Growth under Red Light Enhances Photosystem II Relative to Photosystem I and Phycobilisomes in the Red Alga Porphyridium cruentum

Acclimation of the photosynthetic apparatus to light absorbed primarily by photosystem I (PSI) or by photosystem II (PSII) was studied in the unicellular red alga Porphyridium cruentum (ATCC 50161). Cultures grown under green light of 15 microeinsteins per square meter per second (PSII light; absorbed predominantly by the phycobilisomes) exhibited a PSII/PSI ratio of 0.26 ± 0.05. Under red light (PSI light; absorbed primarily by chlorophyll) of comparable quantum flux, cells contained nearly five times as many PSII per PSI (1.21 ± 0.10), and three times as many PSII per cell. About 12% of the chlorophyll was attributed to PSII in green light, 22% in white light, and 39% in red light-grown cultures. Chlorophyll antenna sizes appeared to remain constant at about 75 chlorophyll per PSII and 140 per PSI. Spectral quality had little effect on cell content or composition of the phycobilisomes, thus the number of PSII per phycobilisome was substantially greater in red light-grown cultures (4.2 ± 0.6) than in those grown under green (1.6 ± 0.3) or white light (2.9 ± 0.1). Total photosystems (PSI + PSII) per phycobilisome remained at about eight in each case. Carotenoid content and composition was little affected by the spectral composition of the growth light. Zeaxanthin comprised more than 50% (mole/mole), β-carotene about 40%, and cryptoxanthin about 4% of the carotenoid pigment. Despite marked changes in the light-harvesting apparatus, red and green light-grown cultures have generation times equal to that of cultures grown under white light of only one-third the quantum flux.     

Phycobilisomes of Porphyridium cruentum. I. Isolation

A procedure was developed for the isolation of phycobilisomes from Porphyridium cruentum. The cell homogenate, suspended in phosphate buffer (pH 6.8), was treated with 1% Triton X-100, and its supernatant fraction was centrifuged on a sucrose step gradient. Phycobilisomes were recovered in the 1 M sucrose band. The phycobilisome fraction was identified by the characteristic appearance of the phycobilisomes, and the absorbance of the component pigments: phycoerythrin, R-phycocyanin, and allophycocyanin Isolated phycobilisomes had a prolate shape, with one particle axis longer than the other. Their size varied somewhat with their integrity, but was about 400–500 A (long axis) by 300–320 A (short axis). Phycobilisome recovery was determined at six phosphate buffer concentrations from 0.067 M to 1.0 M. In 0.5 M phosphate, phycobilisome yield (60%) and preservation were optimal. Such a preparation had a phycoerythrin 545 nm/phycocyanin 620 nm ratio of 8.4. Of the detergents tested (Triton X-100, Tween 80, and sodium deoxycholate), Triton X-100 gave the best results Freezing of the cells caused destruction of phycobilisomes.     

Irradiance Effects on Thylakoid Membranes of the Red Alga Porphyridium cruentum. An Immunocytochemical Study

Immunogold labelling on ultrathin sections of the red alga Porphyridiumcruentum (ATCC 50161) was used to assess changes in the densityand distribution of polypeptide components of photosystem I,photosystem II, phycobilisomes, and ATP synthase within thethylakoid membrane as a function of growth irradiance. In cellsgrown under a low, limiting quantum flux (6 microeinsteins persquare meter per second of continuous white light) thylakoidmembrane density and total thylakoid area per cell are 2 1/2times greater than in cells grown under a high, saturating quantumflux (280 microeinsteins per square meter per second). Immunogoldlabelling data indicate that concentrations of photosystem I,photosystem II and phycobilisomes in thylakoids of low light-growncells are only slightly greater than in cells grown under highlight. In contrast, the concentration of ATP synthase withinthe thylakoid membrane is nearly ten times greater in high light-growncells. Photosystem I polypeptides were detected in those portionsof the thylakoid membrane which traverse the pyrenoid, but photosystemII and phycobilisomes appeared to be absent from these membranes.Ribulose-l,5-bisphosphate carboxylase was restricted primarilyto the pyrenoid, and its concentration in the stroma or pyrenoidwas little affected by the photon flux density. Quantitativeestimates of photosystems I and II, phycobilisomes, and ATPsynthase by spectroscopy or by immunoelectrophoresis are inaccord with the immunogold results and lend support to the useof immunogold labelling for quantifying changes in relativeamounts of membrane proteins. (Received October 29, 1990; Accepted February 4, 1991)     

Photoacclimation in the Red Alga Porphyridium cruentum: Changes in Photosynthetic Enzymes, Electron Carriers, and Light-Saturated Rate of Photosynthesis as a Function of Irradiance and Spectral Quality

Acclimation of the photosynthetic apparatus to changes in the light environment was studied in the unicellular red alga Porphyridium cruentum (American Type Culture Collection No. 50161). Absolute or relative amounts of four photosynthetic enzymes and electron carriers were measured, and the data were compared with earlier observations on light-harvesting components (F.X. Cunningham, Jr., R.J. Dennenberg, L. Mustárdy, P.A. Jursinic, E. Gantt [1989] Plant Physiol 91: 1179-1187; F.X. Cunningham, Jr., R.J. Dennenberg, P.A. Jursinic, E. Gantt [1990] Plant Physiol 93: 888-895) and with measurements of photosynthetic capacity. P_max, the light-saturated rate of photosynthesis on a chlorophyll (Chl) basis, increased more than 4-fold with increase in growth irradiance from 6 to 280 μeinsteins·m⁻²·s⁻¹. Amounts of ferredoxin-NADP⁺ reductase, ribulose-1,5-bisphosphate carboxylase, and cytochrome f increased in parallel with P_max, whereas numbers of the light-harvesting complexes (photosystem [PS] I, PSII, and phycobilisomes) changed little, and ATP synthase increased 7-fold relative to Chl. The calculated minimal turnover time for PSII under the highest irradiance, 5 ms, was thus about 4-fold faster than that calculated for cultures grown under the lowest irradiance (19 ms). A change in the spectral composition of the growth light (irradiance kept constant at 15 μeinsteins·m⁻²·s⁻¹) from green (absorbed predominantly by the phycobilisome antenna of PSII) to red (absorbed primarily by the Chl antenna of PSI) had little effect on the amounts of ribulose-1,5-bisphosphate carboxylase, ATP synthase, and phycobilisomes on a Chl, protein, or thylakoid area basis. However, the number of PSI centers declined by 40%, cytochrome f increased by 40%, and both PSII and ferredoxin-NADP⁺ reductase increased approximately 3-fold on a thylakoid area basis. The substantial increase in ferredoxin-NADP⁺ reductase under PSI light is inconsistent with a PSI-mediated reduction of NADP as the sole function of this enzyme. Our results demonstrate a high degree of plasticity in content and composition of thylakoid membranes of P. cruentum.     

Effective Absorption Cross-Sections in Porphyridium cruentum: Implications for Energy Transfer between Phycobilisomes and Photosystem II Reaction Centers

Effective absorption cross-sections for O₂ production by Porphyridium cruentum were measured at 546 and 596 nanometers. Although all photosystem II reaction centers are energetically coupled to phycobilisomes, any single phycobilisome acts as antenna for several photosystem II reaction centers. The cross-section measured in state I was 50% larger than that measured in state II.     

Noncovalent Intermolecular Forces in Phycobilisomes of Porphyridium cruentum

Using sensitized fluorescence as a measure of intactness of phycobilisomes isolated from Porphyridium cruentum, the effects of various environmental perturbations on phycobilisome integrity were investigated. The rate of phycobilisome dissociation in 0.75 ionic strength sodium salts proceeds in the order: SCN⁻ > NO₃⁻ > Cl⁻ > C₆H₅O₇³⁻ > SO₄²⁻ > PO₄³⁻, as predicted from the lyotropic series of anions and their effects on hydrophobic interactions in proteins. Similarly, increasing temperature (to 30 C) and pH values approaching the isoelectric points of the biliproteins stabilize phycobilisomes. Deuterium substitution at exchangeable sites on the phycobiliproteins decreases the rate of phycobilisome dissociation, while substitution at nonexchangeable sites increases rates of dissociation. It is concluded that hydrophobic intermolecular interactions are the most important forces in maintaining the phycobilisome structure. Dispersion forces also seem to contribute to phycobilisome stabilization. The adverse effects of electrostatic repulsion must not be ignored; however, it seems that the requirement of phycobilisomes of high salt concentrations is not simply countershielding of charges on the proteins.     

Carbonic Anhydrase of a Unicellular Red Alga Porphyridium cruentum R-l. I. Purification and Properties of the Enzyme

Cells of Porphyridium cruentum R-l, a unicellular red alga,grown under ordinary air (0.04% CO₂) showed much higher activityof carbonic anhydrase (CA) than those grown under CCvenrichedair (2% CO₂). CA activity was not detected in a suspension ofintact cells, and was detectable only after the cells had beenhomogenized, indicating that this enzyme was localized onlywithin the algal cells. After partial purification of Porphyridium CA, its mol wt wasestimated as 59 kDa by SDS-PAGE and 55 kDa by gelfiltration.This suggests that the native enzyme is a monomer. Its activitywas not affected by benzensulfonamides, potent inhibitors ofCAs isolated from Chlamydomonas and other organisms. Chloride(or bromide) ions was essential for CA activity. CA activitymarkedly decreased when the cell extract had been incubatedat pH lower than 7 before assay. Upon readjusting the pH ofthe preincubation medium to 9 or higher, the enzyme activitywas restored, indicating that the inactivation is reversible. (Received April 17, 1987; Accepted July 21, 1987)     

Carbonic Anhydrase of a Unicellular Red Alga Porphyridium cruentum R-l. II. Distribution and Role in Photosynthesis

Antibody was raised against Porphyridium carbonic anhydrase(CA) which was electrophoretically recovered from the gel afterSDS-polyacrylamide slab gel electrophoresis (SDS-PAGE) of thepartially purified enzyme. The antiserum reacted with CA ofPorphyridium, but not with that of Chlamydomonas reinhardtii.Even though the antiserum did not react with CA from P. cruentumR-l in Ouchterlony's double immunodiffusion, it blocked theenzyme activity in the presence of 1% Nonidet P-40 and 1% TritonX-100. After Western blotting and enzyme-linked immunostaining(ELIS), only one band which reacted with the antiserum was detectedin the extract of low-CO₂ cells (grown under ordinary air) ofP cruentum, while no significant band was detected in that ofhigh-CO₂ cells (grown under air enriched with 1–5% CO₂).Immunogold electron microscopy of low-CO₂ cells of P. cruentumR-l using this antibody revealed that most of the CA was localizedin the chloroplast, with some in the cytoplasm. No specificbinding of gold particles was observed in the high-CO₂ cells. ¹Present address: National Institute for Basic Biology, Myodaiji,Okazaki 444, Japan (Received May 18, 1987; Accepted September 7, 1987)     

An Evidence Indicating That a Weak Orange Light Absorbed by Phycobilisomes Causes Inactivation of PSII in Cells of the Red Alga Porphyridium cruentum Grown under a Weak Red Light Preferentially Exciting Chl a

Changes in the PSII fluorescence upon shift of light qualitywere studied with the red alga Porphyridium cruentum IAM R-1and supplementarily with P. cruentum ATCC 50161, the cyanophytesSynechocystis spp. PCC6714 and PCC6803 and Synechococcus sp.NIBB1071. When Porphyridium cruentum grown under a weak redlight (PSI light) preferentially absorbed by Chl a was illuminatedwith a weak orange light (PSII light) mainly absorbed by phycobilisomes(PBS), a change of PSII fluorescence at room temperature wasinduced. The ratio of Fvm (Fm— Fo) to Fm was reduced rapidlyaccompanying the increase in Fo (T^1/2 ca. 3 min). The effectsof DCMU and 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinoneindicated that the fluorescence change is induced when plastoquinonepool is highly reduced. The fluorescence change after a shortPSII light illumination was reversible; it rapidly recoveredin the dark (T ^1/2 ca. 3 min). The reversibility was graduallyreduced and disappeared after 40 h under PSII light accompanyingdecrease in PSII activity per PBS down to almost 50%. Sincethe pattern of the fluorescence change resembles that observablewhen PSII is photoinactivated, PSII light probably induces thephotoinactivation of PSII, possibly reversibly at first andirreversibly after prolonged illumination. Such a rapid fluorescencechange was insignificant in Synechocystis sp. either PCC6714or PCC6803. Only a slow and small decrease in Fvm/Fm level appearedafter prolonged PSII light illumination (the reduction of PSIIactivity per PBS was around 20%). In Porphyridium, shift fromPSII light to PSI light caused a rapid and chloramphenicol-sensitiveFvm/Fm elevation during the first 10 h while the increase inPSH activity per PBS was only 10% of that before the light shift.Then, a gradual elevation followed up to the level at the steadystate under PSI light. A similar rapid increase in Fvm/Fm wasobserved with Synechocystis PCC6714, in which the synthesisof PSII is not regulated, suggesting that a rapid increase inFvm/Fm does not reflect the acceleration of the synthesis ofPSII. Results were interpreted as that (1) PSII light causesphotoinactivation of PSII. Such a photoinactivation is markedin Prophyridium cells grown under PSI light. (2) In Porphyridium,changes in the abundance of PSII upon shift of light qualityare largely attributed to the photoinactivation of this type. (Received February 19, 1999; Accepted June 14, 1999)     

Characterization of a Purified Photosystem II-Phycobilisome Particle Preparation from Porphyridium cruentum

Detergent preparations isolated from thylakoids of the red alga Porphyridium cruentum, in a sucrose, phosphate, citrate, magnesium chloride medium consist of phycobilisomes and possess high rates of photosystem II activity. Characterization of these particles shows that the O₂-evolving activity is stable for several hours and the pH optimum is about 6.5 to 7.2. Response of the system to light, electron donors and acceptors, and inhibitors verify that the observed activity, measured both as O₂ evolution and 2,6-dichlorophenol-indophenol reduction, is due to photosystem II. Furthermore, photosystem II is functionally coupled to the phycobilisome in this preparation since green light, absorbed by phycobilisomes of P. cruentum, is effective in promoting both O₂ evolution and 2,6-dichlorophenol-indophenol reduction. Photosystem II activity declines when light with wavelengths shorter than 665 nm is removed. Both 3-(3,4-dichlorophenyl)-1,1-dimethylurea and atrazine inhibit photosystem II activity in this preparation, indicating that the herbicide binding site is a component of the photosystem II-phycobilisome particle.     

The Supramolecular Structure of Photosystem II — Phycobilisome-Complexes of Porphyridium cruentum

The structure and arrangement of phycobilisomes of the unicellular red alga Porphyridium cruentum is compared with the organization of the thylakoid freeze-fracture particles in order to determine the relationship between phycobilisomes and photosystem II. The hemi-ellipsoidal phycobilisomes, 20 nm thick, are predominantly organized into rows; their centre to centre periodicity is 30–40 nm, so that they are well separated by a gap of 10–20 nm. The phycobilisomes are cleaved by a central faint furrow, parallel to the long axis from top to base. The organization of the exoplasmic particles in rows is similar to the arrangement of the phycobilisomes so that a structural relationship between both systems, previously demonstrated in cyanobacteria, is evident. Within the rows, the 10 nm EF-particles are grouped in tetrameric complexes separated by distances similar to those observed for phycobilisomes. We propose that the tetrameric EF-particle complexes correspond to tetrameric photosystem II complexes which bind one hemi-ellipsoidal phycobilisome on the stroma exposed surface of the thylakoid. A hypothetical model of this photosystem II-phycobilisome complex is presented.     

Enhancement of Oxygen-Evolution in Photosystem II-Phycobilisome Particles from Porphyridium cruentum

Oxygen-evolving photosystem II-phycobilisome particles froma red alga were inhibited 50–80% by aging, dilution, lowpH and salt-washing. Bovine serum albumin, and dithiothreitolwere found to stimulate activity in all but salt-washed particles.CaCl₂ and MnCl₂ partially restored activity lost after agingor dilution. ¹Current address: Waksman Institute of Microbiology, RutgersUniversity, Piscataway, New Jersey 08854-0759, U.S.A. (Received October 5, 1985; Accepted March 31, 1986)     

Energy transfer from photosystem II to photosystem I in Porphyridium cruentum

Rates of photooxidation of P-700 by green (560 nm) or blue (438 nm) light were measured in whole cells of porphyridium cruentum which had been frozen to -196 degrees C under conditions in which the Photosystem II reaction centers were either all open (dark adapted cells) or all closed (preilluminated cells). The rate of photooxidation of P-700 at -196 degrees C by green actinic light was approx. 80% faster in the preilluminated cells than in the dark-adapted cells. With blue actinic light, the rates of P-700 photooxidation in the dark-adapted and preilluminated cells were not significantly different. These results are in excellent agreement with predictions based on our previous estimates of energy distribution in the photosynthetic apparatus of Porphyridium cruentum including the yield of energy transfer from Photosystem II to Photosystem I determined from low temperature fluorescence measurements.     

Isolation and Function of Allophycocyanin B of Porphyridium cruentum

Allophycocyanin B was purified to homogeneity from the eukaryotic red alga Porphyridium cruentum. This biliprotein is distinct from the allophycocyanin of P. cruentum with respect to subunit molecular weights, and spectroscopic and immunological properties. The purified allophycocyanin B has a long wavelength absorption maximum at 669 nm at room temperature and at 675 nm at −196 C while the fluorescence emission maximum is at 673 nm at room temperature and 679 nm at −196 C. The emission spectrum of allophycocyanin shifted only 1 nm, from 659 to 660 nm, on cooling to −196 C, and was the same with allophycocyanin crystals as it was with pure solutions of the pigment. Phycobilisomes from P. cruentum have a major fluorescence emission band at 680 nm at −196 C which emanates from the small amount of allophycocyanin B present in the phycobilisomes. Light energy absorbed by the bulk of the biliprotein pigments is transferred to allophycocyanin B with high efficiency.     

Thermal and pH Stability of the B-Phycoerythrin from the Red Algae Porphyridium cruentum

Phycoerythrin is the major light-harvesting pigment-protein of the red algae Porphyridium cruentum and is widely used as fluorescent probe and analytical reagent. Additionally this protein has a potential application as natural dye in food industry. Nevertheless the knowledge of the functional properties of this alga protein is limited, hindering its application as food additive. In this article we report a biophysical characterization of B-phycoerythrin from Porphyridium cruentum (B-PE) in order to study its stability and spectral properties in a broad range of pHs. This information can help in its potential application as colorant in the food industry. Spectroscopic data obtained in this work show that B-PE has a stronger functional stability in the pH range 4.0–10.0, and Size Exclusion Chromatography suggests that the protein maintains a (αβ)₆-γ oligomeric structure in that range of pHs. At pH 7.0, an apparent T _m value of 77.5?±?0.5 °C was calculated. At this pH, the protein is highly stable with a loss of only 20 % of its spectral properties (absorbance and fluorescence) after 25 days at room temperature. These results indicate that B-PE is more stable in a broad range of pHs than other phycoerythrin proteins, which would facilitate its use in the food industry.     

Effects of Growth Irradiance and Nitrogen Limitation on Photosynthetic Energy Conversion in Photosystem II

Photosynthetic energy conversion was investigated in five species of marine unicellular algae, (Dunaliella tertiolecta, Thalassiosira pseudonana, T. weisflogii, Skeletorema costatum, Isochrysis galbana) representing three phylogenetic classes, which were grown under steady state conditions with either light or inorganic nitrogen as a limiting factor. Using a pump and probe fluorescence technique we measured the maximum change in variable fluorescence yields, the flash intensity saturation curves for the change in fluorescence yields and the kinetics of the decay in fluorescence yields. Under all growth irradiance levels nutrient replete cells exhibited approximately the same changes in fluorescence yields and similar fluorescence decay kinetics. The apparent relative absorption cross-section of photosystem II, calculated from the slope of the flash intensity saturation curves, generally increased as cells shade adapted. The decay kinetics of the fluorescence yield following a saturating pump flash can be expressed as the sum of three exponential components, with half-times of 160 and 600 microseconds and 30 to 300 milliseconds. The relative contribution of each component did not change significantly with growth irradiance. As cells became more nitrogen limited, however, the maximum change in fluorescence yield decreased, and was accompanied by a decrease in the proportion of a 160 microsecond fluorescence decay component, which corresponds to the transfer of electrons from Q_a⁻ to Q_b. Changes in fluorescence yields were also accompanied by changes in the levels of D1, a protein which is integral in reaction center II, and CP47, a chlorophyll protein forming part of the core of photosystem II. These results are consistent with a loss of functional photosystem II reaction centers. Moreover, in spite of losses of total cellular chlorophyll, which invariably accompanied nitrogen limitation, the apparent absorption cross-sections of photosystem II increased. Our results suggest that nitrogen limitation leads to substantial decreases in photosynthetic energy conversion efficiency.     

Changes in Quantum Yield of Photosynthesis in the Red Alga Porphyridium cruentum Caused by Stepwise Reduction in the Intensity of Light Preferentially Absorbed by the Phycobilins

This paper describes the relation between the quantum yield of photosynthesis in the red alga Porphyridium cruentum, and the spectral composition of light, changed by filtering white light through aqueous phycobilin solutions of increasing optical density. At sufficiently high densities of the filter solution, no measurable photosynthesis can be observed, although chlorophyll a molecules are still being excited at a significant rate, as can be proved by calculations from spectral distribution curves, and is confirmed by the occurrence of a “second Emerson effect” upon addition of orange light. An interpretation of this result, based on other experiments, will be given in a subsequent paper. A modification of the opal glass technique for reducing the effect of scattering when measuring absorption, was developed in connection with this research, and also is described in the paper.     

Photosystem I-Mediated Regulation of Water Splitting in the Red Alga, Porphyra sanjuanensis

The marine red alga, Porphyra sanjuanensis is found mainly in the high intertidal zone and at low tide subject to frequent and extreme water stress, often accompanied by high temperatures and light intensities. Such exposures can lead to severe desiccation which is accompanied by the progressive loss of photosynthetic activity. Even following the loss of more than 90% of the thallus water content the alga recovers rapidly when returned to seawater. This stress-induced, reversible inactivation of photosynthesis is believed to be a protective adaptation which prevents photodamage to the exposed alga. Effects of light, inhibitors of water splitting, and electron donors to PSI on variable fluorescence and water splitting suggest that activity of the oxygen evolving complex is regulated by the PSI-driven reduction of a component of intersystem electron transport.