On insertion of pigment-associated polypeptides during membrane biogenesis in Rhodopseudomonas capsulata

Early stages in the formation of membranes and photosynthetic units were studied under growth-limiting phototrophic and chemotrophic conditions in cells of Rhodopseudomonas capsulata. The incorporation of polypeptides, forming bacteriochlorophyll-carotinoid-protein complexes in the membrane, was followed by use of pulse-labeling and immunoprecipitation techniques. The newly synthesized polypeptides were inserted into two distinct membrane fractions at both different rates and proportions. The two membrane fractions differed in sedimentation behavior, absorption spectra and activities of the respiratory chain. The individual pigment-associated proteins did not exhibit precursor-product relationship between the two membrane fractions. The data suggest that newly synthesized polypeptides were integrated both into cytoplasmic and pre-existing intracytoplasmic membranes, where the proteins and pigments were assembled to form reaction centers and light-harvesting pigment-protein complexes.Abbreviations Bchl bacteriochlorophyll - cpm counts per minute - M _r relative molecular mass - P 100 pellet of 100,000xg, 60 min - P300 pellet of 300,000xg, 90 min - pO₂ oxygen partial pressure - R Rhodopseudomonas - dodecyl sulfate sodium dodecyl sulfate. International standard units - Bq Becquerel (s^-1) - Pa Pascal (N/m²; 1 Torr=133,3 Pa)     

Time-resolved electron transfer at the donor side of Rhodopseudomonas viridis photosynthetic reaction centers in whole cells

We have studied the electron transfer reactions from the tetraheme cytochrome of Rhodopseudomonas viridis to the oxidized primary donor in whole cells with a new high sensitivity spectrophotometer. In this apparatus the monochromatic detecting flashes are provided by a YAG pumped Optical Parametric Oscillator, allowing a 10 ns time resolution. When four hemes are reduced the observed electron transfer reaction sequence is the following: first the low-potential c552 heme (the number refers to the maximum absorption wavelength in the alpha-band region) is oxidized with a half time of 130 ns, in agreement with previous reports of measurements performed with purified reaction centers. Then, the electron hole is transferred to the low potential c554 heme with a half time of 2.6 µs. When only the two high potential hemes are reduced the observed electron transfer sequence is the following: oxidation of the high potential c559 heme in the hundreds of ns time range (410 ns), reduction of this heme by the high potential c556 heme in the µs time range (2.7 µs). This confirms the first steps of electron transfer observed in isolated reaction centers. However, in the microsecond time domain, the overall amount of oxidized hemes increases suggesting that, in vivo, the equilibrium constant between the P⁺/P and the c559^ox/c559^red couples is significantly lower than expected from the difference in their midpoint potentials.     

Light-induced conformational change at low temperature in the coordination of heme c-556 in the reaction center of Rhodopseudomonas viridis

Isolated reaction centers of Rhodopseudomonas viridis with the two high-potential hemes reduced were illuminated at 5 K. Difference spectra show a bleaching of the heme c-556 alpha bands and a red shift of the Soret band. These effects are reversed by warming to around 80 K. They are not induced by near infra-red light absorbed by the chlorine pigments of the reaction centers and they are not associated with electron transfer from P to Q_A. It is concluded that, following direct excitation, heme c-556 becomes five-coordinated. We find no evidence of a significant photooxidation of heme c-559 under the same conditions.     

Turnover of the B870-α pigment-binding protein in a mutant of Rhodopseudomonas capsulata which is defective in assembling reaction center and B870 into membranes

Abstract The photosynthetically negative mutant strain Y142 of Rhodopseudomonas capsulata , which synthesizes bacteriochlorophyll (Bchl), carotenoids and the light-harvesting (LH) complex B800–850, but no reaction center and LH complex B870, is capable of synthesizing the Bchl-binding polypeptide (α, 12 kDa) of B870. In contrast to the high stability of the polypeptides of the B800–850 complex, the 12 kDa polypeptide was rapidly degraded after synthesis and insertion into the membrane.     

Synthesis of the Rhodopseudomonas viridis holo-cytochrome c2 in Paracoccus denitrificans

Abstract The gene encoding the Rhodopseudomonas viridis cytochrome c ₂ (cycA) has been introduced on a broad host range vector into Paracoccus denitrificans , leading to high-level expression of the holo-cytochrome with the heme moiety covalently attached to the apoprotein. The cytochrome was demonstrated to reside in the periplasmic space of the host cell. In contrast to R. viridis , aerobic rather than anaerobic growth conditions led to higher production levels of the holo-cytochrome in P. denitrificans . This heterologous expression system provides a suitable genetic background for the functional expression and mutagenesis of polypeptides involved in bacterial photosynthesis, offering the possibility of detailed structural and functional investigation.     

Structural analysis of photosynthetic membranes by cryo-electron tomography of intact Rhodopseudomonas viridis cells

During the photosynthetic process, highly organized membranal assemblies convert light into biochemical energy with high efficiency. We have used whole-mount cryo-electron tomography to study the intracellular architecture of the photosynthetic membranes of the anaerobic purple photosynthetic bacterium Rhodopseudomonas viridis, as well as the organization of the photosynthetic units within the membranes. Three-dimensional reconstruction demonstrates a continuity of the plasma membrane with the photosynthetic membranes that form tunnel-like structures with an average diameter of 31 nm ± 8 nm at the connection sites. The spacing between the photosynthetic membranes at their cytoplasmic faces was found to be 11 nm, thus enforcing a highly close packaging of the photosynthetic membranes. Analysis of successive tomographic slices allowed for derivation of the spacing between adjacent photosynthetic core complexes from a single-layered photosynthetic membrane, in situ. This analysis suggests that most, if not all, photosynthetic membranes in R. viridis are characterized by a similar two-dimensional hexagonal lattice organization.     

The Rhodopseudomonas viridis photosynthetic membrane: arrangement in situ

The organization of photosynthetic membranes in the cytoplasm of the photosynthetic bacterium Rh. viridis has been examined by several techniques for electron microscopy. Thin sections of membrane stacks show that the regular lattice of membrane subunits reported in other studies can be observed in thin section. Tilting of sections in the electron microscope shows that the regular lattices of several membranes overlap in a way that suggests they are in register with each other. This observation can be confirmed by freeze-fracture images in which a regular arrangement of membrane lattices can be observed, each perfectly aligned.Analysis of the spacings of membrane pairs shows that the photosynthetic membranes of Rh. viridis are very closely apposed. The mean diameter of two membranes is 160A, and the average space between two such membranes is only 42A. When a recently developed atomic level model of Rh. viridis reaction center is superimposed against these spacings, each reaction center extends from the surface of its respective membrane far enough to make contact with an apposing membrane. The limited free space between membranes and regular alignment of lattices has a number of implications for how this membrane is organized to carry out the process of energy transfer.     

The Photosynthetic Reaction Centre from the Purple Bacterium Rhodopseudomonas viridis

We first describe the history and methods of membrane protein crystallization, and show how the structure of the photosynthetic reaction centre from the purple bacterium Rhodopseudomonas viridis was solved. The structure of this membrane protein complex is correlated with its function as a light-driven electron pump across the photosynthetic membrane. Finally we draw conclusions on the structure of the photosystem II reaction centre from plants and discuss the aspects of membrane protein structure.Published in Les Prix Nobel–The Nobel Prizes 1988 (Nobel Foundation, Stockholm, 1989) and republished here with the permission of the Nobel Foundation the copyright holders.     

Efficient photochemical activity and strong dichroism of single crystals of reaction centers from Rhodopseudomonas viridis

Crystallized reaction centers from Rhodopseudomonas viridis (i) are photochemically active with electron transfer from the special pair to the quinones, (ii) show dichroism giving valuable information on the orientation of the different chromophores and (iii) allow chemical treatment in the crystalline phase.     

Orientation of reaction center and antenna chromophores in the photosynthetic membrane of rhodopseudomonas viridis

Whole cells of Rhodopseudomonas viridis were oriented in a magnetic field. The degree of orientation of the cells was determined by using a photoselection technique. In order to deduce the orientation of the antennae and chromophores of the reaction centers with respect to the membrane plane, we performed linear dichroism measurements of absolute spectra and light induced difference spectra linked to states P⁺I and PI^? on oriented cells. These measurements lead to the following conclusions:The antennae bacteriochlorophyll molecular plane is nearly perpendicular to the membrane. The Q_y and Q_x transitions moments of these molecules make respectively angles of 20 and 70°ith the membrane plane. The antenna carotenoid molecules make an angle of 45°ith the membrane.The primary electron donor possesses two transition moments centered respectively at 970 and 850 nm. The 970 nm transition moment is parallel to the membrane plane, the 850 nm transition is tilted out of the plane. Upon photooxidation of this primary electron donor, a monomer-like absorption band appears at 805 nm. Its transition makes an angle smaller than 25° with the membrane. The photooxidation of the dimer also induces an absorption band shift for the two other bacteriochlorophyll molecules of the reaction center. The absorption band shifts of the two bacteriochlorophyll molecules occur in opposite direction.One bacteriopheophytin molecule is photoreduced in state PI^?. This photoreduction induces an absorption band shift for only one bacteriochlorophyll molecule. Finally, the geometry of the dimeric primary donor seems to be affected by the presence of a negative charge in the reaction center.     

Localisation of reaction centre and light harvesting complexes in the photosynthetic unit of Rhodopseudomonas viridis

The photosynthetic unit of Rhodopseudomonas viridis contains a reaction centre (P960) and a light harvesting complex (B1015). Immune electron microscopy combined with image processing has allowed the central core of the photosynthetic unit to be identified as the reaction centre and the surrounding protein ring as the light harvesting complex. This light harvesting complex, subdivided into twelve subunits was shown to contain 24 bacteriochlorophyll b molecules. A model is presented which may account for the far red shift of the Qy absorption of the bacteriochlorophyll b molecules in vivo.     

Comparative studies on membranes isolated from Rhodopseudomonas viridis grown in the presence and in the absence of yeast extract

Rhodopseudomonas viridis was grown in the presence and in the absence of yeast extract. The cells grown under this latter condition present a ten fold diminished bacteriochlorophyll (bchl) content. This decrease was paralleled by a similar increase in the ratio lipid phosphorous/bchl, whereas the ornithine lipid/bchl ratio remains constant. Some quantitative differences in the fatty acid composition are also reported.The protein composition of both membranes was also studied, only indicating quantitative differences.An active reaction center preparation was obtained from both types of cells. When isolated from cells grown in the presence of yeast extract, this reaction center preparation shows the presence of proteins a, b, c and d. Further treatment of this active reaction center results, in cells grown under either condition, in the isolation of green (oxidized behl) and brown (inactive reaction center) bchl containing fractions.The protein composition and absorption spectrum of the inactive reaction centers obtained from both types of cells were identical (proteins a, c and d).On the other hand the green complexes differ in their protein composition as well as in their absorption spectrum.     

Electronic interactions between iron and the bound semiquinones in bacterial photosynthesis. EPR spectroscopy of oriented cells of Rhodopseudomonas viridis

Electron paramagnetic resonance (EPR) spectroscopy of the iron-semiquinone complex in photosynthetic bacterial cells and chromatophores of Rhodopseudomonas viridis is reported. Magnetic fields are used to orient the prolate ellipsoidal-shaped cells which possess a highly ordered internal structure, consisting of concentric, nearly cylindrical membranes. The field-oriented suspension of cells exhibits a highly dichroic EPR signal for the iron-semiquinone complex, showing that the iron possesses a low-symmetry ligand field and exists in a preferred orientation within the native reaction-center membrane complex. The EPR spectrum is analyzed utilizing a spin hamiltonian formalism to extract physical information describing the electronic structure of the iron and the nature of its interaction with the semiquinones. Exact numerical solutions and analytical expressions for the transition frequencies and intensities derived from a perturbation theory expansion are presented, and a computer-simulated spectrum is given. It has been found that, for a model which assumes no preferred orientation within the plane of the membranes, the orientation of the Fe²⁺ ligand axis of largest zero-field splitting (Z, the principal magnetic axis) is titled 64±6° from the membrane normal. The ligand field for Fe²⁺ has low symmetry, with zero-field splitting parameters of |D₁|=7.0±1.3 cm^?1 and |E₁|=1.7±0.5 cm^?1 and $\text{|}\text{E}{}_1\text{D}{}_1\text{|=0.26}$ for the redox state Q₁^?Fe²⁺Q^2?. The rhombic character of the ligand field is increased in the redox state Q₁Fe²⁺Q^?₂, where $\text{0.33>|}\text{E}{}_2\text{D}{}_2\text{|>0.26}$. This indicates that the redox state of the quinones can influence the ligand field symmetry and splitting of the Fe²⁺. There exists an electron-spin exchange interaction between Fe²⁺ and Q^?₁ and Q^?₂, having magnitudes |J₁|=0.12±0.03 cm^?1 and $\text{|J}{}_2\text{|?0.06}\text{cm}{}^{\mathrm{?1}}$, respectively. Such weak interactions indicate that a proper electronic picture of the complex is as a pair of immobilized semiquinone radicals having very little orbital overlap (probably fostered by superexchange) with the Fe²⁺ orbitals. The exchange interaction is analyzed by comparison with model systems of paramagnetic metals and free radicals to indicate an absence of direct coordination between Fe²⁺ and Q^?₁ and Q^?₂. Selective line-broadening of some of the EPR transitions, involving Q^? coupling to the magnetic sublevels of the Fe²⁺ ground state, is interpreted as arising from an electron-electron dipolar interaction. Analysis of this line-broadening indicates a distance of 6.2–7.8 ? between Fe²⁺ and Q^?₁, thus placing Q₁ outside the immediate coordination shell of Fe²⁺.     

The incorporation of reaction centres into membranes from a bacteriochlorophyll-less mutant of Rhodopseudomonas sphaeroides

Reaction centres purified from a blue-green mutant R-26 of Rhodopseudomonas sphaeroides can be incorporated into bacteriochlorophyll-less membranes purified from an aerobically-grown bacteriochlorophyll-less mutant 01 of R. sphaeroides. This can be accomplished by raising the temperature of the mixture or by addition of the detergent sodium cholate and its subsequent removal by dilution or dialysis. Optimum conditions for the reconstitution are at 4°C in the presence of 1% cholate and soybean phospholipid (2 : 1, w/w, with membrane protein). Isopycnic sucrose density gradient centrifugation of such preparations shows that reaction centres and light-harvesting pigment-protein complex bind to the membranes. Reconstituted membranes exhibit light-induced steady-state cytochrome absorbance changes resembling those observed in chromatophores prepared from the photosynthetically-grown mutant R-26. The effect on these absorbance changes of varying reaction centre content in the membrane has been studied, and the time course of the interaction between 01 membrane cytochrome c₂ and added reaction centre examined.Cytochrome b photoreduction and cytochrome c₂ photo-oxidation were observed in the reconstituted preparation; each increased following the addition of antimycin A, suggesting that a cyclic light-driven system had been reconstituted.     

翡翠贻贝精子的超微结构

利用透射电镜研究翡翠贻贝 (Pernaviridis)精子的超微结构。精子为典型的原生型 ,包括头部、中段与尾部三部分。头部由顶体和细胞核组成。顶体明显突出呈倒漏斗形。亚顶体腔呈锥形 ,其中的亚顶体物质呈伞状分布 ,中轴一直延伸至核的后端。细胞核近似球形 ,被管状的核前窝几乎分成相似的两部分。 4～ 5个椭圆形的线粒体围绕着中心粒复合体形成精子的中段。中心粒为中空的圆柱形 ,具有卫星体结构。尾部细长 ,轴丝为典型的“9 2”结构。本文讨论了双壳类精子形态的种属间的差异。     

Absorbance changes of carotenoids and bacteriochlorophylls responding to the change of local electrical field induced by hydrophobic anion,tetraphenylborate in membranes of photosynthetic bacteria

Large blue-shifts of carotenoid absorption bands were induced by dark addition of a hydrophobic anion, tetraphenylborate, in chromatophores and cell membranes of photosynthetic bacteria, Rhodopseudomonas sphaeroides and Rhodopseudomonas capsulata. Tetraphenylborate also induced a red-shift of the 850 nm absorption band and a blue-shift and broadening of the 800 nm band of bacteriochlorophyll. From the analysis of the relation between the magnitude and isosbestic wavelength of the absorbance changes the tetraphenylborate-induced carotenoid band shift were assumed to reflect the change of local electrical field close to each carotenoid molecule which exists as a minor pool on the light-harvesting pigment-protein complex II (LHC II). Absorbance changes of carotenoid and chlorophylls were also induced by tetraphenylborate in membranes of spinach chloroplasts.     

Isolation of cytochrome bc 1 complexes from the photosynthetic bacteria Rhodopseudomonas viridis and Rhodospirillum rubrum

Cytochrome bc ₁ complexes have been isolated from wild type Rhodopseudomonas viridis and Rhodospirillum rubrum and purified by affinity chromatography on cytochrome c-Sepharose 4B. Both complexes are largely free of bacteriochlorophyll and carotenoids and contain cytochromes b and c ₁ in a 2:1 molar ratio. For the Rps. viridis complex, evidence has been obtained for two spectrally distinct b-cytochromes. The R. rubrum complex contains a Rieske iron-sulfur protein (present in approximately 1:1 molar ratio to cytochrome c ₁) and catalyzes an antimycin A- and myxothiazol-sensitive electron transfer from duroquinol to equine cytochrome c or R. rubrum cytochrome c ₂. Although an attempt to prepare a cytochrome bc ₁ complex from the gliding green bacterium Chloroflexus aurantiacus was not successful, membranes isolated from phototrophically grown Cfl. aurantiacus were shown to contain a Rieske iron-sulfur protein and protoheme (the prosthetic group of b-type cytochromes).Dedicated to Prof. L.N.M. Duysens on the occasion of his retirement.     

Recombination reduction of photooxidized cytochrome c in reaction centers of Rhodopseudomonas viridis at low temperature

The temperature dependence of dark reduction of photooxidized cytochrome c was studied in isolated preparations of Rhodopseudomonas viridis reaction centers. Within the range from room temperature to 260 K this process was found to be mediated by thermal diffusion of exogenous donor molecules, whereas at lower temperatures photooxidized cytochrome is reduced as a result of indirect recombination with photoreduced primary quinone acceptor. Kinetic simulation allowed certain thermodynamic characteristics of this reaction to be calculated. To the first approximation, these characteristics correlate with the estimates obtained from the results of direct redox titration.     

不同生境中沼泽红假单胞菌基因型多样性分析

沼泽红假单胞菌(Rhodopseudomonas palustris,R.palustris)是一种分布广泛的紫色非硫细菌,代谢方式的多样性赋予了它们重要的生态学意义和应用价值。从湖泊、池塘和河流的11个底泥样品中富集培养紫色非硫细菌,利用基于pufM基因的PCR-DGGE技术鉴定为R.palustris,再利用rep-PCR技术进行基因型指纹图谱分析。结果发现相近生境,即湖泊中的菌株基因型相似度较高,80%,而差异越大的生境中菌株基因型指纹图谱差异也越大。这种基因型差异性分析不仅可以帮助研究者更全面地了解不同环境中R.palustris基因型多样性,也为进一步揭示其生态学意义和进化过程提供基础。