collected in Hachinohe Harbor, on the northerncoast of Japan, and Off Tsushima Island, on the western coastof Japan, and its structure and pigment composition were investigated.Light and electron microscopy indicated that the alga belongsto the genus Chlamydomonas and it is identified as C. parkeae. Pigment analysis by high-performance liquid chromatography revealedthe presence of 2,4-divinylprotochlorophyllide (DVP) as a thirdchlorophyll in addition to chlorophylls a and b. Such a pigmentcomposition has been reported previously only for some prasinophytesamong autotrophically grown algae. With respect to carotenoids,the alga contains, in addition to the carotenoids of higherplants (neoxanthin, violaxanthin, zeaxanthin, lutein, ß-carotene),siphonaxanthin and siphonein (siphonaxanthin dodecenoate); thelatter have been detected previously only in marine benthiculvophycean algae and in some prasinophytes. However, the coexistenceof DVP, siphonein and siphonaxanthin in a single species hasnever been reported for either ulvophycean or prasinophyceanalgae. In addition to siphonaxanthin dodecenoate, the alga wasfound to contain two "siphoneins", siphonaxanthin decenate andsiphonaxanthin octanoate. ³ Present address: Nippon Roche Research Center, Kajiwara, Kamakura,Kanagawa, 247 Japan.     

VARIATION OF SIPHONAXANTHIN SERIES AMONG THE GENUS NEPHROSELMIS (PRASINOPHYCEAE,CHLOROPHYTA), INCLUDING A NOVEL PRIMARY METHOXY CAROTENOID1

Carotenoid compositions were analyzed for ten strains of Nephroselmis (Prasinophyceae) containing four described and three undescribed species. Based on the distribution pattern of the siphonaxanthin series, five carotenoid types were recognized in the examined strains/species: type I (N. astigmatica Inouye et Pienaar, N. pyriformis (N. Carter) Ettl, and Nephroselmis sp1. MBIC 11158) had siphonaxanthin C12:1 and C14:1 esters as well as 6′‐OH siphonaxanthin C12:1 and C14:1 esters, type II (Nephroselmis sp2. MBIC 11149) had siphonaxanthin C8:1 ester, type III (Nephroselmis sp3. NIES 486, NIES‐PS 535, and MBIC 10871) had 19‐methoxy siphonaxanthin and siphonaxanthin C12:1 and C14:1 esters, type IV (N. spinosa Suda) had only a small amount of siphonaxanthin C12:1 ester, and type V (N. olivacea Stein) had lutein as a major carotenoid but completely lacked the siphonaxanthin series. 19‐Methoxy siphonaxanthin was a novel and very unique carotenoid, that is, it contains a methoxy group and was found for the first time in photosynthetic eukaryotes. Additionally, carotenoids containing a primary methoxy group had previously never been found in any group of organisms. Siphonaxanthin C8:1 ester, which was only known as a trace carotenoid in Chlamydomonas parkeae Ettl, was first discovered as a major carotenoid in Nephroselmis sp2. (MBIC 11149). Based on these results and comparison of the phylogenetic relationships of the Nephroselmis species used, we discuss the taxonomic significance of the carotenoid types and evolutionary process of the photosynthetic antenna systems in green plants.     

Spectral characteristics of fluorophores formed via interaction between all-trans-retinal with rhodopsin and lipids in photoreceptor membrane of retina rod outer segments

It is shown that all-trans-retinal under model conditions of its excessive accumulation in photoreceptor membranes interacts with amino groups of rhodopsin and lipids, forming at least three distinct fluorophores with fluorescence quantum yield 20–40 times higher than that of free all-trans-retinal. These retinal derivatives are likely precursors of photo- and cytotoxic fluorophores of lipofuscin and in particular of A2E. Spectral characteristics of fluorophores have been described. Picosecond time-resolved laser fluorescence spectroscopy was used to study kinetics of fluorescence decay of both free and bound all-trans-retinal; fluorophores were determined and their lifetimes have been measured. Based on calculations it is shown that the decay kinetics of all-trans-retinal derivatives consists of three components with lifetimes equal to 48, 208, and 900 ps; kinetics of free all-trans-retinal is monoexponential with lifetime of 31 ps. The chemical nature of fluorophores with the lifetimes obtained is discussed.     

Diversity and evolution of photosynthetic antenna systems in green plants

Photosynthetic antenna systems are mainly involved in the absorption of light energy required for photosynthesis. The typical green plants arrange chlorophylls a and b and carotenoids, including lutein and 9′‐cis neoxanthin, in their antenna systems; such antenna systems have prospered on earth. Therefore, these antenna systems should be highly evolved and should adapt to the photoenvironments in which plants grow. However, little information is available on the diversity and evolution of antenna systems in green plants as a whole. To approach this, the present study focused on the antenna systems in the Prasinophyceae, an assemblage of early diverging lineages of green plants and analyzed their photosynthetic pigments in detail. In the present study, various novel blue–green light‐absorbing siphonaxanthin series were detected in the early diverging species of the Prasinophyceae and the distribution of these carotenoids was revealed. Additionally, to clarify the evolution of antenna systems in the Ulvophyceae, a highly developed green algal group that specializes in inhabiting various aquatic environments, members of the Cladophorales belonging to this class were selected and their carotenoid compositions were determined to compare them with the molecular phylogenetic tree constructed on the basis of the 18S rRNA gene sequences of the Cladophorales. In this review, these data will be summarized and the remarkable variation of photosynthetic pigments will be presented. A possible scenario detailing the evolution of antenna systems in green plants will be elucidated.     

Preparation of labelled terpenyl pyrophosphates using extracts of barley seed embryos

A cell-free system derived from seed embryos of barley (Hordeum vulgare cv. Zephyr) grain has been used to prepare substrate quantities of radioactively-labelled C₅-C₂₀ intermediates of terpenoid biosynthesis. The purification and characterization of high specific activity all-trans farnesyl-[4, 8, 12-³H] and all-_trans geranylgeranyl-[4, 8, 12, 16-³H] pyrophosphates, suitable for use in studies of sterol and carotenoid biosynthesis, are described in detail. The effects of the plant growth retardant AMO 1618 on the system are reported.     

Light-induced efficiency and pigment alterations in red algae

The low photosynthetic efficiency of chlorophyll in freshly collected red algae, can, in the case of Porphyra perforata, P. nereocystis, and Porphyridium cruentum, be increased by growing the algae for 10 days in red or blue light. Exposure to darkness or to green light maintains the algae in their originally low efficiency with respect to chlorophyll, while retaining the high efficiency of phycobilins. Red- or blue-adapted algae are rapidly reversed by exposure to green light, the chlorophyll efficiency dropping to low values again in a few hours. This is assumed to account for the action spectrum of freshly gathered plants. Some pigment changes were observed, but not in the direction of "chromatic adaptation;" and the carotenoid pigments were not activated, even by blue light, but remained as photosynthetically inactive shading filters. The higher red algae (Florideae) did not show activation of chlorophyll by red or blue light.