The Involvement of the Complexes of Photosystems in the Organization of Chloroplast Ultrastructure in Pea Mutants

We studied the involvement of pigment-protein complexes of photosystems (PS) in the development and spatial arrangement of thylakoids in chloroplasts of pea (Pisum sativum L.) leaves. The initial line (cv. Torsdag) and its mutants, chlorotica 2004 displaying primary disturbances in the PSI reaction centers and chlorotica 2014 containing only 50% of chlorophyll and, as a sequence, the reduced amount of all pigment-protein complexes. A proportional decrease in the content of PSI and PSII complexes in the chlorotica 2014 mutant resulted in a partial reduction of the whole chloroplast membrane system, whereas grana and stroma thylakoid regions were well developed. In contrast, a loss of only 20% of chlorophyll and destruction of PSI complexes in the chlorotica 2004 mutant by 50% resulted in the destruction of stroma thylakoid regions and disturbed longitudinal thylakoid and grana orientation. It was concluded that protein-protein interactions in pigment-protein complexes played a key role in the structure of thylakoid membranes and their longitudinal orientation.     

A diatom light-harvesting pigment-protein complex : purification and characterization

A light-harvesting pigment-protein complex was isolated from the diatom Phaeodactylum tricornutum using the zwitterionic detergent CHAPS (3-[3-cholamidopropyl)dimethylammonio]-1-propanesulfonate). Detergent-solubilized membranes were fractionated by sucrose density gradient centrifugation into three components. The medium density fraction contained chlorophyll a, chlorophyll c, and fucoxanthin. This fraction was purified by DEAE-ion exchange chromatography, and contained chlorophyll a, chlorophyll c, and fucoxanthin in a molar ratio of 2.4:1.0:4.8. Fluorescence emission and excitation spectra of the isolated complex demonstrated that light energy absorbed by chlorophyll c and fucoxanthin was coupled to chlorophyll a fluorescence. Upon denaturation, the apoprotein yielded a polypeptide doublet at 17.5 to 18.0 kilodaltons which accounted for 30 to 40% of the toal membrane protein. These findings indicate that this pigment-protein complex is a major component of the diatom photosynthetic lammellae. The quantitative amino acid composition of the apoprotein was very similar to those reported for other membrane-bound pigment-protein complexes. Based on the protein to chlorophyll a ratio of 7700 grams protein per mole chlorophyll a for the complex, each apoprotein molecule contains, to the nearest integer, two chlorophyll a, one chlorophyll c, and five fucoxanthin molecules. Polyclonal antibodies raised against the 17.5 to 18.0 kilodaltons apoprotein showed a monospecific reaction with only the 17.5 to 18.0 protein zone from denatured P. tricornutum membranes as well as to the nondenatured pigment-protein complex. It appears that this complex is common to other diatom species.     

Light-Harvesting Function in the Diatom Phaeodactylum tricornutum: I. Isolation and Characterization of Pigment-Protein Complexes

Three pigment-protein complexes were isolated from the marine diatom Phaeodactylum tricornutum (Bohlin) by treatment of thylakoid membrane fragments with 1% Triton X-100 at 4°C followed by centrifugation on sucrose density gradients. The major complex contains chlorophyll a, c₁, c₂, and the carotenoid fucoxanthin (chlorophyll a: c₁: c₂: fucoxanthin = 1.0: 0.09: 0.28: 2.22) bound to an apoprotein doublet of 16.4 and 16.9 kilodaltons. This complex accounts for >70% of the total pigment and 20 to 40% of the protein in the thylakoid membranes. Efficient coupling of chlorophyll c and fucoxanthin absorption to chlorophyll a fluorescence supports a light-harvesting function for the complex. A minor light-harvesting complex containing chlorophyll a, c₁, and c₂ but no fucoxanthin (chlorophyll a: c₁: c₂ = 1.0: 0.23: 0.26) was also isolated at Triton: chlorophyll a ratios between 20 and 40. These pigments are bound to a similar molecular weight apoprotein doublet. The third complex isolated was the P700-chlorophyll a protein, the reaction center of photosystem I, which showed characteristics similar to those isolated from other plant sources. The yield of the chlorophyll a/c-fucoxanthin complex was shown to respond strongly to changes in light intensity during growth, accounting for most of the changes in cellular pigmentation.     

Isolation and characterization of pigment-protein particles from the light-harvesting complex of Phaeodactylum tricornutum

The light-harvesting complex of the marine diatom Phaeodactylum tricornutum was fractionated into two large pigment-protein particles. One pigment-protein particle, which was contained in a yellow fraction, has a molecular weight, determined by gel filtration, of approx. 230 000 and can be dissociated in sodium dodecyl sulfate/mercaptoethanol solution to apopolypeptides of approx. 15 000. Characterization of particles with regard to molecular weights, subunits, protein and pigments suggests approx. 12 subunits per particle. The other pigment-protein particle, which was found in a green fraction, of approx. 95 000 molecular weight also reduces to apopolypeptide subunits of approx. 15 kDa. The relative molar proportions of chlorophyll a, chlorophyll c, fucoxanthin and total other accessory pigments in the former fraction are 3:1.3:6:2, whereas the proportions in the latter fraction are 5:1:3:1.     

Orientation of photosystem-I pigments. Investigation by low-temperature linear dichroism and polarized fluorescence emission

Using absorption and fluorescence experiments at low temperature with polarized light on oriented samples, the orientation of PS-I-related pigments, both in green plants and in Chlamydomonas reinhardtii, has been investigated on isolated pigment-protein complexes and intact thylakoids. The following observations have been made. (i) The isolation procedure of PS I₁₁₀, PS I₆₅, LHC I and CP0) particles from pea and C. reinhardtii do not alter significantly the intrinsic orientation of the pigments inside the complexes; (ii) Chl b is a structural component of PS I, linked to the peripheral antenna, with an orientation with respect to the thylakoid plane different from that observed in the main light-harvesting complex (iii) PS I₆₅ (i.e., ‘core’ PS I) of pea and C. reinhardtii contains identical chromophores having the same orientation with respect to the geometrical longest axis (axes) of the complexes. (iv) LHC I and CP0 (i.e., PS I ‘peripheral antenna’) of pea and C. reinhardtii have identical oriented chromophores, except that a long-wavelength component with a high anisotropy is only present in green plants. This set of pigments, which absorbs at 705–725 nm, has the same orientation as the dipoles emitting F₇₃₅ and also as the Q_Y transition of P-700. (v) All the long-wavelength fluorescence properties of the various studied membranes are explained by these data on isolated PS I complexes: wild-type C. reinhardtii and Chl-b-less barely fluoresce from the core pigments, while a CP1 deficient mutant of C. reinhardtii and wild-type barley fluoresce from the antenna pigments.     

Thylakoid Organization in the Chromophyte Alga Ochromonas danica: Isolation and Characterization of a New Pigment-Protein Complex

This report describes the isolation and preliminary characterization of a new pigment-protein complex from the chromophyte alga, Ochromonas danica. The pigment-protein complex was obtained by extracting a thylakoid membrane preparation with the zwitterionic detergent lauryldimethylamine oxide followed by ultracentrifugation on sucrose gradients. The pigment-protein complex has been characterized by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, absorption spectroscopy, and low temperature (77 Kelvin) chlorophyll fluorescence spectroscopy. A polypeptide with a monomeric molecular weight of 31,000 as determined by denaturing sodium dodecyl sulfate-polyacrylamide gel electrophoresis was the major constituent of this pigment-protein complex. The major pigment in this complex was chlorophyll a, although an as yet unidentified carotenoid was also present. There was no evidence for the presence of chlorophyll c.     

Light-harvesting systems of brown algae and diatoms. Isolation and characterization of chlorophyll ac and chlorophyll afucoxanthin pigment-protein complexes

The present study examined the protein associations and energy transfer characteristics of chlorophyll c and fucoxanthin which are the major light-harvesting pigments in the brown and diatomaceous algae. It was demonstrated that sodium dodecyl sulfate (SDS)-solubilized photosynthetic membranes of these species when subjected to SDS polyacrylamide gel electrophoresis yielded three spectrally distinct pigment-protein complexes. The slowest migrating zone was identical to complex I, the SDS-altered form of the P-700 chlorophyll a-protein. The zone of intermediate mobility contained chlorophyll c and chlorophyll a in a molar ratio of 2 : 1, possessed no fucoxanthin, and showed efficient energy transfer from chlorophyll c to chlorophyll a. The fastest migrating pigment-protein zone contained fucoxanthin and chlorophyll a, possessed no chlorophyll c, and showed efficient energy transfer from fucoxanthin to chlorophyll a. It is demonstrated that the chlorophyll $\text{a}\text{c-}\text{protein}$ and the chlorophyll $\text{a}\text{fucoxanthin-protein}$ complexes are common to the brown algae and diatoms examined, and likely share similar roles in the photosynthetic units of these species.     

Pigment ligation to proteins of the photosynthetic apparatus in higher plants

Ligation of pigments to proteins of the thylakoid membrane is a central step in the assembly of the photosynthetic apparatus in higher plants. Because of the potentially damaging photooxidative activity of chlorophylls, it is likely that between their biosynthesis and final assembly, chlorophylls will always be bound to protein complexes in which photooxidation is prevented by quenchers such as carotenoids. Such complexes may include chlorophyll carriers and/or membrane receptors involved in protein insertion into the membrane. Many if not all pigment-protein complexes of the thylakoid are stabilised towards protease attack by bound pigments. The major light-harvesting chlorophyll a/b protein (Lhebl,2) folds into its native structure in vitro only when it binds pigments. Pigment-induced folding may also be a general feature of chlorophyll-carotenoid proteins of the photosynthetic apparatus.     

Mutants of Sweetclover (Melilotus alba) Lacking Chlorophyll b: Studies on Pigment-Protein Complexes and Thylakoid Protein Phosphorylation

Mutants of sweetclover (Melilotus alba) with defects in the nuclear ch5 locus were examined. Using thin-layer chromatography and absorption spectroscopy, three of these mutants were found to lack chlorophyll (Chl) b. One of these three mutants, U374, possessed thylakoid membranes lacking the three Chl b-containing pigment-protein complexes (AB-1, AB-2, and AB-3) while still containing A-1 and A-2, Chl a complexes derived from photosystems I and II, respectively. Complete solubilization and denaturation of the thylakoid proteins from this mutant revealed very little apoprotein from the Chl b-containing light-harvesting complexes, the major thylakoid proteins in normal plants. The normal and mutant sweetclover plants had active thylakoid protein kinase activities and numerous polypeptides were labeled following incubation with [γ-³²P]ATP. With the U374 mutant, however, there was very little detectable label co-migrating with the light-harvesting complex apoproteins on polyacrylamide gels. The Chl b-deficient chlorina-f2 mutant of barley (Hordeum vulgare) also had an active protein kinase activity capable of phosphorylating numerous polypeptides, including ones migrating with the same mobility as the light-harvesting complex apoproteins. These results indicate that the sweetclover mutants may be useful systems for studies on the function and organization of Chl b in thylakoid membranes of higher plants.     

Effect of DNAase on fluorescent properties of pigment-protein complexes, contained in photosystem II

It was found that chlorophyll fluorescence spectra and spectra of fluorescence excitation of pigment-protein complexes of photosystem II are affected by treatment with DNase. Pigment-protein complexes were isolated from pea thylakoid membranes. Spectra were measured at room temperature. It was shown that the treatment with DNase leads to a 30% increase in fluorescence yield at excitation in chlorophyll absorption bands in the fraction containing CP47, CP43, and CP29, and also in the fraction containing reaction center complexes with minor contaminations of light-harvesting complexes. Upon excitation at 260-300 nm and in the region of 500 nm, a diminishing of fluorescence yield takes place. These results suggest that pigments and/or pigment-protein complexes are bound to nucleic acids. This association, by influencing the pigment properties, can participate in the photoregulation of biochemical reactions through changes in the thermal dissipation of excited chlorophyll molecules.     

Inhibition of degreening in the peel of bananas ripened at tropical temperatures.

Changes in the plastid ultrastructure as revealed by thin-section electron-microscopy, chlorophyll a/b ratio, and the polypeptides of the thylakoid chlorophyll-protein complexes have been examined during the degreening of bananas (Musa AAA Group, Cavendish Subgroup) and plantains (Musa AAB Group, Plantain Subgroup) ripened at 20°C and 35°C. In bananas, where degreening is inhibited at temperatures above 24°C, ripening at the higher temperature results in a retention of thylakoid membranes, a relatively delayed breakdown in chlorophyll b, and a reduced dismantling of pigment-protein complexes. By contrast, in plantains, where degreening is complete within 4 days at both 20°C and 35°C, thylakoid membranes and their associated pigment-protein complexes are lost, and there is a rapid increase in chlorophyll a/b ratios at both ripening temperatures. It is suggested that the retention of thylakoid membranes is an important factor in the failure of Cavendish bananas to degreen when ripened at tropical temperatures, and that the degreening problem may be related to the comparatively high chlorophyll b content of the preclimacteric fruit.     

Xanthophyll Cycle Pigment Localization and Dynamics during Exposure to Low Temperatures and Light Stress in Vinca major

The distribution of xanthophyll cycle pigments (violaxanthin plus antheraxanthin plus zeaxanthin [VAZ]) among photosynthetic pigment-protein complexes was examined in Vinca major before, during, and subsequent to a photoinhibitory treatment at low temperature. Four pigment-protein complexes were isolated: the core of photosystem (PS) II, the major light-harvesting complex (LHC) protein of PSII (LHCII), the minor light-harvesting proteins (CPs) of PSII (CP29, CP26, and CP24), and PSI with its LHC proteins (PSI-LHCI). In isolated thylakoids 80% of VAZ was bound to protein independently of the de-epoxidation state and was found in all complexes. Plants grown outside in natural sunlight had higher levels of VAZ (expressed per chlorophyll), compared with plants grown in low light in the laboratory, and the additional VAZ was mainly bound to the major LHCII complex, apparently in an acid-labile site. The extent of de-epoxidation of VAZ in high light and the rate of reconversion of Z plus A to V following 2.5 h of recovery were greatest in the free-pigment fraction and varied among the pigment-protein complexes. Photoinhibition caused increases in VAZ, particularly in low-light-acclimated leaves. The data suggest that the photoinhibitory treatment caused an enrichment in VAZ bound to the minor CPs caused by de novo synthesis of the pigments and/or a redistribution of VAZ from the major LHCII complex.     

Orientation of pigments and pigment-protein complexes in the green photosynthetic bacterium Prosthecochloris aestuarii

The orientation of pigments and pigment-protein complexes of the green photosynthetic bacterium Prosthecochloris aestuarii was studied by measurement of linear dichroism spectra at 295 and 100 K. Orientation of intact cells and membrane vesicles (Complex I) was obtained by drying on a glass plate. The photochemically active pigment-protein complexes (photosystem-protein complex and reaction center pigment-protein complex) and the antenna bacteriochlorophyll a protein were oriented by pressing a polyacrylamide gel. The data indicate that the near-infrared transitions (Q_y) of bacteriochlorophyll c and most bacteriochlorophyll a molecules have a relatively parallel orientation to the membrane, whereas the Q_y transitions of the bacteriochlorophyll a in the antenna protein are oriented predominantly perpendicularly to the membrane. Carotenoids and the Q_x transitions (590–620 nm) of bacteriochlorophyll a, not belonging to the bacteriochlorophyll a protein, have a relatively perpendicular orientation to the membrane. The absorption and linear dichroism spectra indicate the existence of different pools of bacteriochlorophyll c in the chlorosomes and of carotenoid and bacteriopheophytin c in the cell membrane. The results suggest that the photosystem-protein and reaction center pigment-protein complexes are oriented with their short axes approximately perpendicular to the plane of the membrane. The symmetry axis of the bacteriochlorophyll a protein has an approximately perpendicular orientation.     

High light-induced changes in thylakoid supercomplexes organization from cyclic electron transport mutants of Chlamydomonas reinhardtii

The localization of carotenoids and macromolecular organization of thylakoid supercomplexes have not been reported yet in Chlamydomonas reinhardtii WT and cyclic electron transport mutants (pgrl1 and pgr5) under high light. Here, the various pigments, protein composition, and pigment-protein interactions were analyzed from the cells, thylakoids, and sucrose density gradient (SDG) fractions. Also, the supercomplexes of thylakoids were separated from BN-PAGE and SDG. The abundance of light-harvesting complex (LHC) II trimer complexes and pigment-pigment interaction were changed slightly under high light, shown by circular dichroism. However, a drastic change was seen in photosystem (PS)I-LHCI complexes than PSII complexes, especially in pgrl1 and pgr5. The lutein and β-carotene increased under high light in LHCII trimers compared to other supercomplexes, indicating that these pigments protected the LHCII trimers against high light. However, the presence of xanthophylls, lutein, and β-carotene was less in PSI-LHCI, indicating that pigment-protein complexes altered in high light. Even the real-time PCR data shows that the pgr5 mutant does not accumulate zeaxanthin dependent genes under high light, which shows that violaxanthin is not converting into zeaxanthin under high light. Also, the protein data confirms that the LHCSR3 expression is absent in pgr5, however it is presented in LHCII trimer in WT and pgrl1. Interestingly, some of the core proteins were aggregated in pgr5, which led to change in photosynthesis efficiency in high light.     

Pigment and protein composition of reconstituted light-harvesting complexes and effects of some protein modifications

The structure and heterogeneity of LHC II were studied by in vitro reconstitution of apoproteins with pigments (Plumley and Schmidt 1987, Proc Natl Acad Sci 84: 146–150). Reconstituted CP 2 complexes purified by LDS-PAGE were subsequently characterized and shown to have spectroscopic properties and pigment-protein compositions and stoichiometries similar to those of authentic complexes. Heterologous reconstitutions utilizing pigments and light-harvesting proteins from spinach, pea and Chlamydomonas reinhardtii reveal no evidence of specialized binding sites for the unique C. reinhardtii xanthophyll loroxanthin: lutein and loroxanthin are interchangeable for in vitro reconstitution. Proteins modified by the presence of a transit peptide, phosphorylation, or proteolytic removal of the NH₂-terminus could be reconstituted. Evidence suggests that post-translational modification are not responsible for the presence of six electrophoretic variants of C. reinhardtii CP 2. Reconstitution is blocked by iodoacetamide pre-treatment of the apoproteins suggesting a role for cysteine in pigment ligation and/or proper folding of the pigment-protein complex. Finally, no effect of divalent cations on pigment reassembly could be detected.Abbreviations cab chlorophyll a/b-binding protein genes - Chl chlorophyll - CP2 light-harvesting chlorophyll A+b-protein complex fractionated by mildly denaturing LDS-PAGE from Photosystem II in thylakoids - CP 43 and CP 47 chlorophyll a-antenna complexes fractionated from Photosystem II in thylakoids by mildly denaturing LDS-PAGE at 4°C - IgG gamma immunoglobulin - LDS lithium dodecyl sulfate - LDS-PAGE lithium dodecyl sulfate polyacrylamide gel electrophoresis at 4°C - LHC I and LHC II thylakoid light-harvesting chlorophyll a+b-protein holocomplexes associated with Photosystems I and II, respectively - PS II Photosystem II - TX100 Triton X-100 - TX100-derived LHC light-harvesting complexes enriched in LHC II following fractionation of thylakoids by TX100     

PHYLOGENETIC DISTRIBUTION OF THE MAJOR DIATOM LIGHT-HARVESTING PIGMENT-PROTEIN DETERMINED BY IMMUNOLOGICAL METHODS 1

Monospecific, polyclonal antibodies raised against the apoprotein of the major light-harvesting pigment-protein of Phaeodactylum tricornutum Bohlin UTEX 646 were used to determine (1) whether this complex was common to the class Bacillariophyceae, whose members contain chlorophylls a and c and fucoxanlhin; (2) whether antigenically-related apoproteins were present in other chlorophyll c-containing groups, and (3) whether there was immunological homology with the light-hanvsting chlorophyll a/b protein of similar photosynthetic function in the Chlorophyta and vascular plants. We have used protein blotting techniques to show that antibodies against the two P. tricornutum light-harvesting complex polypeptides cross-reacted with one or two polypeptides of similar molecular weight (17–21 kD) in all ten diatom species examined, representing two orders and six families. No cross-reactivity was obtained with total membrane polypeptides from isolated representatives of three chromophyte algal divisions (Chrysophyta, Cryptophyta, Pyrrophyta), all of which contained chlorophyll c. No cross-reactivity was observed with membrane Polypeptides isolated from members of two classes of Chlorophte algae. These data suggest that the Bacillariophyceae may be monophyletic, and that the primary structure of the diatom light-harvesting complex is not closely related to pigment-protein complexes with similar function in other chlorophyll c-containing unicellular algal groups. Lastly, it may be possible to use the antibodies to the diatom light-harvesting polypeptides as specific markers for diatoms in natural phytoplankton assemblages.     

Events surrounding the early development of Euglena chloroplasts. 16. Plastid thylakoid polypeptides during greening

Using sulfolipid to locate plastid thylakoid membranes in gradients from dark-grown resting cells it has been possible to study the plastid thylakoid membrane polypeptides of Euglena gracilis var. bacillaris undergoing light-induced chloroplast development. All plastid thylakoid bands seen in dark-growing wild-type cells and in mutant W₃BUL in which plastid DNA is undetectable, are observed to increase in amount during plastid development. Others, which are undetectable in dark-grown wild-type and W₃BUL increase greatly during plastid development and appear to be those associated with pigment-protein complexes. The data obtained from experiments where the polypeptides were labeled with ³⁵S during development, either continuously or in pulses, were consistent with these findings. Cycloheximide strongly inhibited the increases in amount in all bands and chloramphenicol or streptomycin produced a lower level of inhibition in all bands indicating tight control of the formation of each plastid membrane constituent by the others. The formation of a polypeptide band of 25 000 molecular weight, thought to be a part of a pigment-protein complex of the thylakoid, and chlorophyll synthesis were inhibited identically by these antibiotics.     

The Light Harvesting System of the Diatom Cyclotella cryptica. Isolation and Characterization of the Main Light Harvesting Complex and Evidence for the Existence of Minor Pigment Proteins*

The main chlorophyll a/c light harvesting complex of the diatom Cyclotella cryptica was isolated by sucrose density gradient centrifugation. It consisted of two polypeptides of Mrs 18000 and 22000. Both polypeptides and fragments thereof, obtained by formic acid treatment, were blocked at their N-ter-mini. An antiserum raised against the two subunits selectively immunolabeled the thylakoid within the chloroplasts. The subunits were nuclear encoded and could be immunoprecipitated from poly (A)⁺ RNA as precursor proteins in the Mr range of 20000 to 24000. The existence of minor chlorophyll protein complexes and their possible function in light climate adaptation processes was investigated in cells adapted to low light and high light conditions. Low light grown cells contained more fucoxanthin and less β-carotene relative to chlorophyll a than high light adapted cells. The xanthophyll cycle pigments diatoxanthin and diadinoxanthin increased five-fold relative to chlorophyll a under high light conditions. Western-immunoblotting experiments with antisera raised against several chlorophyll a/b and chlorophyll a/c antenna complexes demonstrated that, beside the dominating chlorophyll a/c light harvesting complex, minor antenna complexes might exist, which, in part, seem to react to the light climate applied.     

Disturbed structure and function of chloroplasts during blocked biosynthesis of 5-aminolevulinic acid in the light

Xantha-702 mutant of cotton (Gossypium hirsutum L.) proved to have blocked synthesis of 5-aminolevulinic acid in the light. Accordingly, mutant leaves accumulated 2–5% chlorophyll of baseline. Mutant plants demonstrated disturbed production of pigment-protein complexes of photosystems I (PSI) and II (PSII) and generation of the chloroplast membrane system blocked at the early stages, largely, at the stages of vesicles and single short thylakoid. The functional activity of the PSI and PSII reaction centers was close to zero. Only the chlorophyll a/b light-harvesting complexes of PSI and PSII with the chlorophyll fluorescence peaks at 728 and 681 nm, respectively, were produced in the xantha-702 mutant. We propose that the genetic block of 5-aminolevunilic acid biosynthesis in the light in the xantha-702 mutant disturbs the formation and activity of the complexes of the reaction centers of PS-I and PS-II and inhibits the development of the whole membrane system of chloroplasts.     

A Cyanobacterial Chlorophyll Synthase-HliD Complex Associates with the Ycf39 Protein and the YidC/Alb3 Insertase

Macromolecular membrane assemblies of chlorophyll-protein complexes efficiently harvest and trap light energy for photosynthesis. To investigate the delivery of chlorophylls to the newly synthesized photosystem apoproteins, a terminal enzyme of chlorophyll biosynthesis, chlorophyll synthase (ChlG), was tagged in the cyanobacterium Synechocystis PCC 6803 (Synechocystis) and used as bait in pull-down experiments. We retrieved an enzymatically active complex comprising ChlG and the high-light-inducible protein HliD, which associates with the Ycf39 protein, a putative assembly factor for photosystem II, and with the YidC/Alb3 insertase. 2D electrophoresis and immunoblotting also provided evidence for the presence of SecY and ribosome subunits. The isolated complex contained chlorophyll, chlorophyllide, and carotenoid pigments. Deletion of hliD elevated the level of the ChlG substrate, chlorophyllide, more than 6-fold; HliD is apparently required for assembly of FLAG-ChlG into larger complexes with other proteins such as Ycf39. These data reveal a link between chlorophyll biosynthesis and the Sec/YidC-dependent cotranslational insertion of nascent photosystem polypeptides into membranes. We expect that this close physical linkage coordinates the arrival of pigments and nascent apoproteins to produce photosynthetic pigment-protein complexes with minimal risk of accumulating phototoxic unbound chlorophylls.