Salt-induced redox-independent phosphorylation of light harvesting chlorophyll a/b proteins in Dunaliella salina thylakoid membranes

This study investigated the regulation of the major light harvesting chlorophyll a/b protein (LHCII) phosphorylation in Dunaliella salina thylakoid membranes. We found that both light and NaCl could induce LHCII phosphorylation in D. salina thylakoid membranes. Treatments with oxidants (ferredoxin and NADP) or photosynthetic electron flow inhibitors (DCMU, DBMIB, and stigmatellin) inhibited LHCII phosphorylation induced by light but not that induced by NaCl. Furthermore, neither addition of CuCl₂, an inhibitor of cytochrome b₆f complex reduction, nor oxidizing treatment with ferricyanide inhibited light- or NaCl-induced LHCII phosphorylation, and both salts even induced LHCII phosphorylation in dark-adapted D. salina thylakoid membranes as other salts did. Together, these results indicate that the redox state of the cytochrome b₆f complex is likely involved in light- but not salt-induced LHCII phosphorylation in D. salina thylakoid membranes.     

Cloning and expression of a gene coding for the major light-harvesting chlorophyll a/b protein of photosystem II in the green alga <Emphasis Type="Italic">Dunaliella salina</Emphasis>

Genes encoding proteins of the major light-harvesting complex of photosystem II (LHCII) in higher plants are well studied. However, little is known about the corresponding genes in the green alga Dunaliella salina, although this knowledge might provide valuable information about the respective roles of each LHCII protein at the molecular level under extreme environmental conditions. Here, we describe an additional LhcII gene from D. salina. An LhcII cDNA cloned by screening a D. salina cDNA library contains an open reading frame encoding a protein of 261 amino acids with a calculated molecular mass of 27.8 kDa. The deduced amino acid sequence shows high homology with other LHCII proteins. Genomic DNA—obtained by PCR using a specific primer set corresponding to the 5′ and 3′ untranslated regions—was used to determine the intron-exon structure. Short-term changes in mRNA levels after a shift from low-light to high-light or dark conditions were analyzed by real-time quantitative PCR, and indicated that this gene expresses different mRNA levels under different light conditions.     

Calcium-induced formation of chlorophyll b and light-harvesting chlorophyll complex in cucumber cotyledons in the dark

Dark-grown cucumber seedlings were exposed to intermittent light (2 min light and 98 min dark) and then cotyledons were incubated with 50 mM CaCl₂ in the dark. Chlorophyll (Chl) a was selectively accumulated under intermittent light and Chl b was accumulated during the subsequent dark incubation with CaCl₂. The change in chlorophyll-protein complexes during Chl b accumulation induced by CaCl₂ in the dark was investigated by SDS-polyacrylamide gel electrophoresis. Chlorophyll-protein complex I and free chlorophyll were major chlorophyll-containing bands of the cotyledons intermittently illuminated 10 times. When these cotyledons were incubated with CaCl₂ in the dark, the light-harvesting Chl complex was formed. When the number of intermittent illumination periods was extended to 55, small amounts of Chl b and light-harvesting Chl complex were recognized at the end of intermittent light treatment, and these two pigments were further increased during the subsequent incubation of the cotyledons with CaCl₂ in the dark compared to water controls.     

Photosynthetic apparatus organization and function in the wild type and a chlorophyll b-less mutant of Chlamydomonas reinhardtii. Dependence on carbon source

 The assembly, organization and function of the photosynthetic apparatus was investigated in the wild type and a chlorophyll (Chl) b-less mutant of the unicellular green alga Chlamydomonas reinhardtii, generated via DNA insertional mutagenesis. Comparative analyses were undertaken with cells grown photoheterotrophically (acetate), photomixotrophically (acetate and HCO⁻ ₃) or photoautotrophically (HCO⁻ ₃). It is shown that lack of Chl b diminished the photosystem-II (PSII) functional Chl antenna size from 320 Chl (a and b) to about 95 Chl a molecules. However, the functional Chl antenna size of PSI remained fairly constant at about 290 Chl molecules, independent of the presence of Chl b. Western blot and kinetic analyses suggested the presence of inner subunits of the Chl a-b light-harvesting complex of PSII (LHCII) and the entire complement of the Chl a-b light-harvesting complex of PSI (LHCI) in the mutant. It is concluded that Chl a can replace Chl b in the inner subunits of the LHCII and in the entire complement of the LHCI. Growth of cells on acetate as the sole carbon source imposes limitations in the photon-use efficiency and capacity of photosynthesis. These are manifested as a lower quantum yield and lower light-saturated rate of photosynthesis, and as lower variable to maximal (F_v/F_max) chlorophyll fluorescence yield ratios. This adverse effect probably originates because acetate shifts the oxidation-reduction state of the plastoquinone pool, and also because it causes a decrease in the amount and/or activity of Rubisco in the chloroplast. Such limitations are fully alleviated upon inclusion of an inorganic carbon source (e.g. bicarbonate) in the cell growth medium. Further, the work provides evidence to show that transformation of green algae can be used as a tool by which to generate mutants exhibiting a permanently truncated Chl antenna size and a higher (per Chl) photosynthetic productivity of the cells. Received: 10 November 1999 / Accepted: 22 December 1999     

Formation of Chlorophyll-Protein Complexes during Greening 1. Distribution of Newly Synthesized Chlorophyll among Apoproteins

The relationship between the accumulation of Chl and the apoproteinsof the light-harvesting Chl a/b-protein complex of PS II (LHCII)during the greening of cucumber cotyledons was studied. LHCIIapoproteins were not detected in etiolated cotyledons. Uponillumination, Chl a was formed as a result of photoconversionof protochlorophyllide (Pchlide) which had accumulated in thedark. During the lag period that preceded the accumulation ofChl, a small amount of LHCII apoproteins appeared. The amountof LHCII apoproteins increased with increases in levels of Chlb, though somewhat more rapidly during the first 10 h of greening.Treatment with benzyladenine (BA) or levulinic acid (LA) wasused to vary the supply of Chl a for apoproteins by promotingor inhibiting the synthesis of Chl a, respectively. LA decreasedbut BA increased the rate of accumulation of Chl b and LHCIIapoproteins. Only small amounts of Chl b and LHCII apoproteinswere formed under intermittent illumination. However, in thepresence of chloramphenicol (CAP), which inhibits the synthesisof plastome-coded proteins including apoproteins of the P700-Chla-protein complex (CP1) and a Chl a-protein complex of PS II(CPa), we observed the accumulation of Chl b and LHCII apoproteins,both of which are of nuclear origin. During incubation in thedark after intermittent exposure to light, CAP alone allowedneither destruction nor accumulation of Chl b and LHCII apoproteins,but it did enhance the effect of CaCl₂ in inducing both Chlb and these apoproteins. These results can be explained by assumingthat apoproteins of CP1 and CPa have a higher affinity for Chla than do LHCII apoproteins. When the availability of Chl ais limited, these apoproteins compete with one another for Chla, with the resultant preferential formation of CP1 and CPa.However, when the supply of Chl a becomes large enough for saturationof apoproteins of CP1 and CPa, some of the Chl a is incorporatedinto LHCII apoproteins either directly or after conversion toChl b. Thus, the formation of different Chl-protein complexes(CPs) is regulated by the relative rates of synthesis of Chla and apoproteins and by differential affinities of the apoproteinsfor Chl a. ⁴Present address: Kyowa Hakko Co., Ltd., 4041, Ami-machi, Inashiki,Ibaraki, 300-03 Japan (Received September 14, 1989; Accepted April 26, 1990)     

Sequence conservation of light-harvesting and stress-response proteins in relation to the three-dimensional molecular structure of LHCII

The structure of pea light-harvesting complex LHCII determined to 3.4 Å resolution by electron crystallography (Kühlbrandt, Wang and Fujiyoshi (1994) Nature 367: 614–621) was examined to determine the relationship between structural elements and sequence motifs conserved in the extended family of light-harvesting antennas (Chl a/b, fucoxanthin Chl a/c proteins) and membrane-intrinsic stress-induced proteins (ELIPs) to which LHCII belongs. It is predicted that the eukaryotic ELIPs can bind at least four molecules of Chl. The one-helix prokaryotic ELIP of Synechococcus was modelled as a homodimer based on the high degree of conservation of residues involved in the interactions of the first (B) and third (A) helices of LHCII.Abbreviations CAB Chl a/b-binding - ELIP early light-inducible protein - FCP fucoxanthin-Chl a/c protein - Lut1, Lut2 lutein molecules 1 and 2     

Changes in the Levels of Chlorophyll and Light-Harvesting Chlorophyll a/b Protein of PS II in Rice Leaves Aged under Different Irradiances from Full Expansion through Senescence

Effects of irradiance on changes in the amounts of chlorophyll(Chl) and light-harvesting chlorophyll a/b protein of PS II(LHCII) were examined in senescing leaves of rice (Oryza sativaL.). Results of treatments at two irradiances (100% and 20%natural sunlight) were examined after the full expansion ofthe 13th leaf throughout the course of senescence. With 20%sunlight, the Chl content decreased only a little during leafsenescence, while with 100% sunlight it decreased appreciably.Similarly, the amount of LHCII protein during treatment with20% sunlight remained almost constant. However, the ratio ofChl a/b during the shade treatment decreased significantly andthe rate of decrease was greater than during the full-sunlighttreatment. The ratio of Chl a/b for Chl a and b bound to LHCIIwas about 1.2, irrespective of leaf age or irradiance treatment.When the amounts of Chl bound to LHCII were calculated fromthe total leaf content of Chl and the ratio of Chl a/b, assuminga ratio of Chl a/b bound to LHCII of 1.2, they were well correlatedwith the amounts of LHCII protein. Changes in the amounts of LHCII synthesized during the two irradiancetreatments were examined using an ¹⁵ tracer. Incorporation of¹⁵N into LHCII declined dramatically during both treatmentsfrom full expansion through senescence, suggesting that therewas little synthesis of LHCII protein during that time. In addition,the amount of LHCII synthesized during senescence was lowerduring the shade treatment than during the 100% sunlight treatment.These results indicate that the absence of an apparent changein levels of LHCII with shade treatment during senescence wascaused by the very low rate of turnover of LHCII protein. (Received June 17, 1992; Accepted September 28, 1992)     

Novel aspects of chlorophyll a/b-binding proteins

The light-harvesting proteins (LHC) constitute a multigene family including, in higher plants, at least 12 members whose location, within the photosynthetic membrane, relative abundance and putative function appear to be very different. The major light-harvesting complex of photosystem II (LHCII) is the most abundant membrane protein in the biosphere and fulfil a constitutive light-harvesting function for photosystem II while the early light-induced proteins (ELIPs) are expressed in low amounts under stress conditions. Primary sequence analysis suggests that all these proteins share a common structure which was resolved at 3.7 Å resolution by electron crystallography in the case of the major LHCII complex: Three transmembrane helices connected by hydrophilic loops coordinate seven chlorophyll a and five chlorophyll b molecules by histidine, glutamine, asparagine lateral chains as well as by charge compensated ionic pairs of glutamic acid and arginine residues; moreover, at least two xantophyll molecules are located at the centre of the structure in close contact with seven porphyrins, tentatively identified as chlorophyll a. The antenna system is also involved in the regulation of excitation energy transfer to reaction centre II. This function has been attributed to three members of the protein family, namely CP29, CP26 and CP24 (also called minor chlorophyll proteins) which have been recently characterised and shown to bind most of the xantophyll cycle carotenoids, thus suggesting that the non-photochemical quenching mechanism is acting in these proteins. Further support to this assignment comes from the recent identification of protonation sites in CP29 and CP26 by covalent dicyclohexhylcarbodiimide binding suggesting that these respond to low lumenal pH. In addition, CP29 is reversibly phosphorylated under light and cold stress conditions, undergoing conformational change, supporting the hypothesis that these subunits, present in low amounts in photosystem II, have a major regulatory role in the light-harvesting function and are thus important in environmental stress resistance.     

Effects of 5-Aminolevulinic Acid on the Accumulation of Chlorophyll b and Apoproteins of the Light-Harvesting Chlorophyll a/b-Protein Complex of Photosystem II

The effects were examined of 5-aminolevulinic acid (ALA) onthe accumulation of Chl and apoproteins of light-harvestingChl a/b-protein complex of photosystem II (LHCII) in cucumbercotyledons under intermittent light. A supply of ALA preferentiallyincreased the accumulation of Chl a during intermittent illumination.However, when cotyledons were pretreated with a brief exposureto light or benzyladenine (BA), the stimulatory effect of ALAon the increase in the level of Chl b was greater than thatin the level of Chl a, resulting in decreased ratios of Chla/b. Time-course experiments with preilluminated cotyledonsrevealed that LHCII apoproteins accumulated rapidly within thefirst 30 min of intermittent illumination with a decline duringsubsequent incubation in darkness. A supply of ALA did not affectthe accumulation of LHCII apoproteins during the intermittentlight period, but it efficiently inhibited the decline in theirlevels during the subsequent darkness. After exposure to a singlepulse of light of BA-treated cotyledons, the prompt increasein levels of LHCII apoproteins was not accompanied by the formationof Ch b, which began to accumulate later. The pattern of changesin levels of LHCII apoproteins was quite similar to that inlevels of Chl a. These results suggest that LHCII apoproteinsare first stabilized by binding with Chl a and that an increasedsupply of Chl a and the accumulation of LHCII apoproteins areprerequisites for the formation of Chl b. ¹Present address: Department of Chemistry, Faculty of Scienceand Technology, Meijo University, Aichi, 468 Japan.     

Evidence for a light-harvesting chlorophyll a-protein complex in a chlorophyll b-less barley mutant

Chloroplasts of a chlorophyll (Chl) b-less barley mutant were solubilized with digitonin and fractionated by polyacrylamide gel electrophoresis with sodium deoxycholate in the running buffer. By this procedure, in contrast to using sodium dodecylsulfate (SDS) for solubilization, a Chl a-protein analogous to the major light-harvesting Chl a-b protein complex from wildtype chloroplasts was recovered. This mutant Chl a-protein comprises about fifty percent of the total Chl a, and is very similar in carotenoid, amino acid, protein and polypeptide composition to the major wildtype antenna Chl a-b protein. The only major differences we have found is its instability in the presence of SDS and sensitivity to protease action. Even with deoxycholate, the mutant Chl a complex often dissociates during electrophoresis into two green bands. The lack of Chl b appears to affect the normal organization of Chl a and protein in such a way as to render the complex more unstable.CIW-DPB No. 917.     

Comparison of chlorophyll a spectra in wild-type and mutant barley chloroplasts grown under day or intermittent light

The absorption (640–710 nm) and fluorescence emission (670–710 nm) spectra (77 K) of wild-type and Chl b-less, mutant, barley chloroplasts grown under either day or intermittent light were analysed by a RESOL curve-fitting program. The usual four major forms of Chl a at 662, 670, 678 and 684 nm were evident in all of the absorption spectra and three major components at 686, 693 and 704 nm in the emission spectra. A broad Chl a component band at 651 nm most likely exists in all chlorophyll spectra in vivo. The results show that the mutant lacks not only Chl b, but also the Chl a molecules which are bound to the light-harvesting, Chl a/b, protein complex of normal plants. It also appears that the absorption spectrum of this antenna complex is not modified appreciably by its isolation from thylakoid membranes.Abbreviations Chl chlorophyll - DL daylight - ImL intermittent light - WT wildtype - LHC light-harvesting Chl a/b protein complex - S.E. standard error of the mean DBP-CIW No. 763.     

The effects of detergents DDM and β-OG on the singlet excited state lifetime of the chlorophyll a in cytochrome b6f complex from spinach chloroplasts

The singlet excited state lifetime of the chlorophyll a (Chl a) in cytochrome b ₆ f (Cyt b ₆ f) complex was reported to be shorter than that of free Chl a in methanol, but the value was different for Cyt b ₆ f complexes from different sources (∼200 and ∼600 ps are the two measured results). The present study demonstrated that the singlet excited state lifetime is associated with the detergents n-dodecyl-β-D-maltoside (DDM) and n-octyl-β-D-glucopyranoside (β-OG), but has nothing to do with the different sources of Cyt b ₆ f complexes. Compared with the Cyt b ₆ f dissolved in β-OG, the Cyt b ₆ f in DDM had a lower fluorescence yield, a lower photodegradation rate of Chl a, and a shorter lifetime of Chl a excited state. In short, the singlet excited state lifetime, ∼200 ps, of the Chl a in Cyt b ₆ f complex in DDM is closer to the true in vivo.     

The inter-monomer interface of the major light-harvesting chlorophyll a/b complexes of photosystem II (LHCII) influences the chlorophyll triplet distribution

Under strong light conditions, long-lived chlorophyll triplets (³Chls) are formed, which can sensitize singlet oxygen, a species harmful to the photosynthetic apparatus of plants. Plants have developed multiple photoprotective mechanisms to quench ³Chl and scavenge singlet oxygen in order to sustain the photosynthetic activities. The lumenal loop of light-harvesting chlorophyll a/b complex of photosystem II (LHCII) plays important roles in regulating the pigment conformation and energy dissipation. In this study, site-directed mutagenesis analysis was applied to investigate triplet–triplet energy transfer and quenching of ³Chl in LHCII. We mutated the amino acid at site 123 located in this region to Gly, Pro, Gln, Thr and Tyr, respectively, and recorded fluorescence excitation spectra, triplet-minus-singlet (TmS) spectra and kinetics of carotenoid triplet decay for wild type and all the mutants. A red-shift was evident in the TmS spectra of the mutants S123T and S123P, and all of the mutants except S123Y showed a decrease in the triplet energy transfer efficiency. We propose, on the basis of the available structural information, that these phenomena are related to the involvement, due to conformational changes in the lumenal region, of a long-wavelength lutein (Lut2) involved in quenching ³Chl.     

Exchange of pigment-binding amino acids in light-harvesting chlorophyll a/b protein

Four amino acids in the major light-harvesting chlorophyll (Chl) a/b complex (LHCII) that are thought to coordinate Chl molecules have been exchanged with amino acids that presumably cannot bind Chl. Amino acids H68, Q131, Q197, and H212 are positioned in helixes B, C, A, and D, respectively, and, according to the LHCII crystal structure [Kühlbrandt, W., et al. (1994) Nature 367, 614-621], coordinate the Chl molecules named a(5), b(6), a(3), and b(3). Moreover, a double mutant was analyzed carrying exchanges at positions E65 and H68, presumably affecting Chls a(4) and a(5). All mutant proteins could be reconstituted in vitro with pigments, although the thermal stability of the resulting mutant versions of recombinant LHCII varied significantly. All complexes reconstituted with the mutant proteins contained fewer chlorophyll molecules per two lutein molecules than complexes reconstituted with the wild-type protein. However, the chlorophyll-binding amino acids could not be unambiguously assigned to binding either chlorophyll a or b, as in most cases more than one chlorophyll molecule was lost due to the mutation. The changes in Chl stoichiometries suggest that in LHCII some chlorophyll positions can be filled with either Chl a or b. Only some of the point mutations in LHCII affected the ability of the apoprotein to assemble into trimeric LHCII upon insertion into isolated thylakoid membranes. Among these were exchanges of H68 with either F or L, suggesting that the stability of the LHCII trimer significantly depends on this amino acid or the Chl molecule named a(5) that is attached to it and is located close to the center of the trimeric complex. The ion pair bridge between E65 and R185 in LHCII does not appear to be essential for the proper folding of the protein.     

Responses of chlorophyll <Emphasis Type="Italic">b</Emphasis>-less <Emphasis Type="Italic">chlorina</Emphasis> 3613 mutant of barley to a prolonged decrease in illuminance: 2. Dynamics of carotenoids in leaf chloroplasts

Barley (Hordeum vulgare L.) mutant chlorina 3613 is notable for a lack of chlorophyll b (Chl b), low content of chlorophyll a (Chl a) and carotenoids in the chloroplasts, as well as reduction in the majority of components of LHCI and LHCII. Incompletely developed photosynthetic machinery of chlorina 3613 results in suppressed growth, lower biomass, and the declined rate of photosynthesis (as compared with the wild-type cv. Donaria). The lack of Chl b and greater part of peripheral antenna suggests that this mutant will have difficulties during acclimation to long-term shading because the light-harvesting role of Chl b-containing antenna becomes more important under the shortage of light. Earlier, our experiments with the mature chlorina 3613 plants shaded for one week at PAR photon flux density of 60 and 40% of that in full sunlight showed a stimulating effect of shading on growth, biomass accumulation, and Chl a synthesis in chlorina 3613 when biosynthesis of Chl b did not occur [1]. In this work, we investigated in more detail the changes in the content of carotenoids in chlorina 3613. We found that in Donaria at both investigated levels of illumination (60 and 40% of full sunlight) and in chlorina 3613 at 60% illumination, moderate reversible changes typical of shade-enduring plants occur in the content of carotenoids. In chlorina 3613 at 40% illumination, the content of β-carotene increased considerably (by 3 times) with simultaneous accumulation of Chl a. When full illumination was restored, the content of β-carotene decreased and remained on the level, which exceeded its initial content in the plants without shading by 38%; this level, was maintained by the end of vegetation. The changes in the contents of β-carotene and Chl a in chlorina 3613 were not accompanied by any accumulation of xanthophylls or changes in the relative content of active violaxanthin. The obtained results suggest that a long-term shading of the leaves of mature chlorina 3613 plants induced the formation of certain components of photosynthetic apparatus: reactive centers and core parts of photosystems’ antennae as well as proteins CP26 and CP29 and in this way contributed to partial restoration of photosynthetic activity and production process in the mutant lacking Chl b.     

A chlorophyll b-less mutant of Chlamydomonas reinhardii lacking in the light-harvesting chlorophyll complex but not in its apoproteins

The mutant pg 113, derived from Chlamydomonas reinhardii, arg₂⁻ mt⁺ (parent strain), completely lacks chlorophyll (Chl) b but is still able to grow under autotrophic conditions. The light-harvesting Chl complex (LHCP) is absent. This is shown (a) by the lack of the corresponding signal in the CD spectrum of thylakoids and (b) by the absence of the band of the LHCP after electrophoresis of partially solubilized thylakoid membranes on lithium dodecyl sulfate polyacrylamide gels. All the other chlorophyll-protein complexes are present. In spite of the absence of the LHCP, all the polypeptide components of this complex are present in the mutant in the same ratios as in the parent strain, although in slightly reduced amounts. The LHC apoproteins are synthesized, processed and transported into the thylakoid membrane of the mutant. Moreover, the phosphorylation of thylakoid membrane polypeptides, which is related to the regulation of the energy distribution between Photosystem I and II, is the same in the mutant and in the parent strain, indicating that phosphorylation is not dependent on the presence of Chl b. Electron micrographs of thin sections of whole cells show that there are stacked regions of thylakoids in both the mutant and the parent strain chloroplasts. However, in the mutant, stacks are located near the chloroplast envelope, while long stretches or sometimes circles of unstacked membranes are found in the interior, mostly around the pyrenoid.     

Excitation dynamics and relaxation in the major antenna of a marine green alga Bryopsis corticulans

The light-harvesting complexes II (LHCIIs) of spinach and Bryopsis corticulans as a green alga are similar in structure, but differ in carotenoid (Car) and chlorophyll (Chl) compositions. Carbonyl Cars siphonein (Spn) and siphonaxanthin (Spx) bind to B. corticulans LHCII likely in the sites as a pair of lutein (Lut) molecules bind to spinach LHCII in the central domain. To understand the light-harvesting and photoprotective properties of the algal LHCII, we compared its excitation dynamics and relaxation to those of spinach LHCII been well documented. It was found that B. corticulans LHCII exhibited a substantially longer chlorophyll (Chl) fluorescence lifetime (4.9 ns vs 4.1 ns) and a 60% increase of the fluorescence quantum yield. Photoexcitation populated ³Car* equally between Spn and Spx in B. corticulans LHCII, whereas predominantly at Lut620 in spinach LHCII. These results prove the functional differences of the LHCIIs with different Car pairs and Chl a/b ratios: B. corticulans LHCII shows the enhanced blue-green light absorption, the alleviated quenching of ¹Chl*, and the dual sites of quenching ³Chl*, which may facilitate its light-harvesting and photoprotection functions. Moreover, for both types of LHCIIs, the triplet excitation profiles revealed the involvement of extra ³Car* formation mechanisms besides the conventional Chl-to-Car triplet transfer, which are discussed in relation to the ultrafast processes of ¹Chl* quenching. Our experimental findings will be helpful in deepening the understanding of the light harvesting and photoprotection functions of B. corticulans living in the intertidal zone with dramatically changing light condition.     

Characterization of Cytoplasmic and Nuclear Mutations Affecting Chlorophyll and Chlorophyll-Binding Proteins during Senescence in Soybean

Soybean plants (Glycine max [L.] Merr. cv Clark) carrying nuclear and cytoplasmic “stay-green” mutations, which affect senescence, were examined. Normally, the levels of chlorophyll (Chl) a and b decline during seedfill and the Chl a/b ratio decreases during late pod development in cv Clark. Plants homozygous for both the d₁ and d₂ recessive alleles, at two different nuclear loci, respectively, retained most (64%) of their Chl a and b and exhibited no change in their Chl a/b ratio. Combination of G (a dominant nuclear allele in a third locus causing only the seed coat to stay green during senescence) with d₁d₂ further inhibited the loss of Chl in the leaf. Whereas the thylakoid proteins seem to be degraded in normal Clark leaves during late pod development, they were not substantially diminished in d₁d₂ and Gd₁d₂ leaves. In plants carrying a cytoplasmic mutation, cytG, Chl declined in parallel with normal cv Clark; however, the cytG leaves had a much higher level of Chl b, and somewhat more Chl a, remaining at abscission, enough to color the leaves green. In cytG, most thylakoid proteins were degraded, but the Chl a/b-binding polypeptides of the light-harvesting complex in photosystem II (LHCII), and their associated Chl a and b molecules, were not. Thus, the combination of d₁ and d₂ causes broad preservation of the thylakoid proteins, whereas cytG appears to selectively preserve LHCII. The cytG mutation may be useful in elucidating the sequence of events involved in the degradation of LHCII proteins and their associated pigments during senescence.     

Preferential accumulation of apoproteins of the light-harvesting chlorophyll a/b-protein complex in greening barley leaves treated with 5-aminolevulinic acid

In order to study the coordinate accumulation of chlorophyll (Chl) and apoproteins of Chl-protein complexes (CPs) during chloroplast development, we examined changes in the accumulation of the apoproteins in barley (Hordeum vulgare L.) leaves when the rate of Chl synthesis was altered by feeding 5-aminolevulinic acid (ALA), a precursor of Chl biosynthesis. Pretreatment with ALA increased the accumulation of Chl a and Chl b 1.5- and 2.3-fold, respectively, after 12 cycles of intermittent light (2 min light followed by 28 min darkness). Apoproteins of the light-harvesting Chl a/b-protein complex of photosystem II (LHCII) were increased 2.4-fold with ALA treatment. However, apoproteins of the P700-Chl a-protein complex (CP1) and the 43-kDa apoprotein of a Chl a-protein complex of photosystem II (CPa) were not increased by ALA application. With respect to CPs themselves, LHCII was increased when Chl synthesis was raised by ALA feeding, whereas CP1 exhibited no remarkable increase. These results indicate that LHCII serves a role in maintaining the stoichiometry of Chl to apoproteins by acting as a temporary pool for Chl molecules.Abbreviations ALA 5-aminolevulinic acid - Chl chlorophyll - CP chlorophyll-protein complex - CPa chlorophyll a-protein complex of PSII - CP1 P700-chlorophyll a-protein complex - LDS lithium dodecyl sulfate - LHCII light-harvesting chlorophyll a/b-protein complex of PSII This work was supported by the Grants-in-Aid for Scientific Research (04304004) from the Ministry of Education, Science and Culture, Japan.