Chlorophyll and peptide compositions in the two photosystems of marine green algae

The molar ratios of chlorophyll a to b in the thalli of marine green algae were between 1.5 and 2.2, being appreciably lower than the ratio between 2.8 and 3.4 found for the leaves of higher plants and the cells of fresh-water green algae. The ratio of chlorophylls to P-700 in these marine algae was also lower than that in higher plants. The $\text{a}\text{b}$ ratios in the pigment proteins of Photosystems 1 and 2 separated by polyacrylamide-gel electrophoresis from sodium dodecyl sulfate-solubilized chloroplasts of four species of marine green algae, Bryopsis maxima, Cheatomorpha spiralis, Enteromorpha compress and Ulva conglobata, were approximately 5 and 1, which are considerably smaller than the ratios, 7 and 2, respectively, found for the pigment proteins of the two photosystems of higher plants separated by the same technique. The chloroplasts of Bryopsis maxima and Cheatomorpha spiralis lacked two of the peptides associated with Photosystem II, which are present in the chloroplasts of Spinacia oleracea and Taraxacum officinale.     

The stoichiometry and antenna size of the two photosystems in marine green algae, Bryopsis maxima and Ulva pertusa, in relation to the light environment of their natural habitat

The stoichiometry and antenna sizes of the two photosystems in two marine green algae, Bryopsis maxima and Ulva pertusa, were investigated to examine whether the photosynthetic apparatus of the algae can be related to the light environment of their natural habitat. Bryopsis maxima and Ulva pertusa had chlorophyll (Chl) a/b ratios of 1.5 and 1.8, respectively, indicating large levels of Chl b, which absorbs blue-green light, relative to Chl a. The level of photosystem (PS) II was equivalent to that of PS I in Bryopsis maxima but lower than that of PS I in Ulva pertusa. Analysis of Q(A) photoreduction and P-700 photo-oxidation with green light revealed that >50% of PS II centres are non-functional in electron transport. Thus, the ratio of the functional PS II to PS I is only 0.46 in Bryopsis maxima and 0.35 in Ulva pertusa. Light-response curves of electron transport also provided evidence that PS I had a larger light-harvesting capacity than did the functional PS II. Thus, there was a large imbalance in the light absorption between the two photosystems, with PS I showing a larger total light-harvesting capacity than PS II. Furthermore, as judged from the measurements of low temperature fluorescence spectra, the light energy absorbed by Chl b was efficiently transferred to PS I in both algae. Based on the above results, it is hypothesized that marine green algae require a higher ATP:NADPH ratio than do terrestrial plants to grow and survive under a coastal environment.     

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.     

Characterization of Chlorophyll–protein Complexes Isolated from Two Marine Green Algae, Bryopsis maxima and Ulva pertusa, Growing in the Intertidal Zone

Three Chl–protein complexes were isolated from thylakoid membranes of Bryopsis maxima and Ulva pertusa, marine green algae that inhabit the intertidal zone of the Pacific Ocean off the eastern coast of Japan by dodecyl-β-d-maltoside polyacrylamide gel electrophoresis. The slowest-moving fractions showed low Chl a/b and Chl/P-700 ratios, indicating that this fraction corresponds to complexes in PS I, which is large in both algae. The intermediate and fastest-moving fractions showed the traits of PS II complexes, with some associated Chl a/b–protein complexes and LHC II, respectively. The spectral properties of the separated Chl–proteins were also determined. The absorption spectra showed a shallow shoulder at 540 nm derived from siphonaxanthin in Bryopsis maxima, but not in Ulva pertusa. The 77 K emission spectra showed a single peak in Bryopsis maxima and two peaks in Ulva pertusa. Besides the excitation spectra indicated that the excitation energy transfer to the PS I complexes differed quite a lot higher plants. This suggested that the mechanisms of energy transfer in both of these algae differ from those of higher plants. Considering the light environment of this coastal area, the large size of the antennae of PS I complexes implies that the antennae are arranged so as to balance light absorption between the two photosystems. In addition, we discuss the relationships among the photosystem stoichiometry, the energy transfer, and the distribution between the two photosystems.     

Photosynthesis in trees: organization of chlorophyll and photosynthetic unit size in isolated gymnosperm chloroplasts

Chloroplasts have been isolated in high yield from several gymnosperms and from two deciduous trees. The organization of chlorophyll in the chloroplasts of these woody species is basically similar to that in angiosperm crop plants and green algae. The tree chloroplasts contain two chlorophyll proteins, the P700-chlorophyll a-protein and the major light-harvesting chlorophyll a/b-protein, the size, spectral characteristics, and function of which are the same as the equivalent complexes previously isolated from other classes of green plants. All the gymnosperms have chlorophyll/P700 ratios (photosynthetic unit sizes) 1.6 to 3.8 times larger than that typically found in crop plants; the deciduous trees have units of intermediary size. The presence of fewer but larger photosynthetic units in the woody species can partially account for their lower photosynthetic rate and explains why their photosynthetic processes saturate at lower light intensities. Chloroplasts of shade needles have large units containing a greater proportion of the light-harvesting chlorophyll a/b-protein than those of sun needles.     

管藻目绿藻叶绿素蛋白复合物特性及比较研究

By mild PAGE method, 11, 11, 7 and 9 chlorophyll-protein complexes were isolated from two species of siphonous green algae (Codium fragile (Sur.) Hariot and Bryopsis corticulans Setch.), green alga (Ulothrix flacca (Dillw.) Thur.), and spinach (Spinacia oleracea Mill.), respectively. Apparent molecular weights, Chl a/b ratios, distribution of chlorophyll, absorption spectra, low temperature fluorescence spectra of these complexes were determined, and compared with one another. PSⅠ complexes of two siphonous green algae are larger in apparent molecular weight because of the attachment of relative highly aggregated LHCⅠ. Four isolated light-harvesting complexes of PSⅡ are all siphonaxanthin-Chl a/b-protein complexes, and they are not monomers and oligomers like those in higher plants. Especially, the absence of 730 nm fluorescence in PSⅠ complexes indicates a distinct structure and energy transfer pattern.     

CHLOROPLAST STRUCTURE AND PIGMENT COMPOSITION IN THE RED ALGA GRIFFITHSIA PACIFICA: REGULATION BY LIGHT INTENSITY1

The ratio of accessory phycobiliproteins to chlorophyll a is controlled by light intensity in the marine red alga Griffithsia pacifica. The greatest changes in pigment ratios are observed below 300 ft-c; above 300 ft-c the response approaches saturation. Ultrastructural examination of chloroplasts of plants grown at different intensities reveals that the number of phycobilisomes per unit of photosynthetic thylakoid changes in direct proportion to the pigment ratios and in inverse proportion to the light intensity.     

Evolution of o(2) in brown algal chloroplasts

A method is described for the isolation of photosynthetically active chloroplasts from four species of brown algae: Fucus vesiculosis, Nereocystis luetkeana, Laminaria saccharina, and Macrocystis integrifolia. When compared to lettuce and spinach chloroplasts, the algal chloroplasts all showed lower activities for both photosystems II and I. Chloroplasts from all the plants produced H₂O₂, with photosystem I functioning as the O₂ reductant in the light. In contrast to the green plants, however, brown algal chloroplasts strongly reduced O₂ under conditions where both photosystems II and I remain active. Relative variable fluorescence values were lower both in intact plants and chloroplasts of the brown algae than for either spinach or lettuce. It is suggested that although light harvesting activities appear similar in all the plants, details of electron transport in brown algae may differ from those of green plants.     

A Comparison of Pigment-Protein Complexes among Normal, Chlorophyll-Deficient and Senescent Soybean Genotypes

Pigment-protein complexes were isolated from chloroplasts of normal green and several types of chlorophyll-deficient soybeans. The complexes were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and comparisons were made between normal and chlorophyll-deficient genotypes of the relative amounts of chlorophyll associated with Photosystem I (PSI), Photosystem II (PSII), light-harvesting, and free pigment complexes.

Chlorophyll-deficient genotypes, compared to normal green genotypes, have fewer light-harvesting complexes and a higher ratio of PSII to PSI complexes. Chlorophyll associated with PSII in yellow genotypes is in relatively higher amounts in spite of the fact that these genotypes have much less grana stacking than normal green genotypes. Although PSII activity has been associated with appressed regions of grana in normal plants, our work shows that the association does not always hold true.

     

Formation and Growth of Bryopsis hypnoides Lamouroux Regenerated from Its Protoplasts

Tissue culture, SDS-polyacrylamide gel electrophoresis (SDS-PAGE) and spectra analysis were used for studying the aggregation mechanism of protoplasts from Bryopsis hypnoides Lamouroux and the discrepancy between the protoplast-regenerated plants and the wild type. The aggregation of protoplasts from B. hypnoides was observed in natural seawater and artificial seawater with different pH values, and the location and mechanism of the materials causing the aggregation were also studied. Results showed that the protoplasts could aggregate into some viable spheres in natural seawater and subsequently grow into mature individuals. Aggregation of the protoplasts depended exclusively upon the pH value (6-11), and the protoplasts aggregated best at pH 8-9. Some of the extruded protoplasts were separated into two parts by centrifugation: the pellet (PO) and the supernatant (PL). The PO could aggregate in artificial seawater (pH8.3) but not in PL. No aggregation was found in PO cultured in natural seawater containing nigericin, which can dissipate the proton gradients across the membrane. These experiments suggest that the aggregation of protoplasts is proton-gradient dependent and the materials causing the aggregation were not in the vacuolar sap, but located on the surface or inside the organelles. Furthermore, the transfer of the materials across the membrane was similar to △pH-based translocafion (△pH/TAT) pathway that occurs in the chloroplasts of higher plants and bacteria. Obvious discrepancies in both the total soluble proteins and the ratio of chlorophyll a to chlorophyll b between the regenerated B. hypnoides and the wild type were found, which may be related to the exchange of genetic material during aggregation of the organelles. In the process of development, diatom Amphora coffeaeformis Agardh attached to the protoplast aggregations, retarding their further development, and once they were removed, the aggregations immediately germinated, which showed that diatoms can affect the development of other algae.     

Formation and Growth of Bryopsis hypnoides Lamouroux Regenerated from Its Protoplasts

Tissue culture, SDS-polyacrylamide gel electrophoresis (SDS-PAGE) and spectra analysis were used for studying the aggregation mechanism of protoplasts from Bryopsis hypnoides Lamouroux and the discrepancy between the protoplast-regenerated plants and the wild type. The aggregation of protoplasts from B. hypnoides was observed in natural seawater and artificial seawater with different pH values, and the location and mechanism of the materials causing the aggregation were also studied. Results showed that the protoplasts could aggregate into some viable spheres in natural seawater and subsequently grow into mature individuals. Aggregation of the protoplasts depended exclusively upon the pH value (6-11), and the protoplasts aggregated best at pH 8-9. Some of the extruded protoplasts were separated into two parts by centrifugation: the pellet (PO) and the supernatant (PL). The PO could aggregate in artificial seawater (pH 8.3) but not in PL. No aggregation was found in PO cultured in natural seawater containing nigericin, which can dissipate the proton gradients across the membrane. These experiments suggest that the aggregation of protoplasts is proton-gradient dependent and the materials causing the aggregation were not in the vacuolar sap, but located on the surface or inside the organelles. Furthermore, the transfer of the materials across the membrane was similar to △pH-based translocation (△pH/TAT) pathway that occurs in the chloroplasts of higher plants and bacteria. Obvious discrepancies in both the total soluble proteins and the ratio of chlorophyll a to chlorophyll b between the regenerated B. hypnoides and the wild type were found, which may be related to the exchange of genetic material during aggregation of the organelles. In the process of development, diatom Amphora coffeaeformis Agardh attached to the protoplast aggregations, retarding their further development, and once they were removed, the aggregations immediately germinated, which showed that diatoms can affect the development of other algae.     

Composition of the photosystems and chloroplast structure in extreme shade plants

Chloroplasts were isolated from leaves of three species of tropical rainforest plants, Alocasia macrorrhiza, Cordyline rubra and Lomandra longifolia; these species are representative of extreme “shade” plants. It was found that shade plant chloroplasts contained 4–5 times more chlorophyll than spinach chloroplasts. Their chlorophyll a/chlorophyll b ratio was 2.3 compared with 2.8 for spinach. Electron micrographs of leaf sections showed that the shade plant chloroplasts contained very large grana stacks. The total length of partitions relative to the total length of stroma lamellae was much higher in Alocasia than in spinach chloroplasts. Freeze-etching of isolated chloroplasts revealed both the small and large particles found in spinach chloroplasts.

Despite their increased chlorophyll content, low chlorophyll a/chlorophyll b ratio, and large grana, the shade plant chloroplasts were fragmented with digitonin to yield small fragments (D-144) highly enriched in Photosystem I, and large fragments (D-10) enriched in Photosystem II. The degree of fragmentation of the shade plant chloroplasts was remarkably similar to that of spinach chloroplasts, except that the subchloroplast fragments from the shade plants had lower chlorophyll a/chlorophyll b ratios than the corresponding fragments from spinach. The D-10 fragments from the shade plants had chlorophyll a/chlorophyll b ratios of 1.78-2.00 and the D-144 fragments ratios of 3.54–4.07. We conclude that Photosystems I and II of the shade plants have lower proportions of chlorophyll a to chlorophyll b than the corresponding photosystems of spinach. The lower chlorophyll a/chlorophyll b ratio of shade plant chloroplasts is not due to a significant increase in the ratio of Photosystem II to Photosystem I in these chloroplasts.

The extent of grana formation in higher plant chloroplasts appears to be related to the total chlorophyll content of the chloroplast. Grana formation may simply be an means of achieving a higher density of light-harvesting assemblies and hence a more efficient collection of light quanta.     

Spectral and kinetic parameters of phosphorescence of triplet chlorophyll a in the photosynthetic apparatus of plants

Spectral and kinetic parameters and quantum yield of IR phosphorescence accompanying radiative deactivation of the chlorophyll a (Chl a) triplet state were compared in pigment solutions, greening and mature plant leaves, isolated chloroplasts, and thalluses of macrophytic marine algae. On the early stages of greening just after the Shibata shift, phosphorescence is determined by the bulk Chl a molecules. According to phosphorescence measurement, the quantum yield of triplet state formation is not less than 25%. Further greening leads to a strong decrease in the phosphorescence yield. In mature leaves developing under normal irradiation conditions, the phosphorescence yield declined 1000-fold. This parameter is stable in leaves of different plant species. Three spectral forms of phosphorescence-emitting chlorophyll were revealed in the mature photosynthetic apparatus with the main emission maxima at 955, 975, and 995 nm and lifetimes ～1.9, ～1.5, and 1.1–1.3 ms. In the excitation spectra of chlorophyll phosphorescence measured in thalluses of macrophytic green and red algae, the absorption bands of Chl a and accessory pigments — carotenoids, Chl b, and phycobilins — were observed. These data suggest that phosphorescence is emitted by triplet chlorophyll molecules that are not quenched by carotenoids and correspond to short wavelength forms of Chl a coupled to the normal light harvesting pigment complex. The concentration of the phosphorescence-emitting chlorophyll molecules in chloroplasts and the contribution of these molecules to chlorophyll fluorescence were estimated. Spectral and kinetic parameters of the phosphorescence corresponding to the long wavelength fluorescence band at 737 nm were evaluated. The data indicate that phosphorescence provides unique information on the photophysics of pigment molecules, molecular organization of the photosynthetic apparatus, and mechanisms and efficiency of photodynamic stress in plants.     

Reassembly of living cells from dissociated components in Bryopsis

Protoplasm from Bryopsis maxima, a coenocytic green alga, wasdissociated into two fractions: chloroplasts, and protoplasmicfraction without chloroplasts (PF). The protoplasmic fraction(PF) included nuclei, mitochondria, dictyosomes, endoplasmicreticuli, etc. These two fractions were reassembled and formedprotoplasts, which developed into mature plants. (Received June 9, 1977; )     

Exploring the low photosynthetic efficiency of cyanobacteria in blue light using a mutant lacking phycobilisomes

Photosynthesis Research - The ubiquitous chlorophyll a (Chl a) pigment absorbs both blue and red light. Yet, in contrast to green algae and higher plants, most cyanobacteria have much lower...     

Chloroplasts as functional organelles in animal tissues

The marine gastropod molluscs Tridachia crispata, Tridachiella diomedea, and Placobranchus ianthobapsus (Sacoglossa, Opisthobranchia) possess free functional chloroplasts within the cells of the digestive diverticula, as determined by observations on ultrastructure, pigment analyses, and experiments on photosynthetic capacity. In the light, the chloroplasts incorporate H¹⁴CO₃^- in situ. Reduced radiocarbon is translocated to various chloroplast-free tissues in the animals. The slugs feed on siphonaceous algae from which the chloroplasts are derived. Pigments from the slugs and from known siphonaceous algae, when separated chromatographically and compared, showed similar components. Absorption spectra of extracts of slugs and algae were very similar. The larvae of the slugs are pigment-free up to the post-veliger stage, suggesting that chloroplasts are acquired de novo. with each new generation.     

Characterization of genes encoding the light-harvesting proteins in diatoms: biogenesis of the fucoxanthin chlorophylla/c protein complex

In chromophytic algae the major light-harvesting complex is the fucoxanthin chlorophylla/c protein complex. Recently, we have cloned several highly related cDNA and genomic sequences encoding the fucoxanthin chlorophylla/c proteins from the diatomPhaeodactylum tricornutum. These genes are clustered on the nuclear genome. The sequences of the fucoxanthin chlorophylla/c proteins as deduced from the gene sequences have some similarity to the chlorophylla/b proteins associated with light-harvesting complexes of higher plants and green algae. Like the chlorophylla/b proteins of higher plants, the fucoxanthin chlorophylla/c proteins are synthesized as higher-molecular weight precursors in the cytoplasm of the cell and are transported into the plastids. However, the mode of transport into diatom plastids is very different from the mechanism involved in transporting proteins into the chloroplasts of higher plants and green algae. We focus here on the characteristics of the fucoxanthin chlorophylla/c proteins, the mode of transport of these proteins into plastids, the arrangement of the genes encoding these proteins, and efforts to utilize these genes to develop a DNA transformation system for diatoms.     

Characterization of three forms of light-harvesting chlorophyll a/b-protein complexes of photosystem II isolated from the green alga, Dunaliella salina

Three forms of light-harvesting chlorophyll a/b-protein complexes of photosystem II (LHC II) were isolated from the thylakoid membranes of Dunaliella salina grown under different irradiance conditions. Cells grown under a low intensity light condition (80 micromol quanta m(-2) s(-1)) contained one form of LHC II, LHC-L. Two other forms of LHC II, LHC-H1 and LHC-H2, were separated from the cells grown under a high intensity light condition (1,500 micromol quanta m(-2) s(-1)). LHC-L and LHC-H1 showed an apparent particle size of 310 kDa and contained four polypeptides of 31, 30, 29 and 28 kDa. LHC-H2, with a particle size of 110 kDa, consisted of 30 and 28 kDa polypeptides. LHC-L contained 7.5 molecules of Chl a, 3.2 of Chl b and 2.1 of lutein per polypeptide, analogous to the content in higher plants. LHC-H1, with 5.6 molecules of Chl a, 2.5 of Chl b and 1.8 of lutein per polypeptide was similar to that in the green alga Bryopsis maxima. LHC-L and LHC-H1 maintained high efficiency energy transfer from Chl b and lutein to Chl a molecules. LHC-H2 showed a high Chl a/b ratio of 7.5 and contained 3.4 molecules of Chl a, 0.5 of Chl b and 1.4 of lutein per polypeptide. Chl b and lutein could not completely transfer the excitation energy to Chl a in LHC-H2.     

Reduction of 2,6-dichlorophenol-indophenol (Hill Reaction) by Chloroplasts with Different Chlorophyll a/b Ratios Under monochromatic Light

Chloroplasts with different chlorophyll a/b ratios were isolated from 7 to 8 days old wheat seedlings and the activities of reduction of 2,6-dichlorophenol-indophenol (DPIP) by these chloroplasts as function of the chlorophyll a/b ratios were studied under mono-chromatic light (650 m μ, 670 mμ, 680 mμ, 707 mμ). It was found that the DPIP reducing activities by these chloroplasts varied with their chlorophyll a/b ratios, and these variations are affected by the wavelengths of the illuminating light. Under 650 mμ, at the a/b ratios of 2.2 to 2.82, the activities of DPIP reduction in- creased with the a/b ratios, but decreased when the a/b ratios were higher than 2.82. Under 670 mμ, the DPIP reducing activities also varied with the a/b ratios of isolated chloroplasts. However, the variation was more gradual and steadier. Under 680 mμ, the DPIP reducing activities increased with the a/b ratios over 3.0, but decreased rather suddenly at a/b ratio of 3.30. Essentially the same relation held for 707 mμ, but the Hill reaction activities ceased to decline farther when a/b ratio rose to 3.40 at 707 mμ. When the results were analyzed in terms of the “relative activities” of the chloroplasts of the above mentioned wave lengths, it was found that the values of the "relative activity" (a/a+b) declined steadily from 1.47–1.29 at an a/b ratio range of 2.05–3.40, while the values of the "relative activity" (b/a+b)increased steadily from 3.10--4.40 at the same range of a/b ratios. But it is to be noted that, under 650 mμ, the (a/a+b) was 1.36 at the a/b ratio range of 2.63–2.82. Interesting enough, the DPIP reducing activities were the highest of all with these a/b ratios. Activities of DPIP reduction by isolated chloroplasts kept at 0 ℃, 20 ℃, 30 ℃, and 45 ℃ diminished with time when illuminated at all wavelengths. However, for those kept at 45 ℃ their activities were lost after 20 minutes, except those illuminated with the wave length of 680 mμ which still maintained 30 % of the initial activity. When kept at the above mentioned temperatures, the chlorophyll a/b ratios of all batches of chloroplasts declined steadily with time. The above results are interpreted as being indicative of the possibility that the pigment systems for the partial reaction (Hill reaction) of the over-all photosynthesis process consisted mainly of Chlb650 and Chla670. And the correlation of temperature and abolition of activity reduction of DPIP of chloroplasts varied under monochromatic light of different wave lengths.