Orientation of plgments in the thylakoid membrane and in the isolated chlorophyll-protein complexes of higher plants. IV. The 100 K linear dichroism spectra of thylakoids from wild-type and chlorophyll b-less barley thylakoids

Using a polyacrylamide gel squeezing technique, linear dichroism spectra of thylakoids from wild-type and chlorophyll-b less barley have been obtained at 100 K. The calculated difference linear dichroism spectra, based on normalization at 690–695 nm, are identical to those of the light-harvesting complex (LHC) isolated by Triton solubilization. This observation is in agreement with previous conclusions (Tapie, P., Haworth, P., Hervo, G. and Breton, J. (1982) Biochim. Biophys. Acta 682, 339–344) regarding: (i) scattering artifacts are absent in linear dichroism spectra determined using polyacrylamide gels, (ii) the in vivo orientation of LHC pigments is maintained in the isolated complex and (iii) the largest dimension(s) of the isolated LHC is (are), in vivo, parallel to the plane of the photosynthetic membrane.     

Orientation of the pigments in the thylakoid membrane and in the isolated chlorophyll-protein complexes of higher plants. III. A quantitative comparison of the low-temperature linear dichroism spectra of thylakoids and isolated pigment-protein complexes

The low-temperature linear dichroism spectrum of thylakoids oriented in polyacrylamide gel can be adequately described by a linear combination of the corresponding spectra of particles of light-harvesting complex, Photosystem I and Photosystem II, isolated by Triton X-100 extraction. The main conclusions which can be derived from this observation are: (1) The in vivo orientation of the pigments within each of the three complexes is not significantly affected by the extraction and purification procedures. (2) The various photosynthetic pigments are oriented roughly to the same extent in each of the three main biochemical constituents of the thylakoid. (3) All the complexes investigated behave like ellipsoids, the largest dimensions of which are lying in the plane of the photosynthetic membrane.     

Quantitative method for studying orientation of transition dipoles in membrane vesicles of spherical symmetry

Pigmented vesicular membranes embedded in polyacrylamide gel exhibit linear dichroism when the gel sample is squeezed [Abdourakhmanov, I.A., Ganago, A.O., Erokhin, Yu.E., Solov'ev, A.A. and Chugunov, V.A. (1979) Biochim. Biophys. Acta 546, 183-186]. The orientation technique of gel-squeezing was modified to enhance polarization effects in membrane vesicles of spherical symmetry. Model calculations were carried out to provide a tool for the quantitative evaluation of the dichroism of squeezed gel samples. The orientation angles of the dipoles can be calculated with reasonable precision by measuring two quantities: (i) the macroscopic deformation parameter of the gel sample, and (ii) a parameter (e.g. the polarization ratio of the fluorescence emission) characterizing the orientation of the transition dipoles in the membranes embedded in the squeezed gel. The validity of the model was confirmed through a series of polarization measurements relating to the fluorescence of chlorophyll a in membranes of osmotically shocked chloroplasts, 'blebs'.     

Orientation of pigments in the thylakoid membrane and in the isolated chlorophyll-protein complexes of higher plants. II. Linear dichroism spectra of isolated pigment-protein complexes oriented in polyacrylamide gels at 300 and 100 K

The absorption and linear dichroism (LD) spectra (380–780 nm) of isolated light-harvesting complex (LHC), Photosystem I (PS I), Photosystem II (PS II), as well as intact thylakoids have been determined at 300 and 100 K. The samples were oriented in squeezed polyacrylamide gel. The low-temperature spectra of LHC and PS I present LD signals which are characteristic enough to be recognized in the LD spectrum of thylakoids. Tentative assignments of the various features of the LD spectra to the major photosynthetic pigments are discussed. A shoulder in the low-temperature absorption spectra is observed at about 673 nm in all the systems under investigation. The absence of an associated LD signal suggests that this ubiquitous chlorophyll (Chl) a form is non-dichroic. Furthermore, in the three isolated chlorophyll-protein complexes described in this study the sign of the LD signal indicates that both the Q_y transition of the Chl a and the carotenoid molecules are preferentially oriented parallel to the largest dimension(s) of the particles.     

Isolation and properties of a pigment-protein complex associated with the reaction center of the green photosynthetic sulfur bacterium Prosthecochloris aestuarii

The membrane-bound pigment system of green sulfur bacteria consists of light-harvesting bacteriochlorophyll a-protein and a ‘core complex’ that is associated with the reaction center (Kramer, H.J.M., Kingma, H., Swarthoff, T. and Amesz, J. (1982) Biochim. Biophys. Acta 681, 359–364). The isolation and properties of the core complex from Prosthecochloris aestuarii are described. The complex has a molecular mass of 200 ± 50 kDa and contains bacteriochlorophyll a, carotenoid and pigments absorbing near 670 nm (probably bacteriopheophytin c and an unidentified pigment). Fluorescence emission spectra and sodium dodecyl sulfate polyacrylamide gel electrophoresis showed the absence of light-harvesting bacteriochlorophyll a-protein. The preparation showed no reaction center activity. Circular and linear dichroism spectra indicated that the structure of the core complex was basically not altered by the isolation procedure. Comparison with the CD spectrum of the intrinsic membrane-bound pigment-protein complex indicates that the latter contains 14 bacteriochlorophyll a molecules (two subunits) belonging to the light-harvesting protein and about 20 bacteriochlorophyll a molecules belonging to the core complex.     

Orientation of the pigments in Photosystem II: low-temperature linear-dichroism study of a core particle and of its chlorophyll-protein subunits isolated from Synechococcus sp.

The orientation of the pigments in the Photosystem II core particle isolated from the thermophilic cyanobacterium Synechococcus sp. has been investigated by linear dichroism spectroscopy at 10 K of macroscopically oriented samples. The absorbance (A), linear dichroism (LD) and LD/A spectra are remarkably similar to those previously reported for a core complex isolated from Chlamydomonas reinhardtii (Biochim. Biophys. Acta 850 (1986) 156–161). The spectra of the Synechococcus core particle are compared to the corresponding spectra obtained on its two main constituent chlorophyll-protein complexes CP2-b (photochemically active) and CP2-c (photochemically inactive). The various features seen in the spectra of the core particle appear well segregated into the spectra of one or the other of the two subparticles without significant loss of orientation of the pigments. The orientation of the chlorophyll macrocycles, with the Y and X optical axis preferentially parallel and perpendicular to the plane of largest cross-section of the particle, respectively, is very similar in the two subparticles. CP2-b contains mainly the beta-carotene pool absorbing around 505 and 470 nm, which is oriented close to the membrane plane, while CP2-c contains the beta-carotene pool absorbing around 495 and 465 nm and oriented closer to the normal to the membrane plane. A shoulder at 682 nm in the absorbance and linear dichroism spectra of the core complex is fully segregated in the spectra of CP2-c, thus excluding the possibility that this spectral feature could be assigned to the primary donor of PS II. A negative linear dichroism component peaking around 691 nm (LD 691) in the core particle is mainly segregated in CP2-b together with the photoactive pheophytin acceptor molecule responsible for the 544 nm positive linear dichroism signal (LD 544). While the ratio of the amplitudes LD 691/LD 544 is approximately the same for the core particle and for the CP2-b complex, the amplitude of LD 691 is significantly reduced in CP2-b compared to the core particle.     

On the helix sense of gramicidin A single channels.

In order to resolve whether gramicidin A channels are formed by right- or left-handed beta-helices, we synthesized an optically reversed (or mirror image) analogue of gramicidin A, called gramicidin A-, to test whether it forms channels that have the same handedness as channels formed by gramicidin M- (F. Heitz et al., Biophys. J. 40:87-89, 1982). In gramicidin M- the four tryptophan residues have been replaced with phenylalanine, and the circular dichroism (CD) spectrum therefore reflects almost exclusively contributions from the polypeptide backbone. The CD spectrum of gramicidin M- in dimyristoylphosphatidylcholine vesicles is consistent with a left-handed helical backbone folding motif (F. Heitz et al., Biophys. Chem. 24:149-160, 1986), and the CD spectra of gramicidins A and A- are essentially mirror images of each other. Based on hybrid channel experiments, gramicidin A- and M- channels are structurally equivalent, while gramicidin A and A- channels are nonequivalent, being of opposite helix sense. Gramicidin A- channels are therefore left-handed, and natural gramicidin A channels in phospholipid bilayers are right-handed beta 6.3-helical dimers.     

Further Characterization of Protein Secondary Structures in Purple Membrane by Circular Dichroism and Polarized Infrared Spectroscopies

The conformation and the orientation of the protein secondary structures in purple membrane was analyzed by infrared absorption and linear dichroism of oriented membranes as well as by UV circular dichroism of bacteriorhodopsin in intact purple membrane and in lipid vesicles. A large amount (74 ± 5%) of transmembrane α-helices is detected with no significant contribution of β-sheet strands running perpendicular to the membrane plane. Thus, these data do not support the recent structural model proposed by Jap et al. (Biophys. J. 1983, 43:81-89).     

The rate and extent of phosphorylation of the two light-harvesting chlorophyll a/b binding protein complex (LHC-II) polypeptides in isolated spinach thylakoids

The level of phosphorylation of the 24 kDa and the 25 kDa light-harvesting chlorophyll a/b binding protein complex (LHC) II polypeptides in isolated spinach thylakoids has been determined by quantitative SDS-polyacrylamide gel electrophoresis. The time-course of phosphorylation, after correction for the molar abundance of these two polypeptides, shows that (a) the rate of phosphorylation of the 24 kDa polypeptide is at least 3-fold faster compared with the 25 kDa polypeptide, (b) the final extent of phosphorylation for both the polypeptides is very similar, and (c) the final extent of phosphorylation is typically between 0.15 and 0.25 mol phosphate per mol polypeptide. The low extent of phosphorylation is not simply a consequence of inactivation of the kinase and / or LHC II substrate or ATP depletion. These observations suggest that there are at least three different sub-populations of LHC II in isolated thylakoids: (i) phosphorylated ‘mobile’, (ii) phosphorylated ‘PS II-coupled’ and (iii) non-phosphorylated. Furthermore, the reported differences in the specific activity of phosphorylation for the ‘mobile’ and the ‘PS II-coupled’ LHC II sub-populations (Kyle, D.J. et al. (1984) Biochim. Biophys. Acta 765, 89–96) are no longer observed following correction for the non-phosphorylated LHC-II population.     

Linear dichroism of microalgae, developing thylakoids and isolated pigment-protein complexes in stretched poly(vinyl alcohol) films at 77 K

A variety of unicellular algae, thylakoids from higher plants in different stages of maturity and isolated pigment-protein complexes were oriented in stretched polyvinyl alcohol films. Low temperature linear dichroism (LD) spectra of Chlorella pyrenoidosa and higher plant thylakoids in the films were very similar to those obtained after orientation of similar samples using magnetic or electric fields. Positive LD bands corresponding to Chl a (670) and (682) and negative bands due to Chl a (658) and Chl b(648) were resolved in spectra of the light harvesting Chl a/b protein. Chl b (648) and Chl a (658) and (670) were not seen in the LD spectrum of thylakoids from plants grown in intermittent light, the Chl b-less mutant of barley, Euglena gracilis or the cyanobacteria, Phormidium luridum and Anacystis nidulans, but did appear upon chloroplast maturation in Romaine lettuce and during the greening of etiolated and intermittent light plants. The highly oriented long wavelength Chl a (682) in the light-harvesting complex may represent residual PS II whose peak dichroism is centered at 681 nm. The PS I preparation had a Chl a/b ratio of approx. 6 and the LD spectrum was positive with a maximum at 690-694 nm and a band of lower amplitude at 652 nm. The minor LD band was not observed in PS I preparations from organisms that lack chl b such as the cyanobacteria, intermittent light plants and the Chl b-less mutant of barley. We suggest that the 652 nm band is due to Chl b molecules associated with the antenna of PS I and are distinct from those on the light harvesting complex whose orientation is different. We also conclude that all the Chl a forms are oriented and that the long geometric axes of the pigment-protein complexes, as deduced from the configuration they assume in the stretched films, are axes that normally lie parallel to the plane of the native thylakoid.     

Transmembrane orientation of α-helices in the thylakoid membrane and in the light-harvesting complex. A polarized infrared spectroscopy study

The structure and orientation of the major protein constituent of photosynthetic membranes in green plants, the chlorophyll $\text{a}\text{b}$ light-harvesting complex (LHC) have been investigated by ultraviolet circular dichroism (CD) and polarized infrared spectroscopies. The isolated purified LHC has been reconstituted into phosphatidylcholine vesicles and has been compared to the pea thylakoid membrane. The native orientation of the pigments in the LHC reconstituted in vesicles was characterized by monitoring the low-temperature polarized absorption and fluorescence spectra of reconstituted membranes. Conformational analysis of thylakoid and LHC indicate that a large proportion of the thylakoid protein is in the α-helical structure (56 ± 4%), while the LHC is for 44 ± 7% α-helical. By measuring the infrared dichroism of the amide absorption bands of air-dried oriented multilayers of thylakoids and LHC reconstituted in vesicles, we have estimated the degree of orientation of the α-helical chains with respect to the membrane normal. Infrared dichroism data demonstrate that transmembrane α-helices are present in both thylakoid and LHC with the α-helix axes tilted at less than 30° in LHC and 40° in thylakoid with respect to the membrane normal. In thylakoids, an orientation of the polar C=O ester groups of the lipids parallel to the membrane plane is detected. Our results are consistent with the existence of 3–5 transmembrane α-helical segments in the LHC molecules.     

Refined structure-based simulation of plant light-harvesting complex II: Linear optical spectra of trimers and aggregates

Linear optical spectra of solubilized trimers and small lamellar aggregates of the major light-harvesting complex II (LHCII) of higher plants are simulated employing excitonic couplings and site energies of chlorophylls (Chls) computed on the basis of the two crystal structures by a combined quantum chemical/electrostatic approach. A good agreement between simulation and experiment is achieved (except for the circular dichroism in the Chl b region), if vibronic transitions of Chls are taken into account. Site energies are further optimized by refinement fits of optical spectra. The differences between refined and directly calculated values are not significant enough to decide, whether the crystal structures are closer to trimers or aggregates. Changes in the linear dichroism spectrum upon aggregation are related to site energy shifts of Chls b601, b607, a603, a610, and a613, and are interpreted in terms of conformational changes of violaxanthin and the two luteins involving their ionone rings. Chl a610 is the energy sink at 77K in both conformations. An analysis of absorption spectra of trimers perpendicular and parallel to the C(3)-axis (van Amerongen et al. Biophys. J. 67 (1994) 837-847) shows that only Chl a604 close to neoxanthin is significantly reoriented in trimers compared to the crystal structures. Whether this pigment is orientated in aggregates as in the crystal structures, can presently not be determined faithfully. To finally decide about pigment reorientations that could be of relevance for non-photochemical quenching, further polarized absorption and fluorescence measurements of aggregates or detergent-depleted LHCII would be helpful. This article is part of a Special Issue entitled: Photosynthesis Research for Sustainability: from Natural to Artificial.     

Thermo-optically Induced Reorganizations in the Main Light Harvesting Antenna of Plants. II. Indications for the Role of LHCII-only Macrodomains in Thylakoids

We have investigated the circular dichroism spectral transients associated with the light-induced reversible reorganizations in chirally organized macrodomains of pea thylakoid membranes and loosely stacked lamellar aggregates of the main chlorophyll a/b light harvesting complexes (LHCII) isolated from the same membranes. These reorganizations have earlier been assigned to originate from a thermo-optic effect. According to the thermo-optic mechanism, fast local thermal transients due to dissipation of the excess excitation energy induce elementary structural changes in the close vicinity of the dissipation [Cseh et al. (2000) Biochemistry 39: 15250–15257]. Here we show that despite the markedly different CD spectra in the dark, the transient (light-minus-dark) CD spectra associated with the structural changes induced by high light in thylakoids and LHCII are virtually indistinguishable. This, together with other close similarities between the two systems, strongly suggests that the gross short-term, thermo-optically induced structural reorganizations in the membranes occur mainly, albeit probably not exclusively, in the LHCII-only domains [Boekema et al. (2000) J Mol Biol 301: 1123–1133]. Hence, LHCII-only domains might play an important role in light adaptation and photoprotection of plants.     

Organization of the pigment molecules in the chlorophyll a/b/c containing alga Mantoniella squamata (Prasinophyceae) studied by means of absorption, circular and linear dichroism spectroscopy

In order to obtain information on the organization of the pigment molecules in chlorophyll (Chl) a/b/c-containing organisms, we have carried out circular dichroism (CD), linear dichroism (LD) and absorption spectroscopic measurements on intact cells, isolated thylakoids and purified light-harvesting complexes (LHCs) of the prasinophycean alga Mantoniella squamata. The CD spectra of the intact cells and isolated thylakoids were predominated by the excitonic bands of the Chl a/b/c LHC. However, some anomalous bands indicated the existence of chiral macrodomains, which could be correlated with the multilayered membrane system in the intact cells. In the red, the thylakoid membranes and the LHC exhibited a well-discernible CD band originating from Chl c, but otherwise the CD spectra were similar to that of non-aggregated LHC II, the main Chl a/b LHC in higher plants. In the Soret region, however, an unusually intense (+) 441 nm band was observed, which was accompanied by negative bands between 465 and 510 nm. It is proposed that these bands originate from intense excitonic interactions between Chl a and carotenoid molecules. LD measurements revealed that the Q(Y) dipoles of Chl a in Mantoniella thylakoids are preferentially oriented in the plane of the membrane, with orientation angles tilting out more at shorter than at longer wavelengths (9 degrees at 677 nm, 20 degrees at 670 nm and 26 degrees at 662 nm); the Q(Y) dipole of Chl c was found to be oriented at 29 degrees with respect to the membrane plane. These data and the LD spectrum of the LHC, apart from the presence of Chl c, suggest an orientation pattern of dipoles similar to those of higher plant thylakoids and LHC II. However, the tendency of the Q(Y) dipoles of Chl b to lie preferentially in the plane of the membrane (23 degrees at 653 nm and 30 degrees at 646 nm) is markedly different from the orientation pattern in higher plant membranes and LHC II. Hence, our CD and LD data show that the molecular organization of the Chl a/b/c LHC, despite evident similarities, differs significantly from that of LHC II.     

Characteristics of Photosystem I Complexes in the End Membranes of Pea Granal Thylakoids

Two fractions of the light fragments enriched in the photosystem I (PSI) complexes were obtained from pea (Pisum sativum L.) thylakoids by digitonin treatment and subsequent differential centrifugation. The ratio of chlorophyll a to chlorophyll b, chlorophyll/P700 spectra of low-temperature fluorescence, and excitation spectra of long-wave fluorescence were measured. These characteristics were shown to be different due to variation in the size and composition of the light-harvesting antenna of PSI complexes present in the particles obtained. The larger antenna size of one of the fractions was related to the incorporation of the pool of light-harvesting complex II (LHCII). A comparison with the data available allowed us to identify these particles as fragments of intergranal thylakoids and end membranes of granal thylakoids. The suggestion that an increase in the PSI light-harvesting antenna in intergranal thylakoids is related to the attachment of phosphorylated LHCII is discussed.     

Orientation of emitting dipoles of chlorophyll A in thylakoids: considerations on the orientation factor in vivo.

Orientation angles of five emitting dipoles of chlorophyll a in thylakoids were estimated from low temperature fluorescence polarization ratio spectra of magnetically oriented chloroplasts. A simple expression is given also for the evaluation of data from linear dichroism measurements. It is shown that the Qy dipoles of chlorophylls lie more in the plane of the membranes and span a larger angular interval than was previously thought. Values for the orientation factor are calculated using various models corresponding to different degrees of local order of the Qy dipoles of chlorophylls in the thylakoid. We show that the characteristic orientation pattern of the Qy dipoles of chlorophylls in the membrane, i.e., increasing dichroism toward longer wavelengths, may favour energy transfer between the antenna chlorophylls as well as funnel the excitation energy into the reaction centers.     

Chloroplast phosphoproteins. Phosphorylation of polypeptides of the light-harvesting chlorophyll protein complex.

When isolated, intact chloroplasts of pea (Pisum sativum) are incubated in the light with [32P]-orthophosphate, isotope is incorporated into several polypeptides. Among the most conspicuous phosphoproteins are two which form a very closely spaced doublet on dodecyl sulphate/polyacrylamide gels and co-electrophorese with the major polypeptide component of the light-harvesting chlorophyll a/b binding complex. Like the light-harvesting polypeptide, the phosphoprotein doublet is bound to thylakoids, sediments with the heavy particles released from thylakoids after digitonin treatment, is soluble in chloroform/methanol and has an apparent molecular weight of about 26 000. The doublet also appears in the highly purified light-harvesting chlorophyll a/b binding complex isolated from thylakoids by hydrosylapatite chromatography. I conclude that two polypeptide components of the complex are phosphorylated. One of these components may be the major light-harvesting chlorophyll a/b binding protein.     

Effect of cations on the linear dichroism and selective polarized light scattering of thylakoids

The effect of cations on the linear dichroism (LD) and selective polarized light scattering of higher plant thylakoids was investigated. The results show that the major change in LD signal caused by the addition of cations is due to a scattering contribution most probably resulting from thylakoid stacking. However, minor changes in the LD signal also occur on the short wavelength side of the main LD band that persist even when a large proportion of the scattering change is eliminated by increasing the refractive index of the medium. The minor changes appear to be correlated with the cation-induced increase in variable fluorescence and resolution of the spectra at 77 K reveals that the changes in dichroism are due to LD bands of pigments associated with the light-harvesting complex.     

Structure-based simulation of linear optical spectra of the CP43 core antenna of photosystem II

The linear optical spectra (absorbance, linear dichroism, circular dichroism, fluorescence) of the CP43 (PsbC) antenna of the photosystem II core complex (PSIIcc) pertaining to the S(0)?→?S(1) (Q(Y)) transitions of the chlorophyll (Chl) a pigments are simulated by applying a combined quantum chemical/electrostatic method to obtain excitonic couplings and local transition energies (site energies) on the basis of the 2.9?? resolution crystal structure (Guskov et al., Nat Struct Mol Biol 16:334-342, 2009). The electrostatic calculations identify three Chls with low site energies (Chls 35, 37, and 45 in the nomenclature of Loll et al. (Nature 438:1040-1044, 2005). A refined simulation of experimental spectra of isolated CP43 suggests a modified set of site energies within 143?cm(-1) of the directly calculated values (root mean square deviation: 80?cm(-1)). In the refined set, energy sinks are at Chls 37, 43, and 45 in agreement with earlier fitting results (Raszewski and Renger, J Am Chem Soc 130:4431-4446, 2008). The present structure-based simulations reveal that a large part of the redshift of Chl 37 is due to a digalactosyldiacylglycerol lipid. This finding suggests a new role for lipids in PSIIcc, namely the tuning of optical spectra and the creation of an excitation energy funnel towards the reaction center. The analysis of electrostatic pigment-protein interactions is used to identify amino acid residues that are of potential interest for an experimental approach to an assignment of site energies and energy sinks by site-directed mutagenesis.     

Light-modulated exposure of the light-harvesting complex II (LHCII) to protein kinase(s) and state transition in Chlamydomonas reinhardtii xanthophyll mutants

Reversible phosphorylation of chl a/b protein complex II (LHCII), the mobile light-harvesting antenna, regulates its association and energy transfer/dissipation to photosystem (PS) II or I (state transition). Excitation of LHCII induces conformational changes affecting the exposure of the phosphorylation site at the N-terminal domain to protein kinase(s) [Zer, H., et al. (1999) Proc. Natl. Acad. Sci. U.S.A. 96, 8277-8282; Zer, H., et al. (2003) Biochemistry 42, 728-738]. Thus, it was of interest to examine whether the pigment composition of LHCII affects the light-induced modulation of LHCII phosphorylation and state transition. To this end, we have used thylakoids of wild-type Chlamydomonas reinhardtii and xanthophyll deficient mutants npq1, lor1, npq2, npq1 lor1, and npq2 lor1. Phosphorylated protein bands P11, P13, and P17 are considered components of the mobile C. reinhardtii LHCII complex. The protein composition of these bands has been analyzed by mass spectrometry using Qtof-2 with a nanospray attachment. P11 and P13 contain C. reinhardtii light-harvesting chlorophyll a/b binding protein LhcII type I. P17 contains C. reinhardtii LhcII types III and IV. Illumination of isolated thylakoids inhibits the redox-controlled phosphorylation of polypeptide bands P13 and P17 and to a lower extent that of P11. The light-induced inhibition of LHCII phosphorylation and the state transition process are not influenced by extensive differences in the xanthophyll composition of the mutants. Thus, LHCII can be visualized as possessing two functionally distinct, independent domains: (i) the pigment binding transmembrane domain regulating the extent of energy transfer/dissipation and (ii) the surface-exposed phosphorylation site regulating the association of LHCII with PSII or PSI.