Soluble Chloroplast Enzyme Cleaves preLHCP Made in Escherichia coli to a Mature Form Lacking a Basic N-Terminal Domain

We have investigated the specificity of a chloroplast soluble processing enzyme that cleaves the precursor of the major light-harvesting chlorophyll a/b binding protein (LHCP). The precursor of LHCP (preLHCP) was synthesized in Escherichia coli and recovered from inclusion-like bodies. It was found to be a substrate for proteolytic cleavage by the soluble enzyme in an organelle-free reaction, yielding a 25 kilodalton peptide. This peptide co-migrated during sodium dodecyl sulfate-polyacrylamide gel electrophoresis with the smaller of the forms (25 and 26 kilodalton) produced when either the E. coli-synthesized precursor, or preLHCP made in a reticulocyte lysate, was imported into chloroplasts. N-Terminal sequence analysis of the E. coli-generated precursor showed that it lacked an N-terminal methionine. N-Terminal sequencing of the 25 kilodalton peptide produced in the organelle-free reaction indicated that processing occurred between residues 40 and 41, removing a basic domain (RKTAAK) thought to be at the N-terminus of all LHCP molecules of type I associated with photosystem II. To determine if the soluble enzyme involved also cleaves other precursor polypeptides, or is specific to preLHCP, it was partially purified, and the precursors for Rubisco small subunit, plastocyanin, Rubisco activase, heat shock protein 21, and acyl carrier protein were tested as substrates. All of these precursors were cleaved by the same chromatographic peak of activity that processes preLHCP in the organelle-free reaction.     

Processing of a wheat light-harvesting chlorophyll a/b protein precursor by a soluble enzyme from higher plant chloroplasts

A processing activity has been identified in higher plant chloroplasts that cleaves the precursor of the light-harvesting chlorophyll a/b- binding protein (LHCP). A wheat LHCP gene previously characterized (Lamppa, G.K., G. Morelli, and N.-H. Chua, 1985. Mol. Cell Biol. 5:1370- 1378) was used to synthesize RNA and subsequently the labeled precursor polypeptide in vitro. Incubation of the LHCP precursors with a soluble extract from lysed chloroplasts, after removal of the thylakoids and membrane vesicles, resulted in the release of a single 25-kD peptide. In contrast, when the LHCP precursors were used in an import reaction with intact pea or wheat chloroplasts, two forms (25 and 26 kD) of mature LHCP were found. The peptide released by the processing activity in the organelle-free assay comigrated with the lower molecular mass form of mature LHCP produced during import. Properties of the processing activity suggest that it is an endopeptidase. Chloroplasts from both pea and wheat, two divergent higher plants, contain the processing enzyme, suggesting its physiological importance in LHCP assembly into the thylakoids. We discuss the implications of LHCP precursor processing by a soluble enzyme that may be in the stromal compartment.     

Mutations at the transit peptide-mature protein junction separate two cleavage events during chloroplast import of the chlorophyll a/b-binding protein

We have shown previously that during in vitro import into chloroplasts, the precursor of the major light-harvesting chlorphyll a/b-binding protein (LHCP) generated from a wheat gene gives rise to two mature forms (25 and approximately 26 kDa) which are inserted into the thylakoids. However, during incubation of the LHCP precursor with a chloroplast-soluble extract in an organelle-free processing reaction, the NH2 terminus is cleaved, yielding only a 25-kDa peptide. In the present study, mutations at the transit peptide-mature protein junction were introduced in the LHCP precursor to investigate the relationship between the two peptides and the determinants of proteolytic processing. Mutant p delta 3 lacks 3 amino acids including Met34 at the primary cleavage site thought to give rise to the 26-kDa peptide. It is still processed during import and in the organelle-free reaction yielding in both assays only a 25-kDa peptide. Mutant p + 4 has 4 amino acids inserted immediately after Met34 and a proline that disrupts the alpha-helix predicted by the Garnier-Osguthorpe-Robson method (Garnier, J., Osguthorpe, D. J., and Robson, B. (1978) J. Mol. Biol. 120, 97-120) to extend through this region. Although p + 4 is imported, it is inefficiently processed; both a 25- and 26-kDa peptide are found, but at least 60% of the imported precursor remains uncleaved. Less than 5% is processed in the organelle-free assay. Replacement of the predicted alpha-helix in the mutant p + 4 alpha restores processing upon import into the chloroplast, but this mutant, which also has a 4-amino acid insert, yields only a 26-kDa peptide. p + 4 alpha is not processed in the organelle-free reaction. These results provide evidence that the two forms of LHCP obtained during import are the result of independent processing at two cleavage sites: the first site at Met34, and a second approximately 10 amino acids downstream within what has been designated the NH2 terminus of the mature protein. Whereas p delta 3 has the first site removed but retains a functional second site, in p + 4 alpha only the first site, or one very near it, is accessible to the processing enzyme during import. The conditions of the organelle-free reaction are specific for processing at only the secondary site. We discuss the implications of these findings in terms of the heterogeneity of LHCP in vivo.     

Loss of efficient import and thylakoid insertion due to N- and C-terminal deletions in the light-harvesting chlorophyll a/b binding protein.

C-terminally truncated precursors of wheat light-harvesting chlorophyll a/b binding protein (LHCP) were synthesized to investigate the origin of the two forms (about 25 kD and 26 kD) of the mature protein observed upon in vitro import into the chloroplast. Precursors p delta 13 and p delta 27, lacking 13 and 27 amino acids, respectively, were successfully imported, and both gave rise to two smaller forms proportional to the size of their deletions. These results demonstrate that there are two N-terminal sites that are cleaved during import of the LHCP precursor, undoubtedly contributing to the heterogeneity of LHCP found in vivo. Significantly, p delta 27 yielded only 50% of mature LHCP when compared with wild type. Although the products of p delta 27 import were localized to the thylakoids, in contrast to p delta 13 they were not correctly inserted into the membranes, indicating that residues essential for this step are missing. p delta 27 is distinguished from p delta 13 by lacking the carboxy end of a domain highly conserved between LHCP of photosystems II and I. Other specific precursor mutants with larger C-terminal deletions were not efficiently transported into the organelle in time course experiments, nor did they insert directly into the thylakoids using chloroplast lysates, in an assay independent of translocation across the envelope. In addition, the mutant p delta 18n, lacking the first 18 amino acids of mature LHCP, was only found bound to the chloroplast envelope. However, both p delta 18n and the mature protein, i.e., LHCP, synthesized in vitro without its 34-amino acid transit peptide inserted into the thylakoids in chloroplast lysates. The overall conformation of the mutant precursor polypeptides was probed using the chloroplast soluble processing enzyme in an organelle-free reaction optimized for the LHCP precursor and the more general protease trypsin. A tightly folded, protease-resistant conformation was not apparent to explain the loss of efficient import.     

Properties of a Chloroplast Enzyme that Cleaves the Chlorophyll a/b Binding Protein Precursor : Optimization of an Organelle-Free Reaction

The major light-harvesting chlorophyll a/b binding protein (LHCP) of higher plant chloroplasts is nuclear-encoded, synthesized as a precursor, and processed upon import. We have previously (GK Lamppa, M Abad [1987] J Cell Biol 105: 2641-2648) identified a soluble enzyme that cleaves the LHCP precursor (pLHCP). In this study, we describe the conditions for optimal recovery of the processing activity and provide evidence that the N terminus of pLHCP is indeed cleaved, removing the transit peptide. Two pLHCP deletions were made from a cloned pLHCP gene removing 13 and 21 amino acids, respectively, from the carboxy terminus of the protein. After organelle-free processing, the cleavage products showed a shift in mobility during SDS-PAGE proportional to the size of the precursor truncations, as predicted for N-terminal processing. Unexpectedly, a third truncated precursor lacking 91 residues of the C-terminus was not cleaved although the transit peptide domain was intact, suggesting that this deletion disrupted conformational features of the precursor necessary for processing. The pLHCP processing enzyme is inhibited by 2 millimolar EDTA and the metal chelator 1, 10 phenanthroline at 0.4 millimolar, while being inhibited by EGTA only at high concentrations and insensitive to iodoacetate. Optimal processing occurs at pH 8 to 9, and 26°C. Gel filtration chromatography shows that the pLHCP processing enzyme has an apparent molecular weight of about 240,000. The identical column fractions that process pLHCP also convert the precursor of the small subunit of ribulose-1,5-bisphosphate carboxylase to its mature form.     

The tomato Cab-4 and Cab-5 genes encode a second type of CAB polypeptides localized in Photosystem II

The photosynthetic apparatus of plant chloroplasts contains two photosystems, termed Photosystem I (PSI) and Photosystem II (PSII). Both PSI and PSII contain several types of chlorophyll a/b-binding (CAB) polypeptides, at least some of which are structurally related. It has been previously shown that multiple genes encoding one type of PSII CAB polypeptides exist in the genome of many higher plants. In tomato, there are at least eight such genes, distributed in three independent loci. Genes encoding a second type of CAB polypeptides have been isolated from several plant species, but the precise location of the gene products has not been determined. Here we show that tomato has two unlinked genes encoding this second type and that this type of CAB polypeptide is also localized in PSII.     

Photosystem electron-transport capacity and light-harvesting antenna size in maize chloroplasts

Spectrophotometric and kinetic measurements were applied to yield photosystem (PS) stoichiometries and the functional antenna size of PSI, PSII_α, and PSII_β in Zea mays chloroplasts in situ. Concentrations of PSII and PSI reaction centers were determined from the amplitude of the light-induced absorbance change at 320 and 700 nm, which reflect the photoreduction of the primary electron acceptor Q of PSII and the photooxidation of the reaction center P700 of PSI, respectively. Determination of the functional chlorophyll antenna size (N) for each photosystem was obtained from the measurement of the rate of light absorption by the respective reaction center. Under the experimental conditions employed, the rate of light absorption by each reaction center was directly proportional to the number of light-harvesting chlorophyll molecules associated with the respective photosystem. We determined N_P700 = 195, N_α = 230, N_β = 50 for the number of chlorophyll molecules in the light-harvesting antenna of PSI, PSII_α, and PSII_β, respectively. The above values were used to estimate the PSII/PSI electron-transport capacity ratio (C) in maize chloroplasts. In mesophyll chloroplasts C > 1.4, indicating that, under green actinic excitation when Chl a and Chl b molecules absorb nearly equal amounts of excitation, PSII has a capacity to turn over electrons faster than PSI. In bundle sheath chloroplasts C < 1, suggesting that such chloroplasts are not optimally poised for linear electron transport and reductant generation.     

The chlorophyll a/b-binding protein inserts into the thylakoids independent of its cognate transit peptide

In order to determine if the cognate transit peptide of the light-harvesting chlorophyll a/b-binding protein (LHCP) is essential for LHCP import into the chloroplast and proper localization to the thylakoids, it was replaced with the transit peptide of the small subunit (S) of ribulose-1,5-bisphosphate carboxylase/oxygenase, a stromal protein. Wheat LHCP and S genes were fused to make a chimeric gene coding for the hybrid precursor, which was synthesized in vitro and incubated with purified pea chloroplasts. My results show that LHCP is translocated into chloroplasts by the S transit peptide. The hybrid precursor was processed; and most importantly, mature LHCP did not remain in the stroma, but was inserted into thylakoid membranes, where it normally functions. Density gradient centrifugation showed no LHCP in the envelope fraction. Hence, the transit peptide of LHCP is not required for intraorganellar routing, and LHCP itself contains an internal signal for localization to the correct membrane compartment.     

Probing Photosynthesis on a Picosecond Time Scale: Evidence for Photosystem I and Photosystem II Fluorescence in Chloroplasts

Fluorescent emission kinetics of isolated spinach chloroplasts have been observed at room temperature with an instrument resolution time of 10 ps using a frequency doubled, mode-locked Nd:glass laser and an optical Kerr gate. At 685 nm two maxima are apparent in the time dependency of the fluorescence; the first occurs at 15 ps and the second at 90 ps after the flash. The intervening minimum occurs at about 50 ps. On the basis of theoretical models, lifetimes of the components associated with the two peaks and spectra (in escarole chloroplasts), the fluorescence associated with the first peak is interpreted as originating from Photosystem I (PSI) (risetime ≤10 ps, lifetime ≤10 ps) and the second peak from Photosystem II (PSII) (lifetime, 210 ps in spinach chloroplasts and 320 ps in escarole chloroplasts). The fact that there are two fluorescing components with a quantum yield ratio ≤0.048 explains the previous discrepancy between the quantum yield of fluorescence measured in chloroplasts directly and that calculated from the lifetime of PSII. The 90 ps delay in the peak of PSII fluorescence is probably explained by energy transfer between accessory pigments such as carotenoids and Chl a. Energy spillover between PSI and PSII is not apparent during the time of observation. The results of this work support the view that the transfer of excitation energy to the trap complex in both photosystems occurs by means of a molecular excitation mechanism of intermediate coupling strength. Although triplet states are not of major importance in energy transfer to PSII traps, the possibility that they are involved in PSI photochemistry has not been eliminated.     

Insensitivity of Water-Oxidation and Photosystem II Activity in Tomato to Chilling Temperatures

Chilling tomato plants (Lycopersicon esculentum Mill. cv. Rutgers and cv. Floramerica) in the dark resulted in a sizable inhibition in the rate of light- and CO₂-saturated photosynthesis. However, at low light intensity, the inhibition disappeared and the absolute quantum yield of CO₂ reduction was diminished only slightly. The quantum yield of photosystem II (PSII) electron flow was 18% lower when measured in chloroplasts isolated from chilled leaves than in chloroplasts isolated from unchilled leaves. Even though the maximum rate of PSII turnover in these chloroplasts was 12% lower subsequent to chilling, it was in all cases two or more times that required to support the light- and CO₂-saturated rate of photosynthesis measured in the attached leaf. The concentration of active PSII centers in chloroplasts isolated from leaves either before or after chilling was determined by measurement of the products of water oxidation from a series of saturating flashes short enough to turnover the electron transport carriers only a single time. There was no significant change in the concentration of active PSII centers due to dark chilling.

It was concluded that PSII activity and water oxidation capacity are not significantly impaired in tomato by chilling in the dark and therefore are not primary aspects of the inhibition of CO₂ reduction observed in attached leaves.

     

Cyanobacterial Acclimation to Photosystem I or Photosystem II Light

The organization and function of the photochemical apparatus of Synechococcus 6301 was investigated in cells grown under yellow and red light regimes. Broadband yellow illumination is absorbed preferentially by the phycobilisome (PBS) whereas red light is absorbed primarily by the chlorophyll (Chl) pigment beds. Since PBSs are associated exclusively with photosystem II (PSII) and most of the Chl with photosystem I (PSI), it follows that yellow and red light regimes will create an imbalance of light absorption by the two photosystems. The cause and effect relationship between light quality and photosystem stoichiometry in Synechococcus was investigated. Cells grown under red light compensated for the excitation imbalance by synthesis/assembly of more PBS-PSII complexes resulting in high PSII/PSI = 0.71 and high bilin/Chl = 1.30. The adjustment of the photosystem stoichiometry in red light-grown cells was necessary and sufficient to establish an overall balanced absorption of red light by PSII and PSI. Cells grown under yellow light compensated for this excitation imbalance by assembly of more PSI complexes, resulting in low PSII/PSI = 0.27 and low bilin/Chl = 0.42. This adjustment of the photosystem stoichiometry in yellow light-grown cells was necessary but not quite sufficient to balance the absorption of yellow light by the PBS and the Chl pigment beds. A novel excitation quenching process was identified in yellow light-grown cells which dissipated approximately 40% of the PBS excitation, thus preventing over-excitation of PSII under yellow light conditions. It is hypothesized that State transitions in O₂ evolving photosynthetic organisms may serve as the signal for change in the stoichiometry of photochemical complexes in response to light quality conditions.     

Current views on chloroplast protein import and hypotheses on the origin of the transport mechanism

Most chloroplastic proteins are synthesized as precursors in the cytosol prior to their transport into chloroplasts. These precursors are generally synthesized in a form that is larger than the mature form found inside chloroplasts. The extra amino acids, called transit peptides, are present at the amino terminus. The transit peptide is necessary and sufficient to recognize the chloroplast and induce movement of the attached protein across the envelope membranes. In this review, we discuss the primary and secondary structure of transit peptides, describe what is known about the import process, and present some hypotheses on the evolutionary origin of the import mechanism.Abbreviations DHFR dihydrofolate reductase - EPSP synthase 5-enolpyrovylshikimate-3-phosphate synthase; hsp heat-shock protein - LHCP II light-harvesting chlorophylla/b binding protein - OEE 16, 23, and 33 the 16-, 23-, and 33-kDa proteins of the oxygen-evolving complex - pr precursor - rubisco ribulose-1,5-bisphosphate carboxylase/oxygenase - SS rubisco small subunit     

Photosystem Stoichiometry and Excitation Distribution in Chloroplasts from Surface and Minus 20 Meter Blades of Macrocystis pyrifera, the Giant Kelp

The photochemical apparatus organization in the thylakoid membrane of Macrocystis pyrifera, the giant kelp, was investigated. Chloroplasts were isolated from surface and minus 20 meter blades. Photosynthetic electron-transport complex quantitation revealed ratios of photosystem (PS) II/cytochrome b₆-f/PSI = 1.8:3.3:1.0 in surface and 2.2:2.3:1.0 in minus 20 meter blades. The apparent photosynthetic unit size of chloroplasts from minus 20 meter blades (chlorophyll/P700 = 1485:1) was about 45% larger than that of surface blades (chlorophyll/P700 = 1025:1). The larger photosynthetic unit size of minus 20 meter blades is attributed to the substantially lower intensity of sunlight reaching the minus 20 meter habitat. In different chloroplast preparations, the effective absorption cross section of PSI and PSII to 670 nanometer light (chlorophyll a) and 481 nanometer light (chlorophyll c and fucoxanthin) was investigated. The results showed larger functional antenna size for PSII (about 90%) and for PSI (about 50%) in minus 20 meter than in surface blades. Moreover, the efficiency of utilization of 481 nanometer light by Macrocystis chloroplasts was equal to that of 670 nanometer light. It is concluded that the chlorophyll c-fucoxanthin complex in brown algae enables the highly efficient utilization of blue-green wavelengths of the nearshore marine environment and contributes to the dominance of M. pyrifera in this habitat.     

Stoichiometries of Photosystem I and Photosystem II in Rice Mutants Differently Deficient in Chlorophyll b

Stoichiometries of photosystem I (PSI) and photosystem II (PSII)reaction centers in a cultivar of rice, Norin No. 8, and threechlorophyll b-deficient mutants derived from the cultivar wereinvestigated. Quantitation of PSI by photooxidation of P-700and chromatographic assay of vitamin K₁ showed that, on thebasis of chlorophyll, the mutants have higher concentrationsof PSI than the wildtype rice. Greater increases were observedin the PSII contents measured by photoreduction of Q_A, bindingof a radioactive herbicide and atomic absorption spectroscopyof Mn. Consequently, the PSII to PSI ratio increased from 1.1–1.3in the wild-type rice to 1.8 in chlorina 2, which contains noChl b, and to 2.0–3.3 in chlorina 11 and chlorina 14,which have chlorophyll a/b ratios of 9 and 13, respectively.Measurement of oxygen evolution with saturating single-turnoverflashes revealed that, whereas at most 20% of PSII centers areinactive in oxygen evolution in the wildtype rice, the non-functionalPSII centers amount to about 50% in the three mutant strains.The fluorescence induction kinetics was also analyzed to estimateproportions of the inactive PSII in the mutants. The data obtainedsuggest that plants have an ability to adjust the stoichiometryof the two photosystems and the functional organization of PSIIin response to the genetically induced deficiency of chlorophyllb. (Received July 29, 1994; Accepted February 7, 1996)     

Preparation of chlamydomonas chloroplasts for the in vitro import of polypeptide precursors

To study the import of polypeptide precursors we have adapted and compared two procedures for the isolation of competent chloroplasts from the green unicellular alga, Chlamydomonas reinhardtii: silicasol gradient centrifugation and elutriation. The chloroplasts actively import the precursor of the small subunit of ribulose bisphosphate carboxylase-oxygenase in vitro.     

Connectivity between electron transport complexes and modulation of photosystem II activity in chloroplasts

In chloroplasts, photosynthetic electron transport complexes interact with each other via the mobile electron carriers (plastoquinone and plastocyanin) which are in surplus amounts with respect to photosystem I and photosystem II (PSI and PSII), and the cytochrome b ₆ f complex. In this work, we analyze experimental data on the light-induced redox transients of photoreaction center P₇₀₀ in chloroplasts within the framework of our mathematical model. This analysis suggests that during the action of a strong actinic light, even significant attenuation of PSII [for instance, in the result of inhibition of a part of PSII complexes by DCMU or due to non-photochemical quenching (NPQ)] will not cause drastic shortage of electron flow through PSI. This can be explained by “electronic” and/or “excitonic” connectivity between different PSII units. At strong AL, the overall flux of electrons between PSII and PSI will maintain at a high level even with the attenuation of PSII activity, provided the rate-limiting step of electron transfer is beyond the stage of PQH₂ formation. Results of our study are briefly discussed in the context of NPQ-dependent mechanism of chloroplast protection against light stress.     

Effect of the anthocyanic epidermal layer on Photosystem II and I energy dissipation processes in Tradescantia pallida (Rose) Hunt

The effect of anthocyanic cells of the epidermal layer was investigated on photosynthetic activity of the higher plant Tradescantia pallida. To determine the possible indirect role of anthocyanin in photosynthesis, analysis was done on intact leaves and leaves where anthocyanic epidermal layer was removed. Energy dissipation processes related to Photosystem II (PSII) and Photosystem I (PSI) activity was done using simultaneously Chlorophyll a (Chl a) fluorescence and P700 transmittance signals change. In anthocyanic epidermal-less leaves, PSII photochemical activity was more decreased in dependence to increasing light irradiance exposure. We found that photoinhibition of PSII decreased PSI activity by reducing the electron flow toward PSI, especially under high light intensities. Under those conditions, it resulted in the accumulation of oxidized PSI reaction centers, which was stronger in leaves where the anthocyanic epidermal layer was removed. In conclusion, our results showed that the anthocyanic epidermal layer had a photoprotective effect only on the PSII and not on the PSI of T. pallida leaves, supporting the role of anthocyanin pigments in the regulation of photosynthesis for excess absorbed light irradiance.     

Effect of light quality on chloroplast-membrane organization and function in pea

The effect of light quality during plant growth of chloroplast membrane organization and function in peas (Pisum sativum L. cv. Alaska) was investigated. In plants grown under photosystem (PS) I-enriched (far-red enriched) illumination both the PSII/PSI stoichiometry and the electrontransport capacity ratios were high, about 1.9. In plants grown under PSII-enriched (far-red depleted) illumination both the PSII/PSI stoichiometry and the electron-transport capacity ratios were significantly lower, about 1.3. In agreement, steady-state electron-transport measurements under synchronous illumination of PSII and PSI demonstrated an excess of PSII in plants grown under far-red-enriched light. Sodium dodecylsulfate polyacrylamide gel electrophoretic analysis of chlorophyll-containing complexes showed greater relative amounts of the PSII reaction center chlorophyll-protein complex in plants grown under farred-enriched light. Additional changes were observed in the ratio of light-harvesting chlorophyll a/b protein to PSII reaction center chlorophyll-protein under the two different light-quality regimes. The results demonstrate the dynamic nature of chloroplast structure and support the notion that light quality is an important factor in the regulation of chloroplast membrane organization and-function.Abbreviations and symbols Chl chlorophyll - CPa PSII reaction center chlorophyll protein complex - CPI PSI chlorophyll protein complex - FR-D light depleted in far-red sensitizing primarily PSII - FR-E light enriched in far-red sensitizing primarily PSI - LHCP PSII light-harvesting chlorophyll a/b protein complex - P ₇₀₀ primary electron donor of PSI - PSI, PSII photosystems I and II, respectively - Q primary electron acceptor of PSII     

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.