Pigment-protein complexes from Rhodopseudomonas palustris: isolation, characterization, and reconstitution into liposomes.

We have employed detergent solubilization and sucrose density gradient centrifugation to obtain pigment-protein complexes from Rhodopseudomonas palustris. Two types of detergent buffers were used, containing either octyl-beta-glucopyranoside (OG) plus sodium dodecyl sulfate (SDS) or OG alone. The fractions thus obtained were analyzed spectrophotometrically and by polyacrylamide gel electrophoresis to determine their pigment and protein composition. OG-SDS solubilization yields four fractions. The least dense of these fractions (OG-SDS a and b) are nonspecific mixtures of peptides and pigments. The next fraction, OG-SDS c, is an accessory light-harvesting complex, LHII, called B800-850. The largest particle, OG-SDS d, is a combination of reaction center (RC) and primary light-harvesting complex (LHI), B880. Solubilization using OG alone yields one fraction, a single large complex consisting of RC, LHI, and LHII. We have inserted the two large OG-SDS complexes and the OG complex into phospholipid liposomes to determine the size of such complexes in freeze-fractured membranes. On the basis of morphological, biochemical, and available biophysical data, we propose the following models for pigment-protein complexes in R. palustris membranes: 5-nm particles as free RC or LHI tetramers, 7.5-nm particles as LHI or LHII octamers (or both); 10-nm particles as RC-LHI core complexes (1 RC plus 12 LHI) or large LHII oligomers (or both), and large particles of 12.5 and 15 nm and LHII associated with the RC-LHI core complex.     

Antenna organization in the purple sulfur bacteria Chromatium tepidum and Chromatium vinosum

Structural aspects of the core antenna in the purple sulfur bacteria Chromatium tepidum and Chromatium vinosum were studied by means of fluorescence emission and singlet-singlet annihilation measurements. In both species the number of bacteriochlorophylls of the core antenna between which energy transfer can occur corresponds to one core-reaction center complex only. From measurements of variable fluorescence we conclude that in C. tepidum excitation energy can be transferred back from the core antenna (B920) to the peripheral B800–850 complex in spite of the relatively large energy gap, and on basis of annihilation measurements a model of separate core-reaction center units accompanied by their own peripheral antenna is suggested. C. vinosum contains besides a core antenna, B890, two peripheral antennae, B800–820 and B800–850. Energy transfer was found to occur from the core to B800–850, but not to B800–820, and it was concluded that in C. vinosum each core-reaction center complex has its own complement of B800–850. The results reported here are compared to those obtained earlier with various strains and species of purple non-sulfur bacteria.Abbreviations BChl- bacteriochlorophyll - B800–820 and B800–850- antenna complexes with Q_y-band absorption maxima near 800 nm and 820 or 850 nm, respectively - B890 and B920- antenna complexes with Q_y-band absorption maxima near 890 and 920 nm, respectively - LH1- light harvesting 1 or core antenna - LH2- light harvesting 2 or peripheral antenna     

Investigation of spatial relationships and energy transfer between complexes B800-850 and B890-RC from Chromatium minutissimum reconstituted into liposomes.

Spatial relationships between different pigment-protein complexes in the membranes of the purple photosynthetic bacterium, Chromatium minutissimum, have been studied. The possibility of restoring the function of efficient excitation energy transfer from bacteriochlorophyll molecules to the reaction centers in the system of soybean liposomes, reconstituted with pigment-protein complexes B800-850 and B890-RC from C. minutissimum, has been explored. The chemical cross-linking method, together with stationary and picosecond spectrally resolved fluorescence measurements were employed. It has been shown that after the incorporation of the complexes into the liposome membranes conditions for directed excitation energy transfer from the light-harvesting pigments to the reaction centers are created, which are less optimal, however, than those in the native state. Possible reasons are considered.     

The light-harvesting complex II (B800-850) of Rhodobacter sulfidophilus: Characterization and formation under different growth conditions

Abstract The photosynthetic bacterium Rhodobacter sulfidophilus is able to grow chemotrophically and phototrophically at a broad range of light intensities. In contrast to other facultative phototrophs, R. sulfidophilus synthesizes reaction center and light-harvesting (LH) complexes, B870 (LHI) and B800–850 (LHII) even under full aerobic conditions in the dark. The content of bacteriochlorophyll (BChl) varied from 3.8 μg Bchl per mg cell protein when grown at high light intensity (20 000 lux) to 60 μg Bchl per mg cell protein when grown at low light intensities (6 lux). After a shift from high light to low light conditions, the size of the photosynthetic unit increased by a factor of 4. Chromatographie analysis of the LHII complex, isolated and purified from cells grown phototrophically (at high and low light intensities) and chemotrophically, could resolve only one type of a and one type of β polypeptide in the purified complex, of which the N-terminal sequences have been determined.     

Model of detergent-induced spectral changes of the B800-850 complex from Chromatium minutissimum

The absorption and circular dichroism spectra of the B800-850 complex from Chromatium minutissimum before and after the Triton X-100 treatment were simulated by means of standard exciton theory, taking into account inhomogeneous broadening. To explain the spectral changes of the B800-850 complex treated with Triton X-100, we have assumed that all bacteriochlorophyll pigments absorbing at 850 nm exhibit the same additional rotation of approximately 20 degrees around the axis perpendicular to the membrane plane. This has been sufficient to fit the transformation in absorption and circular dichroism spectra induced by detergent treatment of the B800-850 complex.     

Comparative study of B890 pigment-lipoprotein complexes from sulfur (Chromatium minutissimum) and non-sulfur (Rhodopseudomonas palustris) purple photosynthesizing bacteria]

Pigment-lipoprotein B890 complexes containing reaction center and "light-focusing" bacteriochlorophyll a were isolated from photosynthetic membranes of sulfur (Chromatium minutissimum) and non-sulfur (Rhodopseudomonas palustris) purple bacteria after the treatment with Triton X-100. The molecular weights of complexes were evaluated using several methods (200 000-300 000). By means of electron microscopy the sizes of complexes were found to be about 80 A. On the air-water interface hexagonal packing of complexes was observed. The chemical compositions of complexes are very similar except bacteriochlorophyll a whose specific content is somewhat higher in Chromatium minutissimum. The protein composition of complexes was studied and the molecular weights of proteins were estimated by SDS-gel electrophoresis. The results obtained show significant similarities in molecular organization of B890 complexes isolated from sulfur (Chromatium minutissimum) and non-sulfur (Rhodopseudomonas palustris) purple bacteria.     

Excitation dynamics in strongly bounded associates of B800–850 and B800–830 complexes from photosynthetic purple bacterium Thiorhodospira sibirica

Strongly bounded associates of B800–850 (LH2) and B800–830 (LH3) complexes from photosynthetic purple bacterium Thiorhodospira sibirica were investigated. It was shown that associates contain 8–10 complexes (LH2:LH3 ≈ 1:1). Absorption spectra of the monomer LH2 and the monomer LH3 complexes were calculated. Excitation of B800 absorption band of associates results in: (i) intracomplex excitation energy transfer from B800 to B830 or B850 with time constant of about 500 fs; (ii) intercomplex excitation energy transfer from B820 band of LH3 complex to B850 band of LH2 complex with time constant of about 2.5 ps; (iii) excitation deactivation in B850 band of LH2 complex with time constant of about 800 ps. Signal polarization at long-wavelength side of associates absorption spectrum near 900 nm was negative (?0.1). The interaction of LH3 and LH2 complexes in associates is, to some extent, analogous to the interaction of LH2 and LH1 complexes in chromatophores. Time constant of excitation energy transfer between LH3 and LH2 complexes in associates may be regarded as a minimal time constant for energy transfer between the peripheral and core antenna complexes.     

Structural characterization and comparison of antenna complexes of R26 and R26.1 mutants of Rhodopseudomonas sphaeroides

A reverted R26.1 strain of Rps. sphaeroides contains two types of light-harvesting complexes, absorbing near 880 and 850 nm. Resonance Raman spectroscopy provides evidence that the compensating mutation which, in R26.1, restored an 850-nm-absorbing antenna population, results in a local structure around the bacteriochlorophylls a that is the same as in the B850 (800-depleted) complexes from Rps. sphaeroides 2.4.1 (wild strain). Yet, this compensation is accompanied by a marked change in the control mechanisms of the synthesis of the antenna complexes.     

The isolation and partial characterisation of the light-harvesting pigment-protein complement of Rhodopseudomonas acidophila

The photosynthetic membranes of two strains of Rhodopseudomonas acidophila (7750 and 7050) have been resolved into their constituent light-harvesting pigment-protein complexes. Four different types of antenna complexes (B880, B800–830 and two types of B800–850) have been isolated and partially purified. In each case the light-harvesting pigments (bacteriochlorophyll a and carotenoids) are bound to rather low molecular weight polypeptides (in the 5000–9000 region).     

UV-Induced destruction of light-harvesting complexes from purple bacterium Chromatium minutissimum

We studied UV-induced photodestruction of the native forms of bacteriochlorophyll a (Bchl a) from chromatophores and light harvesting complexes (LHC) of the sulphur photosynthetic bacterium Chromatium minutissimum. Irradiation of chromato- phores with 365-nm light (Soret band) or 280-nm light (absorption region of aromatic amino acids) led to the destruction of all long-wavelength forms of Bchl a. The quantum yields of photodestruction produced by the 280-nm light was higher than that produced by the 365-nm light. For the spectral forms of Bchl a absorbing at 850 nm and 890 nm, the difference was about one order of magnitude, and for the form absorbing at 800 nm the difference was almost two orders of magnitude. Similar UV sensitivity was observed for the Bchl a forms from isolated LHC. As a rule, the quantum yields of photodestruction induced by UV irradiation at 280 nm were about 100-1000 times higher (approximately 10(-3)-10(-4)) than that upon red light irradiation (approximately 10(-6)-10(-7)). We found that irradiation of chromatophores at 280 nm resulted in a crosslink between the core and peripheral LHC.     

Polarization single complex imaging of circular photosynthetic antenna

Single complex fluorescence polarization spectroscopy is applied to study the peripheral light harvesting antenna (LH2) from photosynthetic purple bacterium Rhodopseudomonas (Rps.) acidophila. The measured two-dimensional excitation-emission polarization plots are used to construct geometric representation for the absorbing B800 and emitting B850 as ellipses. The shape and orientation of the ellipses is discussed in terms of tilted LH2 complexes where emission occurs from energetically disordered B850 excitons.     

Changes in the content of pigment-protein complexes in Rhodobacter sphaeroides forma sp. denitrificans grown under photosynthetic and photo-denitrifying conditions

Changes in the relative content of pigment-protein complexes, RC-B880 and B800-850, were studied in membranes of Rhodobacter sphaeroides forma sp. denitrificans cultured under various anaerobic conditions. The content of each pigment-protein complex was determined by the decomposition of the absorption spectra of membranes in the near-infrared region into the spectra of RC-B880 and B800-850. The standard spectrum of each complex in the membranes was obtained using two absorption spectra of membranes with different ratios of the complexes by eliminating the spectrum of first one than the other complex. Spectra composed from the two standard spectra were in good agreement with original membrane spectra after subtraction of the contribution of scattering in various membrane samples. Bacteriochlorophyll (BChl) content in the membrane was dependent on the light intensity during growth. The relation between the total BChl content in the membrane and BChl content in the RC-B880 and B800-850 complex was linear above 15 nmol BChl per mg membrane protein, regardless of the culturel conditions, photosynthetic or photo-denitrifying. The linear relationship reached a point where all BChl molecules were contained in RC-B880 at 13 nmol BChl per mg membrane protein. This means that only RC-B880 would be synthesized below the threshold, and above the threshold additional BChl was distributed between RC-B880 and B800-850 in a constant ratio (1:5.7). The results suggest that the syntheses of B800-850 and RC-B880 are not regulated independently.     

Reconstitution of carotenoids into the light-harvesting complex B800-850 of Chromatium minutissimum

Chromatophores and peripheral light-harvesting complexes B800–850 with a trace of carotenoids were isolated from Chromatium minutissimum cells in which carotenoid biosynthesis was inhibited by diphenylamine. Three methods previously used for the reconstitution of carotenoids into either the light-harvesting (LH1) type complexes or reaction centers (RC) of carotenoidless mutants were examined for the possibility of carotenoid reconstitution into the carotenoid depleted chromatophores. All these methods were found to be unsuitable because carotenoid depleted complex B800–850 from Chr. minutissimum is characterized by high lability. We have developed a novel method maintaining the native structure of the complexes and allowing reconstitution of up to 80% of the carotenoids as compared to the control. The reconstituted complex has a similar CD spectrum in the carotenoid region as the control, and its structure restores its stability. These data give direct proof for the structural role of carotenoids in bacterial photosynthesis.     

Heterologous synthesis and assembly of functional LHII antenna complexes from <Emphasis Type="Italic">Rhodovulum sulfidophilum</Emphasis> in <Emphasis Type="Italic">Rhodobacter sphaeroides</Emphasis> mutant

The light harvesting complexes, including LHII and LHI, are the important components of photosynthetic apparatus. Rhodovulum (Rdv.) sulfidophilum and Rhodobacter (R.) sphaeroides belong to two genera of photosynthetic bacteria, and they are very different in some physiological characteristics and light harvesting complexes structure. The LHII structural genes (pucBsAs) from Rdv. sulfidophilum and the LHI structural genes (pufBA) from R. sphaeroides were amplified, and cloned into an expression vector controlled by puc promoter from R. sphaeroides, which was then introduced into LHI and LHII-minus R. sphaeroides mutants; the transconjugant strains synthesized heterologous LHII and native LHI complexes, which played normal roles in R. sphaeroides. The Rdv. sulfidophilum LHII complex from pucBsAs had near-infrared absorption bands at ~801–853 nm in R. sphaeroides, and was able to transfer energy efficiently to the native LHI complex. The results show that the pucBsAs genes from Rdv. sulfidophilum could be expressed in R. sphaeroides, and the functional foreign LHII and native LHI were assembled into the membrane of R. sphaeroides.     

Oxido-reduction of B800-850 and B880 holochromes isolated from three species of photosynthetic bacteria as studied by electron-paramagnetic resonance and optical spectroscopy

Certain redox properties of bacteriochlorophyll alpha were used to probe the structure of several light-harvesting pigment-protein complexes or holochromes. To attribute redox properties unequivocally to a given holochrome, we worked with purified holochromes. We developed purification procedures for the B880 holochromes from Rhodospirillum rubrum, Rhodopseudomonas sphaeroides and Ectothiorhodospira sp. and for the B800-850 holochromes from the latter two species. In all these holochromes, bacteriochlorophyll alpha could be oxidized by ferricyanide as witnessed by the bleaching of their near-infrared absorption bands. However, only in B880 holochromes was this oxidation reversible. Another important difference between the B800-850 and the B880 holochromes is that oxidation of the latter gives rise to a g = 2.0025 electron paramagnetic resonance (EPR) signal with linewidth varying, according to species, from 0.37 mT to 0.48 mT. Both the reversible EPR signal and absorption changes titrate with a midpoint redox potential (pH 8.0) of approximately 570 mV. Linewidth narrowing can be interpreted by delocalization of the free electron spin over approximately 12 bacteriochlorophyll molecules. While the B880 holochromes from the three species considered had indistinguishable redox properties, the B800-850 holochromes differed from one another by their circular dichroic spectra and by the relative ease of oxidation of their 800-nm and 850-nm bands. This indicates that, contrary to the B880 holochromes, the B800-850 holochromes may not form a homogeneous class.     

Structural characterization of high 800 nm-absorbing light-harvesting complexes from Rhodospirillales from their resonance Raman spectra

Resonance Raman spectroscopy provided evidence that high 800 nm-absorbing antennae from Rhodopseudomonas (Rps.) acidophila and Rps. palustris have similar structures around their dweller bacteriochlorophylls. These host-site structures are different from those of B 850-800 complexes from Chromatiaceae, which also exhibit a high absorbance at 800 nm. As also shown by previous biochemical data, these complexes might be stoichiometrically different from other antenna complexes, having one more BChl per minimal size unit of protein. A new classification of B 850-800 complexes is proposed, on the basis of resonance Raman and biochemical data: this classification distinguishes a class of B 850-800 S (involving the B 850-800 complexes from sulfur purple bacteria), two classes of B 850-800 NS (involving the B 850-800 complexes from non sulfur purple bacteria) and a class of H 800 complexes (involving the B 850-800 complexes from non sulfur purple bacteria exhibiting a high absorbance at 800 nm).     

The observation of ultrafast excited-state dynamical evolution in B800- partially or completely released LH2 of Rhodobacter sphaeroides 601 at room temperature

Photodynamics of two kinds of peripheral antenna complexes (LH2 of Rhodobacter sphaeroides, native LH2 (RS601) and B800-released LH2 where B800-BChls were partially or completely removed with different pH treatments), were studied using femtosecond pump-probe technique at different laser wavelengths. The obtained results for these samples with different B800/B850 ratios demonstrated that under the excitation around B800 nm, the photoabsorption and photobleaching dynamics were caused by the direct excitation of upper excitonic levels of B850 and excited state of B800 pigments, respectively. Furthermore, the removal of B800 pigments had little effect on the energy transfer processes of B850 interband/intraband transfer.     

Characteristics of light-harvesting complex II mutant of <Emphasis Type="Italic">Rhodobacter sphaeroides</Emphasis> with alterations at the transmembrane helices of β-subunit

The peripheral light-harvesting complex II (LHII) is an important component of the photosynthetic apparatus of Rhodobacter sphaeroides. In this study, genetic, biochemical, and spectroscopic approaches were applied to investigate the spectral properties and functions of LHII in which two amino acid residues Phe32 and Leu42 in the transmembrane helix domain of pucB-encoded β-apoprotein were replaced by Leu and Pro. The mutated LHII complex showed blue shift of absorbance peaks in the near infrared region at ∼801–845 nm in R. sphaeroides. It should be noted that the B800 peak was much lower than that of the native LHII, and transfer energy was efficient from the B800 to the B850 pigments in the LHII complex. The results suggest that the mutated pucB could be expressed in R. sphaeroides, and the functional LHII was assembled into the membrane of R. sphaeroides notwithstanding with the different spectral properties. These mutated residues were indeed critical for the modulation of characteristics and function of LHII complex. Published in Russian in Biokhimiya, 2009, Vol. 74, No. 7, pp. 993–999.     

The Observation of Ultrafast Excited-state Dynamical Evolution In B800- Partially or Completely Released LH2 of Rhodobacter sphaeroides 601 at Room Temperature

Abstract

Photodynamics of two kinds of peripheral antenna complexes (LU2 of Rhodobacter sphaeroides, native LH2 (RS601) and B800-released LH2 where B800-BChls were partially or completely removed with different pH treatments), were studied using femtosecond pump-probe technique at different laser wavelengths. The obtained results for these samples with different B800/B850 ratios demonstrated that under the excitation around B800 nm, the photoabsorption and photobleaching dynamics were caused by the direct excitation of upper excitonic levels of B850 and excited state of B800 pigments, respectively. Furthermore, the removal of B800 pigments had little effect on the energy transfer processes of B850 interband/intraband transfer.