Probing the bacteriochlorophyll binding site by reconstitution of the light-harvesting complex of Rhodospirillum rubrum with bacteriochlorophyll a analogues

Structural features of bacteriochlorophyll (BChl) a that are required for binding to the light-harvesting proteins of Rhodospirillum rubrum were determined by testing for reconstitution of the B873 or B820 (structural subunit of B873) light-harvesting complexes with BChl a analogues. The results indicate that the binding site is very specific; of the analogues tested, only derivatives of BChl a with ethyl, phytyl, and geranylgeranyl esterifying alcohols and BChl b (phytyl) successfully reconstituted to form B820- and B873-type complexes. BChl analogues lacking magnesium, the C-3 acetyl group, or the C-13(2) carbomethoxy group did not reconstitute to form B820 or B873. Also unreactive were 13(2)-hydroxyBChl a and 3-acetylchlorophyll a. Competition experiments showed that several of these nonreconstituting analogues significantly slowed BChl a binding to form B820 and blocked BChl a-B873 formation, indicating that the analogues may competitively bind to the protein even though they do not form red-shifted complexes. With the R. rubrum polypeptides, BChl b formed complexes that were further red-shifted than those of BChl a; however, the energies of the red shifts, binding behavior, and circular dichroism (CD) spectra were similar. B873 complexes reconstituted with the geranylgeranyl BChl a derivative, which contains the native esterifying alcohol for R. rubrum, showed in-vivo-like CD features, but the phytyl and ethyl B873 complexes showed inverted CD features in the near infrared. The B820 complex with the ethyl derivative was about 30-fold less stable than the two longer esterifying alcohol derivatives, but all formed stable B873 complexes.     

Influence of carotenoid molecules on the structure of the bacteriochlorophyll binding site in peripheral light-harvesting proteins from Rhodobacter sphaeroides

In the LH2 proteins from Rhodobacter (Rb.) sphaeroides, the hydrogen bonds between the bacteriochlorophyll (Bchl) molecules and their proteic binding sites exhibit a strong variance with respect to carotenoid content and type. In the absence of the carotenoid molecule, such as in the LH2 from Rb. sphaeroides R26.1, the void in the protein structure induces a significant reorganization of the binding site of both Bchl molecules responsible for the 850 nm absorption, which is not observed when the 800 nm absorbing Bchl is selectively removed from these complexes. FT Raman spectra of LH2 complexes from Rb. sphaeroides show that the strength of the hydrogen bond between the 850 nm absorbing Bchl bound to the alpha polypeptide and the tyrosine alpha(45) depends precisely on the chemical nature of the bound carotenoid. These results suggest that the variable extremity of the carotenoid is embedded in these LH2 complexes, lying close to the interacting Bchl molecules. In the LH2 from Rhodopseudomonas acidophila, the equivalent part of the rhodopin glucoside, which bears the glucose group, lies close to the amino terminal of the antenna polypeptide. This contrast suggests that the structure of the carotenoid binding site in LH2 complexes strongly depends on the bacterial species and/or on the chemical nature of the bound carotenoid.     

Isolation, characterization, and comparison of a ubiquitous pigment-protein complex consisting of a reaction center and light-harvesting bacteriochlorophyll proteins present in purple photosynthetic bacteria

Protein complexes (photochemical reaction complex; PR complex) bound to both light-harvesting bacteriochlorophyll-1 (LH-Bchl-1) and reaction center Bchl (RC-Bchl) were purified from Rhodospirillum rubrum (wild and carotenoid-less), Rhodopseudomonas sphaeroides (wild), and Chromatium vinosum (wild). Another protein complex (LH-2 complex) bound to LH-Bchl-2 was also purified from Rps. sphaeroides. The bacteria were grown in the presence of a [14C]amino acid mixture. The purification procedure included molecular-sieve chromatography in the presence of cholate-deoxycholate, and non-equilibrated isoelectric electrophoresis with 3-[(3-cholamidopropyl)dimethylamino]-1-propanesulfonate. The purified complexes were separated into their constituent proteins by sodium dodecylsulfate-polyacrylamide gel electrophoresis. The molar ratios of the proteins were determined by comparing their radioactivities divided by their molecular weights after consideration of the molecular masses of the complexes. The PR complexes all contained per mol: 1 mol each of RC H-, M-, and L-subunits, 10-13 (probably 12) mol each of two other proteins with molecular weights of 11-12K and 8-11K, 28-32 mol Bchl, 13-15 mol carotenoids (except in the carotenoid-less mutant), 2.6-3.9 mol ubiquinone (or menaquinone in Chr. vinosum), and 53-79 mol phosphate without phospholipid. The LH-2 complex contained per mol: 1 mol 52K protein, about 13 (probably 12) mol each of 9K and 8K proteins, 30 mol Bchl, 10 mol carotenoids, and 38 mol phosphate without phospholipid. The PR complexes and LH-2 complex showed similar X-ray diffraction patterns, implying that they had similar, highly organized molecular structures.     

Certain species of the Proteobacteria possess unusual bacteriochlorophyll a environments in their light-harvesting proteins

In this work, we have examined, using Fourier-transform Raman (FT-R) spectroscopy, the bacteriochlorophyll a (BChl a) binding sites in light-harvesting (LH) antennae from different species of the Proteobacteria that exhibit unusal absorption properties. While the LH1 complexes from Erythromicrobium (E.) ramosum (RC-B871) and Rhodospirillum centenum (B875) present classic FT-R spectra in the carbonyl high-frequency region, we show that in the blue-shifted LH1 complex, absorbing at 856 nm, from Roseococcus thiosulfatophilus, as well as in the B798-832 LH2 from E. ramosum, or in the B830 complex from the obligate phototrophic bacterium Chromatium purpuratum, some H-bonds between the acetyl carbonyl of the BChl a and the surrounding protein are missing. The molecular mechanisms responsible for the unusual absorption of these complexes are thus similar to those responsible for tuning of the absorption of the LH2 complexes between 850 and 820 nm. Furthermore, our results suggest that the binding pocket of the monomeric BChl in the LH2 from E. ramosum is different from that of Rps. acidphila or Rb. sphaeroides. The FT-R spectra of Chromatium purpuratum indicate that, in contrast with every LH2 complex previously studied by FT-R spectroscopy, no free-from-interaction keto groupings exist in this complex.     

The complete amino acid sequence of a bacteriochlorophyll a binding polypeptide isolated from the cytoplasmic membrane of the green photosynthetic bacterium Chloroflexus aurantiacus

A polypeptide soluble in organic solvents was isolated from whole membrane fractions of the green thermophilic bacterium Chloroflexus aurantiacus by chromatography on Sephadex LH-60, Whatman DE-32 and Bio Gel P-10. The complete amino acid sequence of this 4.9 kDa polypeptide (44 amino acid residues) was determined. The polypeptide shows a 3-domain structure, similar to the domain structure of the antenna BChI polypeptides of purple photosynthetic bacteria, and sequence homologies (27–39%) to the light-harvesting α-polypeptides of the B870 (890) antenna complexes from purple bacteria. Therefore, the 4.9 kDa polypeptide is designated B(808-866)-α. The typical His residue (conserved His residue identified in all antenna polypeptides of purple bacteria as possible BChI binding site) is found within the hydrophobic domain, which extends from Asn 10 to Leu 30.     

In vitro enzymatic assays of photosynthetic bacterial 3-vinyl hydratases for bacteriochlorophyll biosyntheses

Photosynthesis Research - A chlorosome is a large and efficient light-harvesting antenna system found in some photosynthetic bacteria. This system comprises self-aggregates of bacteriochlorophyll...     

The complete amino acid sequence of the bacteriochlorophyll c binding polypeptide from chlorosomes of the green photosynthetic bacterium Chloroflexus aurantiacus

The BChlc polypeptide was isolated from chlorosomes of the green bacterium Chloroflexus aurantiacus on Sephadex LH-60. The complete amino acid sequence of this 5.6 kDa polypeptide (51 amino acid residues) was determined. Most probably the 5.6 kDa polypeptide forms an α-helix between Trp 5 and Ile 42 with an asymmetrical (bipolar) distribution of polar amino acid residues along the helix axis: (i) At one side of the α-helix 5 Gln and 2 Asn residues are the possible binding sites for 7 BChlc molecules, (ii) On the other side Ser, Thr, His residues seem to be polypeptide-polypeptide interaction sites within the BChlc-protein complexes. It appears that the BChl-protein complex (chlorosome subunit, 5.2 × 6 nm) composed of 12 5.6 kDa polypeptides corresponds to the 'globular units' found by electron microscopy within the chlorosomes.     

Role of bacteriochlorophyll in stabilization of the structure of the core and peripheral light-harvesting complexes from purple photosynthetic bacteria

Pheophytinization of bacteriochlorophyll (BChl) at low pH was investigated in the core (LH1) and peripheral (LH2) light-harvesting complexes, as well as in the ensemble of the reaction center (RC) with the LH1 complex. The stages in disintegration of the native BChl forms in the LH1 complex and in its ensemble with RC were revealed. They were observed as emergence of the absorption band of monomeric BChl and an increase in its intensity, followed by its transformation into the band of monomeric bacteriopheophytin (BPh) and then into the band of aggregated BPh. Unlike the LH1 complex, in the case of the LH2 complex, monomeric BChl was never detected as an intermediate product. While the spectra revealed formation of monomeric BPh, its accumulation did not occur, since its aggregation is very rapid compared to that in the LH1 complex and in the RC-LH1 ensemble. PAAG electrophoresis revealed that pheophytinization of BChl in the LH2 complex was accompanied by disruption of the stable cylindrical structure of this complex with emergence of characteristic fragments consisting of α and β peptides and bearing monomeric BPh, as well as of the α peptide aggregates bearing BPh aggregates. Unlike the LH2 complex, BChl pheophytinization in the LH1 complex did not result in its fragmentation. This is an indication of different types of structural stabilization in the LH1 and LH2 complexes. In the LH2 complex, coordination of bacteriochlorophyll Mg²⁺ by conservative histidine residues of the α and β polypeptides is the main factor responsible for the maintenance of its cylindrical structure. Stability of the LH1 complex is probably based primarily on the highly specific hydrophobic interactions between the surfaces of individual polypeptide chains, since the presence of hydrogen bonds results in autonomy of each αβBChl₂ subunit, rather than in stabilization of the LH1 complex as a whole.     

Interaction of photosynthetic pigments with various organic solvents 2. Application of magnetic circular dichroism to bacteriochlorophyll a and light-harvesting complex 1

Magnetic circular dichroism (MCD) and absorption spectra of metal bacteriochlorin complexes have been measured on bacteriochlorophyll (BChl) a in various solvents and different forms of light-harvesting complexes 1 (LH1 complexes). In hydrophilic organic solvents, the MCD intensity of the Q(y)(0-0) transition of BChl a was sensitive to the wavelength of absorption maximum of Q(x)(0-0), and the ratio of MCD Q(y)(0-0) intensity to the dipole strength (B/D) was inversely proportional to the difference in energy between the Q(x)(0-0) and Q(y)(0-0). The similar correlation has been observed in metal chlorin derivatives as previously reported. The correlation depends on the coordination number of the Mg atom in BChl a and the molecules ligating to it. In a hydrophobic solvent such as carbon tetrachloride (CCl(4)), however, the correlation did not hold because of the existence of aggregates. Hence, the correlation between the values of B/D and the energy difference can be used to estimate the type and number of the molecules ligated to the Mg atom and to disclose the existence of aggregated pigments. We further apply the correlation to the LH 1 complex treated with n-octyl beta-D-glucopyranoside.     

Design and expression of cysteine-bearing hydrophobic polypeptides and their self-assembling properties with bacteriochlorophyll a derivatives as a mimic of bacterial photosynthetic antenna complexes. Effect of steric confinement and orientation of the polypeptides on the pigment/polypeptide assembly process

A series of cysteine-bearing hydrophobic polypeptides analogous to a light-harvesting one betapolypeptide (LH1beta) from the LH1 complex from the purple photosynthetic bacterium, Rhodobacter sphaeroides, was synthesized using an Escherichia coli expression system. The cysteine was placed in the C- or N-terminal regions of the polypeptide to investigate the influence of steric confinement and orientation of the polypeptides via disulfide linkages as they were self-assembled with zinc-substituted bacteriochlorophyll a ([Zn]-BChl a). The polypeptides were expressed as water-soluble fusion proteins with maltose-binding protein (MBP). The fusion proteins formed a subunit-type complex with the [Zn]-BChl a in an n-octyl-beta-d-glucopyranoside (OG) micellar solution regardless of the cross-links or the cleavage of the cysteines, judging from absorption, CD, and fluorescence spectra. Following treatment with trypsin, the polypeptides were detached from the MBP portion. Such trypsin-digested polypeptides formed a subunit-type LH complex at 25 degrees C, which also showed that the disulfide linkage was not crucial for the subunit formation. When a polypeptide having cysteine on the C-terminus was assembled at 4 degrees C, the Qy absorption band was remarkably red-shifted to approximately 836 nm, suggesting that the cleavage of the large MBP portion liberates the polypeptides to form the progressive type of complex similar to LH1-type complex. The trypsin-treated polypeptides bearing cysteines in both terminal regions, which are randomly cross-linked, did not form the LH1-type complex under oxidative conditions but did form the complex under reductive conditions. This observation suggests that the polypeptide orientation strongly influences the LH1-type complex formation. The progressive assembly from the subunit to the holo-LH1-type complex following cleavage of MBP portion in a lipid bilayer is also briefly discussed.     

Structure of a bacterial photosynthetic membrane. Isolation, polypeptide composition, and selective proteolysis

A procedure for the isolation of highly purified bacterial photosynthetic membranes from Rhodopseudomonas viridis is described. The purity of the final membrane fraction has been confirmed by electron microscopy. Seven major polypeptide bands are associated with the photosynthetic membranes, and all seven are resistant to solubilization in Triton X-100 detergent. Two pigmented bands with apparent molecular weights of 44K and 41K are thought to be cytochromes. The three polypeptides with apparent molecular weights of 38K, 32K, and 28K have been reported in reaction center preparations of other laboratories. Two low-molecular-weight (16K and 11K) bands bind bacteriochlorophyll b and may represent light-harvesting bacteriochlorophyll-protein complexes. The structures that were isolated seem to represent complete photosynthetic membranes, consisting of reaction center, electron transport, and light-harvesting components, all arranged in the regular lattice characteristic of viridis. Selective proteolysis of these membranes indicates that all membrane components are accessible to digestion by trypsin and pronase, except for the light-harvesting complexes.     

Reconstitution and replacement of bacteriochlorophyll a molecules in photosynthetic reaction centers

Reaction centers (RCs) of the photosynthetic bacterium Rhodobacter sphaeroides R-26 were reconstituted in liposomes after release of pigments (bacteriochlorophyll a (BChla) and bacteriopheophytin a (BPhea)) by treatment with acetone. As shown by absorption and circular dichroism spectroscopies, the reconstituted RCs had the same arrangement of pigments as the native RC and exhibited photoactivity of the special pair. The recovery yield of RCs of up to 30% was achieved by addition of 7.8-fold excess of BChla in the acetone treatment. Furthermore BChla was partially replaced with Zn-BChla by addition of the pigments during the acetone treatment. About 30% and 50% of the special pair and accessory pigments can be replaced with Zn-BChla, respectively. From this rate, an oxidation-reduction potential of 520 mV (vs. the normal hydrogen electrode NHE) was derived by the simulation of the experimental data, which is 35 mV higher than that of the native RC (484 mV vs. NHE).     

High affinity binding proteins for pancreatic polypeptide on rat liver membranes.

We report here the identification on rat liver plasma membranes and microsomes of proteins that bind pancreatic polypeptide (PP) with high affinity and specificity (plasma membranes: KD = 4.6 nM, Bmax = 3.28 pmol/mg protein; microsomes: KD = 3.45 nM, Bmax = 18.7 pmol/mg protein). These binding proteins appeared coupled to a G-protein, since 0.1 mM guanosine 5'-O-(3-thiotriphosphate) decreased the affinity by half. When 125I-labeled PP-binding protein complexes covalently cross-linked with disuccinimido suberate were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, two radioactive bands with M(r) values of 52,000 and 38,000 were demonstrated. Both bands were inhibited by unlabeled PP with an IC50 of approximately 5 nM (but not by neuropeptide Y or peptide YY). After the cross-linked complexes were solubilized from liver microsomes with 0.2% Triton X-100 and gel-filtered, they did not interact with the lectins wheat germ agglutinin, Ulex europaeus agglutinin, Ricinus communis agglutinin, and soy bean agglutinin. That these binding proteins may not be glycosylated was further supported by the failure of either peptide N-glycosidase F and endo-beta-N-acetylglucosaminidase F to alter the size of the PP-binding protein complexes on gel electrophoresis. These PP-binding proteins may serve as receptors and mediate a hepatic effect of PP.     

X-ray diffraction studies on chromatophore membrane from photosynthetic bacteria. III. Basic structure of the photosynthetic unit and its relation to other bacteriochlorophyll forms

We have performed X-ray diffraction studies on photosynthetic units of Rhodospirillum rubrum and solubilized *B800 + B890 complex from chromatophores of Chromatium vinosum, to investigate the homology of their molecular structures. The native chromatophores of Chromatium vinosum, which contain other bacteriochlorophyll forms, were examined by an X-ray diffraction technique, in order to assess the interactions between the complexes as well as the molecular structures of the bacteriochlorophyll forms. The subchromatophore particles, solubilized by Triton X-100 from cells of Chromatium vinosum, exhibit a major absorption maximum at 881 nm and a minor one at 804 nm, consisting of bacteriochlorophyll form *B800 + B890. The near-IR absorption spectrum of the particle is very similar to that of chromatophores of Rhodospirillum rubrum although the major absorption maximum is shifted slightly. The X-ray diffraction pattern of the subchromatophore particles is very similar to that of chromatophores of Rhodospirillum rubrum. Thus, the subchromatophore particles are considered to be the "photoreaction unit" of Rhodospirillum rubrum. Since the bacteriochlorophyll form, *B800 + B890, is common in the purple bacteria, it is strongly suggested that the photoreaction unit is the basic and common structure existing in the photosynthetic units of purple bacteria. Chromatium vinosum cells exhibit different near-IR absorption spectra, depending on the culture media and also on the intensity of the illumination during culture. The chromatophores from these cells give different equatorial X-ray diffraction patterns. These patterns are much broader than that of solubilized subchromatophore particles, though they have common features. Thus, the molecular structures in the photosynthetic units are different, depending on their constituent bacteriochlorophyll forms.(ABSTRACT TRUNCATED AT 250 WORDS)     

Deduced RNA binding mechanism of ThiI based on structural and binding analyses of a minimal RNA ligand

ThiI catalyzes the thio-introduction reaction to tRNA, and a truncated tRNA consisting of 39 nucleotides, TPHE39A, is the minimal RNA substrate for modification by ThiI from Escherichia coli. To examine the molecular basis of the tRNA recognition by ThiI, we have solved the crystal structure of TPHE39A, which showed that base pairs in the T-stem were almost completely disrupted, although those in the acceptor-stem were preserved. Gel shift assays and isothermal titration calorimetry experiments showed that ThiI can efficiently bind with not only tRNA^Phe but also TPHE39A. Binding assays using truncated ThiI, i.e., N- and C-terminal domains of ThiI, showed that the N-domain can bind with both tRNA^Phe and TPHE39A, whereas the C-domain cannot. These results indicated that the N-domain of ThiI recognizes the acceptor-stem region. Thermodynamic analysis indicated that the C-domain also affects RNA binding by its enthalpically favorable, but entropically unfavorable, contribution. In addition, circular dichroism spectra showed that the C-domain induced a conformation change in tRNA^Phe. Based on these results, a possible RNA binding mechanism of ThiI in which the N-terminal domain recognizes the acceptor-stem region and the C-terminal region causes a conformational change of RNA is proposed.     

Monomeric bacteriochlorophyll is required for the triplet energy transfer between the primary donor and the carotenoid in photosynthetic bacterial reaction centers

Reaction centers from the carotenoidless mutant Rb. sphaeroides R26 were treated with sodium borohydride which is known to remove one of the accessory monomeric bacteriochlorophylls (BB). Subsequently, the carotenoid, spheroidene, was incorporated into the modified reaction centers. It is demonstrated by optical absorption and circular dichroism experiments that spheroidene, reconstituted into the sodium borohydride-treated Rb. sphaeroides R26 reaction centers, is bound in a single site, in the same environment and with the same structure as spheroidene reconstituted into untreated (native) Rb. sphaeroides R26 reaction centers. Transient optical and electron spin resonance spectroscopic data indicate that unless the accessory BB is present, the primary donor-to-carotenoid triplet energy transfer reaction is inhibited. These observations provide direct evidence for the involvement of the accessory BB in the triplet energy transfer pathway.     

Conversion of light into electricity in a semi-synthetic system based on photosynthetic bacterial chromatophores

Chromatophores (Chr) from photosynthetic nonsulfur purple bacterium Rhodobacter sphaeroides immobilized onto a Millipore membrane filter (MF) and sandwiched between two semiconductor indium tin oxide (ITO) electrodes (termed ITO|Chr – MF|ITO) have been used to measure voltage (ΔV) induced by continuous illumination. The maximum ΔV was detected in the presence of ascorbate / N,N,N’N'-tetramethyl-p-phenylenediamine couple, coenzyme UQ₀, disaccaride trehalose and antimycin A, an inhibitor of cytochrome bc₁ complex. In doing so, the light-induced electron transfer in the reaction centers was the major source of photovoltages. The stability of the voltage signal upon prolonged irradiation (>1 h) may be due to the maintenance of a conformation that is optimal for the functioning of integral protein complexes and stabilization of lipid bilayer membranes in the presence of trehalose. Retaining ∼70 % of the original photovoltage performance on the 30th day of storage at 23 °C in the dark under air was achieved after re-injection of fresh buffer (∼40 μL) containing redox mediators into the ITO|Chr – MF|ITO system. The approach we use is easy and can be extended to other biological intact systems (cells, thylakoid membranes) capable of converting energy of light.