Pigment Composition of Chlorophyll-Protein Complexes Isolated from the Green Alga Bryopsis maxima

SDS-solubilized thylakoid membranes of Bryopsis maxima showeda similar pattern to those of higher plants in SDS-poIyacrylamidegel electrophoresis. Absorption spectra and pigment compositionof both CP1 and CPa bands were similar to those of higher plantsand other algae. Five bands containing chlorophyll (Chl) b weredivided into three categories; a group of major light-harvestingChl a/b-protein complexes (LHCP 1, LHCP 2 and LHCP 3), a minorLHCP (LHCP 3') and a photosystem I complex (CP1a). LHCP 1, thehigh molecular form, showed the lowest Chl a/b ratio among theLHCPs, and contained only xanthophylls as carotenoids. LHCP2, LHCP 3 and LHCP 3' bands contained xanthophylls and carotene.Carotenoid composition of LHCP 3' was different from that ofthe major LHCPs. CP1a band contained a considerable amount ofsiphonaxanthin and siphonein. (Received May 24, 1985; Accepted December 13, 1985)     

Chlorophyll-Protein Complexes Associated with Photosystem I Isolated from the Green Alga, Bryopsis maxima

Six chlorophyll (Chl)-protein complexes associated with photosystemI (CPla), and the PS I reaction center complex (CPl) were isolatedfrom the thylakoid membranes of the green alga, Bryopsis maxima,by SDS-polyacrylamide gel electrophoresis. CPla had four polypeptides(22, 24, 25, 26 kDa) in addition to the 67 kDa polypeptide ofCPl. These complexes may thus possibly be a combination of CPland antenna complexes for PS I. Six CPla showed almost the sameoptical properties, with absorption maxima at 650 and 677 nmand contained carotene and a small amount of xanthophylls. TheChl a/b ratios of these CPla were about 2, while that of CPlwas 14. CPla showed a fluorescence emission maximum at 695 nm;its excitation spectrum had peaks at 438, 470 and 540 nm, correspondingto the absorption maxima of Chl a, Chl b, xanthophylls, respectively.An antenna complex free of CPl has been detected in some plantsbut was not found in the present alga. ¹Present address: Department of Botany, The University of Adelaide,Adelaide, S.A. 5001, Australia (Received April 17, 1986; Accepted June 26, 1986)     

Seasonal Effects on Photosynthetic Electron Transport and Fluorescence Properties in Isolated Chloroplasts of Pinus silvestris

Chloroplasts were isolated from primary needles of 1-year-old seedlings and from secondary needles of a 20-year-old pine tree in a natural stand. In autumn the electron transport capacities of PSII, PSI and PS (II + I) decreased and the electron transport between PSII and PSI became inhibited in October in the 20-year-old tree. This inhibition lasted until May the following year. The partial reactions of PSI and PSII still showed low but fairly constant rates during the whole winter seedlings. Seasonal changes in the electron transport properties of 1-year-old showed the same general trends as observed in the 20-year-old tree, but the changes were less pronounced. However, in snow-covered seedlings the PSI-mediated electron transport and the electron transport from H₂O to NADP increased during the late winter when the seedlings were still covered by snow. The total chlorophyll content of the needles decreased in autumn and winter. Low temperature fluorescence ratios of F692/F680 and F726/F680 indicated more severe destruction of the chlorophyll a antennae closely associated with the two photosystems than of the light harvesting chlorophyll a/b complex. In this case, too, the changes were more pronounced in the 20-year-old tree than in the 1-year-old seedlings. The chlorophyll/P700 ratios indicated a more marked reduction in the reaction centre molecules during autumn than in the antennae chlorophyll molecules. The changes in electron transport and low temperature fluorescence properties which occurred during autumn and winter were mainly reversed during spring.     

Effects of Water Stress on Chlorophyll-Protein Complexes in Wheat Chloroplasts

The excitation energy transfer from light harvesting chlorophyll protein complexes to PS Ⅱ was inhibited under water stress. The contents of iriternal antennae chlorophyll-protein complexes of PS Ⅱ (CPa), light harvesting chlorophyll-protein complexes of PS Ⅱ (LHC Ⅱ ), light harvesting chlorophyll-protein of PS Ⅰ (LHC Ⅰ ) and chlorophyll a protein complex of reaction center of PS Ⅰ were decreased by water stress. The decrease of chlorophyll-protein complexes of PS Ⅱ was greater than that of PS Ⅰ . It was indicated that the amount of 25 kD polypeptide of LHC Ⅱ in particular, as well as that of 43 and 47 kD polypeptides of CPa, and 21 kD polypeptide of LHC Ⅰ , were reduced by water stress.     

Effect of Magnesium on Chlorophyll-Protein Complexes

The effect of Mg²⁺ during the isolation of chlorophyll-protein complexes was studied in two moss species (Pleurozium schreberi and Ceratodon purpureus) and New Zealand spinach (Tetragonia expansa). When 2 mM MgCl₂ was included in all the extraction and separation phases, the proportions of chlorophyll-protein complex I. were very small in all plants studied. The withdrawal of Mg²⁺ considerably increased the proportions of CP I. The most pronounced increase in the chlorophyll present as CP I was found when Mg²⁺ was withdrawn from the gel, and this also increased the mobility of the CP II complex and free pigment zone. Exclusion of Mg²⁺ from the running buffer had very little effect. Although Mg²⁺ had little effect on the relative amount of chlorophyll in CP II, the withdrawal of Mg²⁺ from all the extraction and separation phases caused formation of polymers of CP II. In the mosses, the formation of polymers of CP II seemed to be more obvious in the species with large grana. Absence of Mg²⁺ from all the extraction and separation phases sometimes also produced a polymer of CP I.     

Effects of Season and Low Temperature on Polypeptides from Thylakoids Isolated from Chloroplasts of Pinus silvestris

Thylakoids isolated from pine chloroplasts were solubilized by sodium dodecyl sulphate and the polypeptides were separated by polyacrylamide gel electrophoresis. The chlorophyll-protein complexes, P700-CPa₁ and LH-CPa/b, had apparent molecular weights of 92,000 and 25,000, respectively. When the chlorophyll of P700-CPa₁ was extracted or photobleached, the apoprotein of P700-CPa₁ appeared as a pronounced peak in the polypeptide scan profile. The molecular weight of the apoprotein was 70,000. During autumn and winter the complex P700-CPa₁ was destroyed. This was primarily caused by bleaching of chlorophyll, as the 70,000 apoprotein increased in the scan profile when the complex P700-CPa₁ decreased. The winter destruction of P700-CPa₁ was less pronounced in old needles than in young. Freezing of frost-hardened seedlings did not change the polypeptide scan profile, unless the temperature was lowered below the frost-killing point followed by thawing and post-treatment in light or darkness above 0°C. Again the main destruction occurred in the P700-CPa₁ complex, but in this case no significant increase of the apoprotein was observed. These alterations in the polypeptide scan profile of frost-killed needles were not caused by the low temperature treatment as such, but they occurred after thawing of the needles.     

Chlorophyll-Protein Complexes of Blue-Green Algae Isolated by a New Gel Electrophoresis System with High Resolving Power

At least 13 chlorophyll bands from the thylakoid membranes of blue-green algae could be clearly resolved by SDS-PAGE employing a new improved procedure. They were designated as CPIa, CPIb, CPIc, CPId, CPIe, CPIf, CPIg, CHIh, CPal, CPa2, CPa3, CPa4 and FC. 8 chlorophyll-protein complexes, CPIa-CPIh, had the same absorption spectrum at 676 nm in the red and 436 nm in the blue region. They belonged to the chlorophyll-protein complexes of PS Ⅰ. 4 chlorophyll-protein complexes, CPal-CPa4, had a red absorption peak at 670­672 nm and a blue one at 436 nm. Their fluorescence emission peak at 77K was at 685 nm. They were chlorophyll-protein complexes of PS Ⅱ.     

Chlorophyll-Protein Complexes in Salix sp. 'Aquatica Gigantea' under Strong and Weak Light I. Spectral Characterization of the Chlorophyll-Protein Complexes

The distribution of chlorophyll in the chlorophyll-protein complexeswas studied in Salix sp. ‘aquatica gigantea’ grownunder high and low irradiance. The chlorophyll- containing bandsthat could be separated by SDS-polyacrylamide gel electrophoresisin strong and weak light numbered 9 to 13 and 9 to 11, respectively.In strong light the following bands were separated, in the orderof the highest to the lowest molecular weight: one to two chlorophylla/b-protein complexes, three to four chlorophyll a-containingbands similar to the P700-chlorophyll a-protein complex (CPIand its oligomers), three oligomers of the light-harvestingchlorophyll a/b-protein complex (LHCP^***, LHCP^**, LHCP^*), twochlorophyll a-protein complexes (CPa₂ and CPa₁), the light-harvestingchlorophyll a/b-protein complex (LHCP) and the protein freepigment (FP). In weak light the same chlorophyll-containingbands were separated with the exception that no high molecularweight chlorophyll a/b-protein complexes could be observed.In strong light the CPI complexes were the largest structuralcomponent of the chloroplast lamellae. In weak light the LHCPcomplexes together contributed the major proportion of the totalchlorophyll. The increase in the chlorophyll associated withthe LHCP complex was possibly caused by reorganization of thelamellar structure or by increased synthesis of the LHCP^** complex,which appeared to be a labile complex in weak light. (Received February 1, 1982; Accepted May 10, 1982)     

Chlorophyll-Protein Complexes of the Cyanophyte, Nostoc sp

Four chlorophyll-protein complexes have been resolved from the cyanophyte, Nostoc sp., by sodium dodecyl sulfate (SDS) polyacrylamide gel electrophoresis at 4 C. Complexes solubilized by SDS from Spinacia oleracea were run for comparison. As has been well documented, the P700-chlorophyll a-protein complex from the higher plant and blue-green algal samples are similar, and the light-harvesting pigment protein complex is present only in the former. Most noteworthy are two closely migrating chlorophyll proteins in Nostoc sp. which have approximately the same mobility as a single chlorophyll-protein band resolvable from spinach. The absorption maximum of the complex from spinach is at 667 nanometers, and those of the two complexes from Nostoc sp. are at 667 and 669 nanometers; the fluorescence emission maximum at −196 C is at 685 nanometers, and the 735 nanometer fluorescence peak, characteristic of the P700-chlorophyll a-protein complex, is absent. The apoproteins of these new complexes from Nostoc sp. and spinach are in the kilodalton range. It appears that at least one of these two chlorophyll-protein complexes from Nostoc sp. compares with those recently described by others from higher plants and green algae as likely photosystem II complexes, perhaps containing P680, although no photochemical data are yet available.     

The Chlorophyll-Protein Complexes Resolved from Ultrasonically Broken Thylakoid Memb-ranes of Blue-Green Algae

When the thylakoid membranes of blue-green algae were broken by ultrasonic vibrations and subjected to polyacrylamide gel electrophoresis at 4℃, six green zones were resolved. They were designated as CPIa, CPlb, CPI; CPal, CPa2, and FC. The absorption spectrum of CPI had a red maximum at 674 nm and a peak in the blue at 435 nm. It was identified as PS chlorophyll a-protein Complex, but was contaminated with minor PSⅡ which was implied by the appearance of fluorescence emission peak at 680 nm besides the main one at 725 nm at 77 K. The spectral properties of CPIa and CPlb were similar to that of CPl. The absorption spectra of CPa1 and CPa2 were similar, both having red maxima at 667 nm and peaks in the blue at 431.5 nm. Their fluorescence emission had the same peaks at 684 nm at 77 K indicating that they belonged to PSⅡ. It was recognized that CPal of 47 kD is the reaction center complex of photosystem Ⅱ and CPa2 of 40 kD is the internal antenna complex of photosystem Ⅱ. The spectral characteristics of the chlorophyll-protein complexes resolved by ultrasonic method were similar to those of the same complexes resolved by SDS solubilization, except the absorbance positions of CPa1 and CPa2 in the blue peak and the red one which shifted to blue about 3–5 nm. It was calculated that in thylakoid membranes of blue-green algae 40.93% chlorophyll was in PSⅠ, while 38.78% of chlorophyll in PSⅡ. The difference of chlorophyll contents between PSⅠ and PSⅡ was only 2.15%. Concerning the fact that minor PSⅡ compound remained in the part of PSⅠ zones, it might be concluded that the distribution of chlorophyll between PSⅠ and PSⅡ in blue-green algae was equal. This result was in agreement with the hypothesis that PSⅠ and PSⅡ operates in series in photosynthetic electron transport.     

Appearance of Chlorophyll-Protein Complexes in Greening Barley Seedlings

The sequential appearance of chlorophyll-protein complexes (CP)in greening barley leaves was studied by an improved methodof SDS-polyacrylamide gel electrophoresis (PAGE). Solubilizedthylakoid membranes were purified using a sucrose step gradientand CPs were separated by PAGE with low concentrations of SDSin solubilizing and reservoir buffers. At 10 min after the onsetof illumination, a chlorophyll-protein complex (CPX) was detected.It was a labile CP, its chlorophyll (Chl) being easily releasedfrom the apoprotein during electrophoresis. The P700-chlorophylla/b-protein complex (CPl) appeared after 45–60 min ofillumination together with P700 activity. Light-harvesting chlorophylla/b-protein complex (LHCP) began to accumulate at 2.5 h withthe beginning of Chl b synthesis. In some cases a small amountof CPa could be detected after 6 h of greening. The time-differencespectrum between homogenates of leaves illuminated for 30 and60 min had an absorbance maximum at 677 nm, showing that a redshift indicative of CPl formation began soon after completionof the Shibata shift. The time-difference spectrum between 3.5-hand 4.0-h illuminated leaves resembled the absolute spectrumof fully greened leaves, indicating that at this stage, spectralcomponents were being synthesized at the same ratio at whichthey exist in fully greened tissues. Both absolute and time-differencespectral data supported the SDS-PAGE results. (Received February 27, 1985; Accepted May 8, 1985)     

Chlorophyll-Protein Complexes of a Photosystem II Mutant of Maize : Evidence that Chlorophyll-Protein a-2 and a Chlorophyll-Protein Complex Derived from a Photosystem I Antennae System Comigrate on Polyacrylamide Gels

Use of the octyl β-d-glucopyranoside solubilization procedure of Camm and Green (1980 Plant Physiol 66: 428-432) reveals that thylakoid membranes of a photosystem (PS) II-deficient maize (Zea mays L.) mutant lack two chlorophyll protein (CP) complexes associated with PSII, i.e. CPa-1 and CPa-2. In contrast, when lithium dodecyl sulfate is used to solubilize the membranes of the mutant prior to electrophoretic separation, a CP complex is observed which has a mobility similar to that of CPa-2. Comparison of spectral characteristics and polypeptide composition of the green bands in this region taken from samples of the mutant, normal sibling control plants and from PSII preparations indicate that the CP complex observed in the mutant represents a portion of a light-harvesting complex of PSI (Mullet et al. 1980 Plant Physiol 65: 814-822). The green band observed in normal maize samples can contain both the CPa-2 complex as well as the CP complex derived from the PSI antennae system.     

Chlorophyll-Protein Complexes in Salix sp. 'Aquatica Gigantea' under Strong and Weak Light II. Effect of Water Stress on the Chlorophyll-Protein Complexes and Chloroplast Ultrastructure

The effect of slowly-induced water stress on the distributionof chlorophyll among the chlorophyll-protein complexes and onthe chloroplast ultrastructure was studied in Salix sp. ‘aquaticagigantea’ grown under two different light regimes. Underhigh irradiance the proportion of chlorophyll was largest inthe P700-chlorophyll-a protein complex (CPI). With increasingwater stress the proportion of the light-harvesting chlorophylla/b-protein complex (LHCP) and the chlorophyll a-protein complex(CPa) decreased, and these changes corresponded with inversechanges in the amount of chlorophyll in the protein free pigment(FP) band. The CPI complex remained stable throughout the dryingperiod. Under low irradiance the LHCP complex was the largeststructural component and its proportion of the total chlorophyllremained constant with increasing water stress. Under theselight conditions CPI and the CPa complex appeared to be thelabile components of the chloroplast lamellae. The integrityof the chloroplast membranes, as judged by electron microscopicobservations, was preserved well under both light regimes andwith increasing water stress. This and the relative constancyof the chlorophyll content during the experiments suggestedthat no great changes had occurred in the lamellar structureduring water stress. In the chloroplast stroma area, however,large crystal formations were observed under the strong lightregime with increasing water stress. In weak light these crystalstructures could be seen in the well-watered controls, but seemedto disappear totally as water stress became severe. (Received February 1, 1982; Accepted May 10, 1982)     

Characterization of Photosystem I Chlorophyll-Protein Complexes Reconstituted into Phosphatidylcholine Liposomes

Chlorophyll-protein complexes associated with photosystem Iwere isolated from native photosystem I particles (PS I-200)of spinach thylakoids by centrifugation in SDS-sucrose densitygradients. These complexes were designated CPIa (Chl/P700 ratioof 160), CPI' (CW/P700 ratio of 70), and LHCI (light-harvestingChl a/bprotein complex associated with photosystem I). CPI'was reconstituted with and without LHCI into phosphatidylcholineliposomes by a freeze-thaw technique. The first-order rate constantfor P700-photooxidation in proteoliposomes reconstituted withCPI' plus LHCI increased with an increase in the concentrationof phosphatidylcholine. When the concentration of phosphatidylcholinewas more than 20 times (by weight) that of chlorophyll in thecomplexes, the rate constant under lightlimiting conditionswas approximately double that of a mixture of two complexesnot reconstituted into liposomes. The fluorescence emissionspectrum (77 K) of the proteoliposomes reconstituted with CPI'plus LHCI displayed a longer wavelength band at 730–733nm which was very similar to the spectrum of CPIa and whichwas not displayed in the spectrum of a mixture of CPI' and LHCIwithout liposomes. The circular dichroism spectrum of a mixtureof CPI' and LHCI indicated that the intensity of both a positivepeak at 665 nm and a negative peak at 686 nm increased whena mixture of the two complexes was reconstituted into liposomes.These results suggest that some alteration of chlorophyll organizationoccurs in proteoliposomes reconstituted with both CPI' and LHCI,facilitating energy transfer from LHCI to the reaction centerof photosystem I. (Received July 18, 1986; Accepted March 12, 1987)     

Comparative Study of Chlorophyll-Protein Complexes of Thylakoids of Bryopsis and Spinacia

properties, pigment compositions, Chl a/b ratios and apparent molecular weights of chlorophyll-protein complexes were compared between spinach and a marine green alga, Bryopsis corticulans. The results are as follows: 1. Ten chlorophyll-protein complexes were resolved from spinach thylakoid membranes solubilized by SDS in a final SDS/Chl weight ratio of 10:1, and subjected to SDS-PAGE with 11% resolution gel. CPIa 1–3 and CPI belonged to photosystem Ⅰ, and the rest to phorosystem Ⅱ. The maximum absorption of CPIa2, CPIas and CPI were all at 674nm, but that of CPIa1 at 670nm, and those of LHCII and D2 at 670 and 673nm, respectively. Chlorophyll ia PSⅡ was 63% of the total. In PSⅡ, most of chlorophyll was in LHCII which contained 86% of the chlorophyll in PSⅡ. In PSⅠ, chlorophyll in CPla was 72% of the total. Chlorophyll a was the main pigment in PSⅠ components which have Chl a/b ratio over 15. 2. Eight chlorophyll-protein complexes were isolated from B. corticulans with a SDS/Chi weight ratio of 8:1 and 8% resolution gel. The maximum absorption of CPIa, CPI, LHCII and D2 were respectively at 671nm, 673nm, 669nm and 664nm. PSⅡ contained 77% of the total chlorophyll. LHCII chlorophyll was 95% of the PSⅡ chlorophyll. CPI held 77% of PSⅠ chloro~ phyll. There was more chlorophyll b in Bryopsis complexes, especially in LHCI1 (Chl a/b< 0.8). The molecular weights of Bryopsis complexes were higher than those of the spinach complexes. Bryopsis LHCII contained siphoxanthin and siphothin, the marked pigments of Siphohales, as functional pigments. The above results revealed three points of difference between these two plants. Firstly, Chl a is the main pigment in spinach, whereas in Bryopsis the main pigments are Chl b and siphoxanthin. This is in accordance with the suggestion that plants may change their pigment composition to adapt light regime in the environment during evolution. Secondly, in Bryopsis, chlorophyll is concentrated in photosystem Ⅱ, but in spinach chlorophyll is shared evenly by two photosystems. Finally, CPI in Bryopsis contained the major part of chlorophyll in PSⅠ, yet in spinach CPIa is the superior.     

Influences of Ce on the Formation of Chlorophyll-Protein Complexes in Chloroplasts of Cucumber Leaves

It has been proven that the Ce content of cucumber (Cucumis sativus L. ) leaves was enhanced with the increase of CeC13 concentration in Hoagland solution. The Chl a/b ratio of cucumber leaves in the control was the same as that in the treated plant, both being 3.67. However, under lower light intensity, the Chl a/b ratio in leaves of the contral was 2.72 whereas that of the treated leaves was 2.86. It showed that only under lower light intensity Ce could decrease the contents of chlorophyll b in leaves. The authors also evidenced that Ce was able to accelerate the formation of chlorophyll-protein complexes of PS Ⅰ and 110 kD polypeptide and decrease the light harvesting complex protein and 27 kD polypeptide.     

Chlorophyll-Protein Complexes from Euglena gracilis and Mutants Deficient in Chlorophyll b: II. Polypeptide Composition

Chlorophyll-protein complexes (CPs) obtained from thylakoids of Euglena gracilis Klebs var bacillaris Cori contain the following polypeptides (listed in parentheses in order of prominence after Coomassie R-250 staining of polyacrylamide gels): CP Ia (66, 18, 22, 22.5, 27.5, 21, 28, 24, 25.5, and 26 kilodaltons [kD]); CP I (66 kD); CPx (41 kD); LHCP₂ (an oligomer of LHCP) (26.5, 28, and 26 kD); CPy (27 and 19 kD); CPa (54 kD); and LHCP (26.5, 28, and 26 kD). Mutants of bacillaris low in chlorophyll b (Gr₁BSL, G₁BU, and O₄BSL; Chl a/b [mol/mol] = 50-100) which lack CP Ia, LHCP₂, and LHCP also lack or are deficient in polypeptides associated with these complexes in wild-type cells. Mutants G₁ and O₄, which also lack CPy, lack the CPy-associated polypeptides found in wild-type and Gr₁. Using an antiserum which was elicited by and reacts strongly and selectively with the SDS-treated major polypeptide (26.5 kD) of the LHCP complexes of wild-type, this polypeptide is undetectable in the mutants (0.25% of the level in wild-type on a cell basis); the antiserum does not react with the SDS-treated 28 kD polypeptide of the Euglena LHCP complexes and cross-reacts only very weakly with components in SDS-treated cells of Chlamydomonas reinhardtii Dangeard and chloroplasts of Spinacia oleracea L. cv Winter Bloomsdale. Rates of photosynthesis of the wild-type and mutant cells of Euglena are approximately equal on a cell basis when measured at light saturation, consistent with the selective loss of major antenna components but not CP I or CPa from the mutants.     

Chlorophyll-Protein Complexes from Euglena gracilis and Mutants Deficient in Chlorophyll b: I. Pigment Composition

The use of n-octyl-beta-d-glucopyranoside along with sodium dodecyl sulfate improves the retention of chlorophyll (Chl) by chlorophyll-protein complexes (CPs) prepared from thylakoids of Euglena gracilis Klebs var bacillaris Cori and yields several additional complexes. Thylakoids from wild-type (WT) cells, solubilized in these detergents and subjected to polyacrylamide gel electrophoresis at 0 degrees C, yield the following CPs, in order of relative molecular weight, containing the pigments shown in parentheses with their respective molar ratios where determined: CP Ia (Chl a, diadinoxanthin and beta-carotene; 100:12:5); CP I (Chl a and beta-carotene; 100:6-12); CPx (Chl and carotenoids); LHCP(2) (light-harvesting CP oligomer) (Chl a, Chl b, diadinoxanthin and neoxanthin; 12:4:3:1); CPy (Chl a, diadinoxanthin and beta-carotene; 100:14:8); CPa (Chl a and beta-carotene; 100:18-25) and LHCP (monomer) (Chl a, Chl b, diadinoxanthin and neoxanthin; 12:6:4:1). The LHCP complexes retain up to 40% of the total Chl and 80% of the Chl b in the thylakoids. CP Ia contains only a trace of Chl b (Chl a/b [mol/mol] = 62). The lower amount of Chl b in Euglena (about 10% of Chl a + b) compared to higher plants (about 30% of Chl a + b) is probably a consequence of the lower Chl b (relative to Chl a) in the LHCPs of Euglena rather than of fewer LHCPs being present. G(1)BU, Gr(1)BSL, and O(4)BSL, mutants of bacillaris low in Chl b (1-2% of Chl a + b), lack the CP Ia, LHCP, and LHCP(2) found in wildtype (WT); G(1) and O(4) also lack CPy. The mutants contain reduced amounts of Chl a (two-thirds of WT in Gr(1) and one-third in G(1) and O(4)) and neoxanthin (20-40% of WT) but retain levels of beta-carotene and diadinoxanthin close to those in cells of WT. The CPs remaining in the mutants have pigment compositions very similar to their counterparts from WT.     

Seasonal variation in ribulose bisphosphate carboxylase activity in Pinus silvestris

Ribulose bisphosphate carboxylase activity was examined in Pinus silvestris L. during successive seasons. The enzyme activities were studied both in seedlings, kept under controlled conditions in a climate chamber, and in needles from a 15-year-old tree in a natural stand. The enzyme activities were analysed in cell-free extracts prepared with Tween 80 as protective agent. The carboxylase activity fluctuated periodically both in the seedlings and in the natural stand. In the seedlings, the weight-related activity in the older needles increased 50–100% (in the cotyledons c. 200%) in the beginning of the “summer”. It decreased as the new shoot developed. The specific activity increased c. 100%. With chlorophyll as base, the activity usually decreased during “summer”. In the developing current needles the carboxylase activity increased when expressed on a weight or on a protein basis. The decrease in weight-related carboxylase activity in the older needles was preceded by, or simultaneous with, loss of total protein. It is suggested that protein, including the carboxylase, is utilized as nitrogen reserve for the new shoot. During hardening by combined photoperiod and thermoperiod, the carboxylase activity decreased when expressed relative to dry weight and protein. Calculated on a chlorophyll basis, the activity was rather constant. In the natural stand the activity in the one- and two-year-old needles increased during spring and summer and decreased during autumn and winter. Even at severe winter stress substantial carboxylase activity remained in the needles. The activity of the enzyme in vivo is discussed with respect to electron transport and net photosynthesis.     

Distribution of Chlorophyll-Protein Complexes during Chilling in the Light Compared with Heat-Induced Modifications

The effects of chilling in the light (4 days at 5°C and 100-200 micromoles of photons per square meter per second) on the distribution of chlorophyll (Chl) protein complexes between appressed and nonappressed thylakoid regions of pumpkin (Cucurbita pepo L.) chloroplasts were studied and compared with the changes occurring during in vitro heat treatment (5 minutes at 40°C) of isolated thylakoids. Both treatments induced an increase (18 and 65%, respectively) in the relative amount of the antenna Chl a protein complexes (CP47 + CP43) of photosystem II (PSII) in stroma lamellae vesicles. Freeze-fracture replicas of light-chilled material revealed an increase in the particle density on the exoplasmic fracture face of unstacked membrane regions. These two treatments differed markedly, however, in respect to comigration of the light-harvesting Chl a/b protein complex (LHCII) of PSII. The LHCII/PSII ratio in stroma lamellae vesicles remained fairly constant during chilling in the light, whereas it dropped during the heat treatment. Moreover, it was a minor light-harvesting Chl a/b protein complex of PSII, CP29, that increased most in stroma lamellae vesicles during light-chilling. Changes in the organization of LHCII during chilling were suggested by a shift to particles of smaller sizes on the protoplasmic fracture face of stacked membrane regions and a decrease in the amount of trans-Δ³-hexadecenoic acid in the phosphatidyldiacylglycerol fraction.