The major light-harvesting complex (LHCII) of photosystem II, the most abundant chlorophyll-containing complex in higher plants, is organized in trimers. In this paper we show that the trimerization of LHCII occurs spontaneously and is dependent on the presence of lipids. LHCII monomers were reconstituted from the purified apoprotein (LHCP), overexpressed in Escherichia coli, and pigments, purified from chloroplast membranes. These synthetic LHCII monomers trimerize in vitro in the presence of a lipid fraction isolated from pea thylakoids. The reconstituted LHCII trimers are very similar to native LHCII trimers in that they are stable in the presence of mild detergents and can be isolated by partially denaturing gel electrophoresis or by centrifugation in sucrose density gradients. Moreover, both native and reconstituted LHCII trimers exhibit signals in circular dichroism in the visible range that are not seen in native or reconstituted LHCII monomers, indicating that trimer formation either establishes additional pigment-pigment interactions or alters pre-existing interactions. Reconstituted LHCII trimers readily form two-dimensional crystals that appear to be identical to crystals of the native complex.
The major light-harvesting complex (LHCII) of photosystem I1 can be reconstituted in its native, trimeric form starting from its apoprotein light-harvesting chlorophyll alb-binding protein (LHCP), pigments, and thylakoid lipids. In this paper we identify segments in the LHCP polypeptide that are essential for the formation of stable LHCII trimers by analyzing N-and C-terminal deletion mutants of LHCP and mutants carrying point-specific amino acid exchanges. C-Terminal deletions that do not abolish pigment binding to LHCP do not affect trimerization either. By contrast, on the N-terminus of LHCP, where as many as 61 amino acids can be deleted without significant effects on pigment binding, only 15 amino acids are dispensible for LHCII trimer formation . This indicates that structural elements between amino acids 16 and 61 are involved in the stabilization of LHCII trimers but not monomers. Closer inspection of this protein domain in a more detailed mutation analysis revealed that amino acids W16 and/or Y17 as well as R21 are essential for the formation of LHCII trimers. These amino acids are conserved in virtually all known sequences of LHCII apoproteins but only in some of the minor chlorophyll alb complexes. Possible functions of the crucial residues are discussed.In the photosynthetic apparatus in higher plants, both photosystem I and photosystem I1 (PSI and PSII, respectively)' contain a number of peripheral, chlorophyll aib-
Light-harvesting chlorophyll-alb-binding protein (LHCP), overexpressed in Escherichia coli, can be reconstituted with pigments to yield complexes that are structurally very similar to light-harvesting complex I1 (LHCII) isolated from thylakoids [Paulsen, H., Riimler, U. & Rudiger, W. (1990) Planta 181, . In order to analyze which domains of the protein are involved in pigment binding, we reconstituted deletion mutants of LHCP with pigments and characterized the resulting complexes regarding their pigment composition and spectroscopic properties. Series of progressive deletions from either end of the protein revealed that most of the N-terminal and part of the C-terminal hydrophilic regions of LHCP are dispensible for pigment binding. In either deIetion series, the deletions that completely abolished reconstitution could be narrowed down to segments of five amino acids that do not contain histidine, asparagine, or glutamine. All mutants either formed complexes with both pigment composition and spectroscopic properties very similar to those of light-harvesting complex I1 isolated from thylakoids, or they did not form any stable complexes at all. There is no indication of a segment of LHCP binding a subset of LHCII pigments. We conclude that the stabilization of LHCP-pigment complexes is highly synergetic rather than based on individual pigment-binding sites provided by the protein.In all photosynthesizing organisms, the efficiency of photosynthesis is greatly enhanced by the presence of lightharvesting or antenna complexes. These contain a number of pigments absorbing light over an extended range of wavelengths and funnel the light energy into the photosynthetic reaction centers. This function requires rapid energy transfer between the antenna pigments to occur, which in turn is dependent on a specific orientation of pigment molecules relative to one another. We wish to understand how this specific arrangement of pigments in antenna complexes is achieved and what role the apoproteins of the antenna complexes play in this concern.In higher plants and green algae, the most prominent antenna complexes are the major light-harvesting complexes associated with photosystem 11 (LHCII). Its apoproteins (LHCP), a family of closely related proteins with molecular mass typically between 24 -29 kDa, represent about one third of the total protein content of the thylakoid membrane and bind roughly 50% of the total chlorophyll present in the plant.
The major light-harvesting complex of photosystem II can be reconstituted in vitro from its bacterially expressed apoprotein with chlorophylls a and b and neoxanthin, violaxanthin, lutein, or zeaxanthin as the only xanthophyll. Reconstitution of these one-carotenoid complexes requires low-stringency conditions during complex formation and isolation. Neoxanthin complexes (containing 30±50% of the all-trans isomer) disintegrate during electrophoresis, exhibit a largely reduced resistance against proteolytic attack; in addition, energy transfer from Chl b to Chl a is easily disrupted at elevated temperature. Complexes reconstituted in the presence of either zeaxanthin or lutein contain nearly two xanthophylls per 12 chlorophylls and are more resistant against trypsin. Lutein±LHCIIb also exhibits an intermediate maintenance of energy transfer at higher temperature. Violaxanthin complexes approach a xanthophyll/12 chlorophyll ratio of 3, similar to the ratio in recombinant LHCIIb containing all xanthophylls. On the other hand, violaxanthin±LHCIIb exhibits a low thermal stability like neoxanthin complexes, but an intermediate accessibility towards trypsin, similar to lutein±LHCIIb and zeaxanthin±LHCIIb. Binary competition experiments were performed with two xanthophylls at varying ratios in the reconstitution. Analysis of the xanthophyll contents in the reconstitution products yielded information about relative carotenoid affinities of three assumed binding sites. In lutein/neoxanthin competition experiments, two binding sites showed a strong preference (. 200-fold) for lutein, whereas the third binding site had a higher affinity (25-fold) to neoxanthin. Competition between lutein and violaxanthin gave a similar result, although the specificities were lower: two binding sites have a 36-fold preference for lutein and one has a fivefold preference for violaxanthin. The lowest selectivity was between lutein and zeaxanthin: two binding sites had a fivefold higher affinity for lutein and one has a threefold higher affinity to zeaxanthin.
In higher plants, the de-epoxidation of violaxanthin (Vx) to antheraxanthin and zeaxanthin is required for the pH-dependent dissipation of excess light energy as heat and by that process plays an important role in the protection against photo-oxidative damage. The de-epoxidation reaction was investigated in an in vitro system using reconstituted light-harvesting complex II (LHCII) and a thylakoid raw extract enriched in the enzyme Vx de-epoxidase. Reconstitution of LHCII with varying carotenoids was performed to replace lutein and/or neoxanthin, which are bound to the native complex, by Vx. Recombinant LHCII containing either 2 lutein and 1 Vx or 1.6 Vx and 1.1 neoxanthin or 2.8 Vx per monomer were studied. Vx de-epoxidation was inducible for all complexes after the addition of Vx de-epoxidase but to different extents and with different kinetics in each complex. Analysis of the kinetics indicated that the three possible Vx binding sites have at least two, and perhaps three, specific rate constants for de-epoxidation. In particular, Vx bound to one of the two lutein binding sites of the native complex, most likely L1, was not at all or only at a slow rate convertible to Zx. In reisolated LHCII, newly formed Zx almost stoichiometrically replaced the transformed Vx, indicating that LHCII and Vx de-epoxidase stayed in close contact during the de-epoxidation reactions and that no release of carotenoids occurred.
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