Completion of biosynthetic pathways for bacteriochlorophyll g in Heliobacterium modesticaldum: The C8-ethylidene group formation

Heliobacteria have the simplest photosynthetic apparatus, i.e., a type-I reaction center lacking a peripheral light-harvesting complex. Bacteriochlorophyll (BChl) g molecules are bound to the reaction center complex and work both as special-pair and antenna pigments. The C8-ethylidene group formation for BChl g is the last missing link in biosynthetic pathways for bacterial special-pair pigments, which include BChls a and b as well. Here, we report that chlorophyllide a oxidoreductase (COR) of Heliobacterium modesticaldum catalyzes the C8-ethylidene formation from 8-vinyl-chlorophyllide a, producing bacteriochlorophyllide g, the direct precursor for BChl g without the farnesyl tail. The finding led to plausible biosynthetic pathways for 8¹-hydroxy-chlorophyll a, a primary electron acceptor from the special pair in heliobacterial reaction centers. Proposed catalytic mechanisms on hydrogenation reaction of the ethylidene synthase-type CORs are also discussed.     

Orientation of the primary quinone of bacterial photosynthetic reaction centers contined in chromatophore and reconstituted membranes

The orientation of the reaction center bacteriochlorophyll dimer, (BChl)₂, and primary quinone, Q_I, has been studied by EPR in chromatophores of Rhodopseudomonas sphaeroides R26 and Chromatium vinosum and in the reconstituted membrane multilayers of the isolated Rps. sphaeroides reaction center protein. The similarity in the angular dependence of the (BChl)₂ triplet and Q_I?Fe²⁺ signals in the chromatophore and reconstituted reaction center membrane multilayers indicates that the reaction center is similarly oriented in both native and model membranes. The principle magnetic axes of the (BChl)₂ triplet are found to lie with the x direction approximately parallel to the plane of the membrane surface, and the z and y directions approx. 10–20° away from the plane of the membrane surface and membrane normal, respectively. The Q_I?Fe²⁺ signals are found to have the g 1.82 component positioned perpendicular to the plane of the membrane surface, with an orthogonal low-field transition (at g 1.68 in Rps. Sphaeroides and at g 1.62 in C. vinosum) lying parallel to the plane of the membrane surface. The orientation of Q_I was determined by the angular dependence of this signal in Fe²⁺-depleted reaction center reconstituted membrane multilayers, and it was found to be situated most likely with the plane of the quinone ring perpendicular to the plane of the membrane surface.     

Low-temperature optical properties and pigment organization of the B875 light-harvesting bacteriochlorophyll-protein complex of purple photosynthetic bacteria

Optical and structural properties of the B875 light-harvesting complex of purple bacteria were examined by measurements of low-temperature circular dichroism (CD) and excitation spectra of fluorescence polarization. In the B875 complex isolated from wild-type Rhodopseudomonas sphaeroides, fluorescence polarization increased steeply across the long-wavelength Q_y bacteriochlorophyll a (BChl) absorption band at both 4 and approx. 300 K. With the native complex in the photosynthetic membranes of Rhodospirillum rubrum and Rps. sphaeroides wild-type and R26-carotenoidless strains, this significant increase in polarization from 0.12 to 0.40 was only observed at low temperature. A polarization of ?0.2 was observed upon excitation in the Q_x BChl band. The results indicate that about 15% of the BChl molecules in the complex absorb at wavelengths about 12 nm longer than the other BChls. All BChls have approximately the same orientation with their Q_y transition dipoles essentially parallel and their Q_x transitions perpendicular to the plane of the membrane. At low temperature, energy transfer to the long-wavelength BChls is irreversible, yielding a high degree of polarization upon direct excitation, whereas at room temperature a partial depolarization of fluorescence by energy transfer between different subunits occurs in the membrane, but not in the isolated complex. CD spectra appear to reflect the two spectral forms of B875 BChl in Rps. sphaeroides membranes. They also reveal structural differences between the complexes of Rps. sphaeroides and Rhs. rubrum, in both BChl and carotenoid regions. The CD spectrum of isolated B875 indicates that the interactions between the BChls but not the carotenoids are altered upon isolation.     

Temporal and spectral characterization of the photosynthetic reaction center from Heliobacterium modesticaldum

A time-resolved spectroscopic study of the isolated photosynthetic reaction center (RC) from Heliobacterium modesticaldum reveals that thermal equilibration of light excitation among the antenna pigments followed by trapping of excitation and the formation of the charge-separated state P₈₀₀ ⁺A₀ ^– occurs within ~25 ps. This time scale is similar to that reported for plant and cyanobacterial photosystem I (PS I) complexes. Subsequent electron transfer from the primary electron acceptor A₀ occurs with a lifetime of ~600 ps, suggesting that the RC of H. modesticaldum is functionally similar to that of Heliobacillus mobilis and Heliobacterium chlorum. The (A₀ ^– ? A₀) and (P₈₀₀ ⁺ ? P₈₀₀) absorption difference spectra imply that an 8¹-OH-Chl a _F molecule serves as the primary electron acceptor and occupies the position analogous to ec3 (A₀) in PS I, while a monomeric BChl g pigment occupies the position analogous to ec2 (accessory Chl). The presence of an intense photobleaching band at 790 nm in the (A₀ ^– ? A₀) spectrum suggests that the excitonic coupling between the monomeric accessory BChl g and the 8¹-OH-Chl a _F in the heliobacterial RC is significantly stronger than the excitonic coupling between the equivalent pigments in PS I.     

The size of the photosynthetic unit in purple bacteria

Pigment analysis was performed by means of normal phase HPLC on a number of bacteriochlorophyll a and b containing species of purple bacteria that contain a core antenna only. At least 99% of the bacteriochlorophyll in Rhodobacter sphaeroides R26, Rhodopseudomonas viridis and Thiocapsa pfennigii was esterified with phytol (BChl a _p and BChl b _p, respectively). Rhodospirillum rubrum contained only BChl a esterified with geranyl-geraniol (BChl a _GG). Rhodospirillum sodomense and Rhodopseudomonas marina contained, in addition to BChl a _p, small amounts of BChl a _GG, and presumably also of BChl a esterified with dihydro and tetrahydro geranyl-geraniol (2,10,14-phytatrienol and probably 2,14-phytadienol). In all species bacteriopheophytin (BPhe) esterified with phytol was present. The BChl/BPhe ratio indicated that in these species a constant number of 25 ± 3 antenna BChls is present per reaction centre. This number supports a model in which the core antenna consists of 12 - heterodimers surrounding the reaction centre. Determination of the in vivo extinction coefficient of BChl in the core-reaction centre complex yielded a value of ca. 140 mM^–1 cm^–1 for BChl a containing species and of 130 mM^–1 cm^–1 for Rhodopseudomonas viridis.Abbreviations BChl bacteriochlorophyll - BPhe bacteriopheophytin - GG geranyl-geraniol - LHI and LHII core and peripheral antenna complexes - P phytol - RC reaction centre Dedicated to the memory of Professor D.I. Arnon.     

Light-induced red shift of the Qx absorption band of light-harvesting bacteriochlorophyll in Rhodopseudomonas capsulata and Rhodopseudomonas sphaeroides

In chromatophores from Rhodopseudomonas sphaeroides and Rhodopseudomonas capsulata, the Q_x band(s) of the light-harvesting bacteriochlorophyll (BChl) (λ_max ~590 nm) shifts to the red in response to a light-induced membrane potential, as indicated by the characteristics of the light-minus-dark difference spectrum. In green strains, containing light-harvesting complexes I and II, and one or more of neurosporene, methoxyneurosporene, and hydroxyneurosporene as carotenoids, the absorption changes due to the BChl and carotenoid responses to membrane potential in the spectral region 540–610 nm are comparable in magnitude and overlap with cytochrome and reaction center absorption changes in coupled chromatophores. In strains lacking carotenoid and light-harvesting complex II, the BChl shift absorption change is relatively smaller, due in part to the lower BChl/reaction center ratio.In the carotenoid-containing strains, the peak-to-trough absorption change in the BChl difference spectrum is 5–8% of the peak-to-trough change due to the shift of the longest-wavelength carotenoid band, although the absorption of the BChl band is 25–40% of that of the carotenoid band. The responding BChl band(s) does not appear to be significantly red-shifted in the dark in comparison to the total BChl Q_x band absorption.     

Engineered biosynthesis of bacteriochlorophyll b in Rhodobacter sphaeroides

Bacteriochlorophyll b has the most red-shifted absorbance maximum of all naturally occurring photopigments. It has a characteristic ethylidene group at the C8 position in place of the more common ethyl group, the product of a C8-vinyl reductase, which is carried by the majority of chlorophylls and bacteriochlorophylls used in photosynthesis. The subsequent and first step exclusive to bacteriochlorophyll biosynthesis, the reduction of the C7 = C8 bond, is catalyzed by chlorophyllide oxidoreductase. It has been demonstrated that the enzyme from bacteriochlorophyll a-utilizing bacteria can catalyze the formation of compounds carrying an ethyl group at C8 from both ethyl- and vinyl-carrying substrates, indicating a surprising additional C8-vinyl reductase function, while the enzyme from organisms producing BChl b could only catalyze C7 = C8 reduction with a vinyl substrate, but this product carried an ethylidene group at the C8 position. We have replaced the native chlorophyllide oxidoreductase-encoding genes of Rhodobacter sphaeroides with those from Blastochloris viridis, but the switch from bacteriochlorophyll a to b biosynthesis is only detected when the native conventional C8-vinyl reductase is absent. We propose a non-enzymatic mechanism for ethylidene group formation based on the absence of cellular C8-vinyl reductase activity.     

Resolved difference spectra of redox centers involved in photosynthetic electron flow in Rhodopseudomonas capsulata and rhodopseudomonas sphaeroides

1. In Rhodopseudomonas sphaeroides the Q_x absorption band of the reaction center bacteriochlorophyll dimer which bleaches on photo-oxidation is both blue-shifted and has an increased extinction coefficient on solubilisation of the chromatophore membrane with lauryldimethylamine-N-oxide. These effects may be attributable in part to the particle flattening effect.2. The difference spectrum of photo-oxidisable c type cytochrome in the chromatophore was found to have a slightly variable peak position in the α-band (λ_max at 551–551.25 nm); this position was always red-shifted in comparison to that of isolated cytochrome c₂ (λ_max at 549.5 ± 0.5 nm). The shift in wavelength maximum was not due to association with the reaction center protein. A possible heterogeneity in the c-type cytochromes of chromatophores is discussed.3. Flash-induced difference spectra attributed to cytochrome b were resolved at several different redox potentials and in the presence and absence of antimycin. Under most conditions, one major component, cytochrome b₅₀ appeared to be involved. However, in some circumstances, reduction of a component with the spectral characteristics of cytochrome b_?90 was observed.4. Difference spectra attributed to (BChl)₂, Q^?_II, c type cytochrome and cytochrome b₅₀ were resolved in the Soret region for Rhodopseudomonas capsulata.5. A computer-linked kinetic spectrophotometer for obtaining automatically the difference spectra of components functioning in photosynthetic electron transfer chains is described. The system incorporates a novel method for automatically adjusting and holding the photomultiplier supply voltage.     

Identification of the Intermediate Charge-Separated State PβL in a Leucine M214 to Histidine Mutant of the Rhodobacter sphaeroides Reaction Center Using Femtosecond Midinfrared Spectroscopy

Energy and electron transfer in a Leu M214 to His (LM214H) mutant of the Rhodobacter sphaeroides reaction center (RC) were investigated by applying time-resolved visible pump/midinfrared probe spectroscopy at room temperature. This mutant replacement of the Leu at position M214 resulted in the incorporation of a bacteriochlorophyll (BChl) in place of the native bacteriopheophytin in the L-branch of cofactors (denoted β_L). Purified LM214H RCs were excited at 600 nm (unselective excitation), at 800 nm (direct excitation of the monomeric BChl cofactors B_L and B_M), and at 860 nm (direct excitation of the primary donor (P) BChl pair (P_L/P_M)). Absorption changes associated with carbonyl (C=O) stretch vibrational modes (9-keto, 10a-ester, and 2a-acetyl) of the cofactors and of the protein were recorded in the region between 1600 cm⁻¹ and 1770 cm⁻¹, and the data were subjected to both a sequential analysis and a simultaneous target analysis. After photoexcitation of the LM214H RC, P^∗ decayed on a timescale of ∼6.3 ps to P⁺B_L⁻. The decay of P⁺B_L⁻ occurred with a lifetime of ∼2 ps, ∼3 times slower than that observed in wild-type and R-26 RCs (∼0.7 ps). Further electron transfer to the β_L BChl resulted in formation of the P⁺β_L⁻ state, and its infrared absorbance difference spectrum is reported for the first time, to our knowledge. The fs midinfrared spectra of P⁺B_L⁻ and P⁺β_L⁻ showed clear differences related to the different environments of the two BChls in the mutant RC.     

Formation and decay of radical-pair state P+I− in Chloroflexus aurantiacus reaction centers

We have examined the room temperature kinetics of the absorption changes associated with the formation of state P⁺I⁻ (P⁺BPh⁻) and its subsequent decay to state P⁺Q⁻_A in reaction centers from Chloroflexus aurantiacus. Our data, acquired using 30-ps excitation flashes, strongly suggest that formation of P⁺I⁻ (P⁺BPh⁻) takes longer in Chloroflexus than in reaction centers from Rhodopseudomonas sphaeroides. The reduction of the photoactive bacteriopheophytin (BPh) could take as long as 13 ps. Absorption changes different from those due to P⁺I⁻ are observed early in the excitation flash, but the detailed identity of the transient remains unclear. We also find that the kinetics observed subsequent to P⁺I⁻ formation differ with detection wavelength. The time constant measured in the anion band (I⁻) at 655 nm is 324 ± 20 ps and probably reflects the rate of electron transfer from I⁻ (BPh⁻) to Q_A. However, the kinetics measured in the BPh ground-state absorption bands are slightly longer: 365 ± 19 and 367 ± 21 ps at 538 and 760 nm, respectively. At 810 nm, a wavelength normally associated with the monomeric bacteriochlorophyll (BChl) in the Chloroflexus reaction center, a slightly faster (281 ± 19 ps) time constant is observed. This detection-wavelength dependence of the kinetics is similar to that observed recently in Rps. sphaeroides reaction centers. Comparison of these results suggests that the kinetics observed in the ground-state absorption bands of the BPhs and BChls in Chloroflexus may contain contributions from readjustments of the pigments and/or protein in response to the charge separation process.     

Isolation and structural determination of C8-vinyl-bacteriochlorophyll d from the bciA and bchU double mutant of the green sulfur bacterium Chlorobaculum tepidum

The mutant lacking enzymes BciA and BchU, that catalyzed reduction of the C8-vinyl group and methylation at the C20 position of bacteriochlorophyll (BChl) c, respectively, in the green sulfur bacterium Chlorobaculum tepidum, were constructed. This mutant accumulated C8-vinyl-BChl d derivatives, and a molecular structure of the major pigment was fully characterized by its NMR, mass, and circular dichroism spectra, as well as by chemical modification: (3¹ R)-8-vinyl-12-ethyl-(R[V,E])BChl d was confirmed as a new BChl d species in the cells. In vitro chlorosome-like self-aggregates of this pigment were prepared in an aqueous micellar solution, and formed more rapidly than those of (3¹ R)-8,12-diethyl-(R[E,E])BChl d isolated from the green sulfur bacterium Chlorobaculum parvum NCIB8327d synthesizing BChl d homologs. Their red-shifted Q _y absorption bands were almost the same at 761 nm, and the value was larger than those of in vitro self-aggregates of R[E,E]BChl c (737 nm) and R[V,E]BChl c (726 nm), while the monomeric states of the former gave Q _y bands at shorter wavelengths than those of the latter. Red shifts by self-aggregation of the two BChl d species were estimated to be 110 nm and much larger than those by BChls c (75 nm for [E,E] and 64 nm for [V,E]).     

Purification of the photosynthetic reaction center from <Emphasis Type="Italic">Heliobacterium modesticaldum</Emphasis>

We have developed a purification protocol for photoactive reaction centers (HbRC) from Heliobacterium modesticaldum. HbRCs were purified from solubilized membranes in two sequential chromatographic steps, resulting in the isolation of a fraction containing a single polypeptide, which was identified as PshA by LC–MS/MS of tryptic peptides. All polypeptides reported earlier as unknown proteins (in Heinnickel et al., Biochemistry 45:6756–6764, 2006; Romberger et al., Photosynth Res 104:293–303, 2010) are now identified by mass spectrometry to be the membrane-bound cytochrome c ₅₅₃ and four different ABC-type transporters. The purified PshA homodimer binds the following pigments: 20 bacteriochlorophyll (BChl) g, two BChl g′, two 8¹-OH-Chl a _F, and one 4,4′-diaponeurosporene. It lacks the PshB polypeptide binding the F_A and F_B [4Fe–4S] clusters. It is active in charge separation and exhibits a trapping time of 23 ps, as judged by time-resolved fluorescence studies. The charge recombination rate of the P₈₀₀ ⁺F_X⁻ state is 10–15 ms, as seen before. The purified HbRC core was able to reduce cyanobacterial flavodoxin in the light, exhibiting a K _M of 10 μM and a k _cat of 9.5 s⁻¹ under near-saturating light. There are ~1.6 menaquinones per HbRC in the purified complex. Illumination of frozen HbRC in the presence of dithionite can cause creation of a radical at g = 2.0046, but this is not a semiquinone. Furthermore, we show that high-purity HbRCs are very stable in anoxic conditions and even remain active in the presence of oxygen under low light.     

Electrostatic charge controls the lowest LH1 Qy transition energy in the triply extremophilic purple phototrophic bacterium,Halorhodospira halochloris

Halorhodospira (Hlr.) halochloris is a unique phototrophic purple bacterium because it is a triple extremophile—the organism is thermophilic, alkalophilic, and halophilic. The most striking photosynthetic feature of Hlr. halochloris is that the bacteriochlorophyll (BChl) b-containing core light-harvesting (LH1) complex surrounding its reaction center (RC) exhibits its LH1 Q_y absorption maximum at 1016 nm, which is the lowest transition energy among phototrophic organisms. Here we report that this extraordinarily red-shifted LH1 Q_y band of Hlr. halochloris exhibits interconvertible spectral shifts depending on the electrostatic charge distribution around the BChl b molecules. The 1016 nm band of the Hlr. halochloris LH1-RC complex was blue-shifted to 958 nm upon desalting or pH decrease but returned to its original position when supplemented with salts or pH increase. Resonance Raman analysis demonstrated that these interconvertible spectral shifts are not associated with the strength of hydrogen-bonding interactions between BChl b and LH1 polypeptides. Furthermore, circular dichroism signals for the LH1 Q_y transition of Hlr. halochloris appeared with a positive sign (as in BChl b-containing Blastochloris species) and opposite those of BChl a-containing purple bacteria, possibly due to a combined effect of slight differences in the transition dipole moments between BChl a and BChl b and in the interactions between adjacent BChls in their assembled state. Based on these findings and LH1 amino acid sequences, it is proposed that Hlr. halochloris evolved its unique and tunable light-harvesting system with electrostatic charges in order to carry out photosynthesis and thrive in its punishing hypersaline and alkaline habitat.     

Characterization of cytochrome b in the isolated ubiquinol-cytochrome c2 oxidoreductase from Rhodopseudomonas sphaeroides GA

Extinction coefficients for cytochrome b and c₁ in the isolated cytochrome bc₁ complex from Rhodopseudomonas sphaeroides GA have been determined. They are 25 mM^?1.cm^?1 at 561 nm for cytochrome b and 17.4 mM^?1.cm^?1 at 553 nM for cytochrome c₁ for the difference between the reduced and the oxidized state. Cytochrome b is present in two forms in the complex. One form has an E_m7 of 50 mV, an α-peak of 557 nm at liquid N₂ temperature and of 561 nm at RT, which is red-shifted by antimycin A. The other form has an E_m7 of ?90 mV, a double α-peak of 555 and 561 nm at liquid N₂ temperature corresponding to 559 and 566 nm at RT. The absorption at 566 nm is red-shifted by myxothiazol. The two shifts are independent of each other. Both midpoint potentials of cytochromes b are pH-dependent. The redox center compositions of the cytochrome bc₁ complexes from Rhodopseudomonas sphaeroides and from mitochondria are identical.     

The F<Subscript>X</Subscript> iron–sulfur cluster serves as the terminal bound electron acceptor in heliobacterial reaction centers

Phototrophs of the family Heliobacteriaceae contain the simplest known Type I reaction center (RC), consisting of a homodimeric (PshA)₂ core devoid of bound cytochromes and antenna proteins. Unlike plant and cyanobacterial Photosystem I in which the F_A/F_B protein, PsaC, is tightly bound to P₇₀₀–F_X cores, the RCs of Heliobacterium modesticaldum contain two F_A/F_B proteins, PshBI and PshBII, which are loosely bound to P₈₀₀–F_X cores. These two 2[4Fe–4S] ferredoxins have been proposed to function as mobile redox proteins, reducing downstream metabolic partners much in the same manner as does [2Fe–2S] ferredoxin or flavodoxin (Fld) in PS I. Using P₈₀₀–F_X cores devoid of PshBI and PshBII, we show that iron–sulfur cluster F_X directly reduces Fld without the involvement of F_A or F_B (Fld is used as a proxy for soluble redox proteins even though a gene encoding Fld is not identified in the H. modesticaldum genome). The reduction of Fld is suppressed by the addition of PshBI or PshBII, an effect explained by competition for the electron on F_X. In contrast, P₇₀₀–F_X cores require the presence of the PsaC, and hence, the F_A/F_B clusters for Fld (or ferredoxin) reduction. Thus, in H. modesticaldum, the interpolypeptide F_X cluster serves as the terminal bound electron acceptor. This finding implies that the homodimeric (PshA)₂ cores should be capable of donating electrons to a wide variety of yet-to-be characterized soluble redox partners.     

Protein-Induced Membrane Curvature Investigated through Molecular Dynamics Flexible Fitting

In the photosynthetic purple bacterium Rhodobacter (Rba.) sphaeroides, light is absorbed by membrane-bound light-harvesting (LH) proteins LH1 and LH2. LH1 directly surrounds the reaction center (RC) and, together with PufX, forms a dimeric (RC-LH1-PufX)₂ protein complex. In LH2-deficient Rba. sphaeroides mutants, RC-LH1-PufX dimers aggregate into tubular vesicles with a radius of ∼250-550 Å, making RC-LH1-PufX one of the few integral membrane proteins known to actively induce membrane curvature. Recently, a three-dimensional electron microscopy density map showed that the Rba. sphaeroides RC-LH1-PufX dimer exhibits a prominent bend at its dimerizing interface. To investigate the curvature properties of this highly bent protein, we employed molecular dynamics simulations to fit an all-atom structural model of the RC-LH1-PufX dimer within the electron microscopy density map. The simulations reveal how the dimer produces a membrane with high local curvature, even though the location of PufX cannot yet be determined uniquely. The resulting membrane curvature agrees well with the size of RC-LH1-PufX tubular vesicles, and demonstrates how the local curvature properties of the RC-LH1-PufX dimer propagate to form the observed long-range organization of the Rba. sphaeroides tubular vesicles.     

The role of the Rieske iron-sulfur center as the electron donor to ferricytochrome c2 in Rhodopseudomonas sphaeroides

The Rieske iron-sulfur center in the photosynthetic bacterium Rhodopseudomonas sphaeroides appears to be the direct electron donor to ferricytochrome c₂, reducing the cytochrome on a submillisecond timescale which is slower than the rapid phase of cytochrome oxidation ($\text{t}{}_{\mathrm{<mtext>1</mtext><mtext>2</mtext>}}\text{3–5 μ}\text{s}$). The reduction of the ferricytochrome by the Rieske center is inhibited by 5-n-undecyl-6-hydroxy-4,7-dioxobenzothiazole (UHDBT) but not by antimycin. The slower (1–2 ms) antimycin-sensitive phase of ferricytochrome c₂ reduction, attributed to a specific ubiquinone-10 molecule (Q_z), and the associated carotenoid spectral response to membrane potential formation are also inhibited by UHDBT. Since the light-induced oxidation of the Rieske center is only observed in the presence of antimycin, it seems likely that the reduced form of Q_z (Q_zH₂) reduces the Rieske center in an antimycin-sensitive reaction. From the extent of the UHDBT-sensitive ferricytochrome c₂ reduction we estimate that there are 0.7 Rieske iron-sulfur centers per reaction center.UHDBT shifts the EPR derivative absorption spectrum of the Rieske center from g_y 1.90 to g_y 1.89, and shifts the E_m,7 from 280 to 350 mV. While this latter shift may account for the subsequent failure of the iron-sulfur center to reduce ferricytochrome c₂, it is not clear how this can explain the other effects of the inhibitor, such as the prevention of cytochrome b reduction and the elimination of the uptake of H⁺_II; these may reflect additional sites of action of the inhibitor.     

The site-directed mutation I(L177)H in Rhodobacter sphaeroides reaction center affects coordination of PA and BB bacteriochlorophylls

To explore the influence of the I(L177)H single mutation on the properties of the nearest bacteriochlorophylls (BChls), three reaction centers (RCs) bearing double mutations were constructed in the photosynthetic purple bacterium Rhodobacter sphaeroides, and their properties and pigment content were compared with those of the correspondent single mutant RCs. Each pair of the mutations comprised the amino acid substitution I(L177)H and another mutation altering histidine ligand of BChl P_A or BChl B_B. Contrary to expectations, the double mutation I(L177)H + H(L173)L does not bring about a heterodimer RC but causes a 46 nm blue shift of the long-wavelength P absorbance band. The histidine L177 or a water molecule were suggested as putative ligands for P_A in the RC I(L177)H + H(L173)L although this would imply a reorientation of the His backbone and additional rearrangements in the primary donor environment or even a repositioning of the BChl dimer. The crystal structure of the mutant I(L177)H reaction center determined to a resolution of 2.9 Å shows changes at the interface region between the BChl P_A and the monomeric BChl B_B. Spectral and pigment analysis provided evidence for β-coordination of the BChl B_B in the double mutant RC I(L177)H + H(M182)L and for its hexacoordination in the mutant reaction center I(L177)H. Computer modeling suggests involvement of two water molecules in the β-coordination of the BChl B_B. Possible structural consequences of the L177 mutation affecting the coordination of the two BChls P_A and B_B are discussed. This article is part of a Special Issue entitled: Photosynthesis Research for Sustainability: from Natural to Artificial.     

Effects of light intensity on membrane differentiation in Rhodopseudomonas capsulata

Cells of Rhodopseudomonas capsulata, strain 37b4, leu^?, precultivated anaerobically under low light intensity, were exposed to high light intensity (2000 W · m^?2). The cells grew with a mass doubling time of 3 h. The synthesis of bacteriochlorophyll (BChl) began after two doublings of cell mass. Reaction center and light-harvesting BChl I (B-875) were the main constituents of the photosynthetic apparatus incorporated into the membrane. The size of the photosynthetic unit (total BChl/reaction center) decreased and light-harvesting BChl I became the dominating BChl species. Concomitant with the appearance of the different spectral forms of BChl the respective proteins were incorporated into the membrane, i.e. the three reaction center polypeptides, the polypeptide associated with light-harvesting BChl I, the two polypeptides associated with BChl II. A polypeptide of an apparent molecular weight of 45 000 was also incorporated. A lowering of the light intensity to 7 W · m^?2 resulted in a lag phase of growth for 6 h. Afterwards, the time for doubling of cell mass was 11 h. The concentration of all three BChl complexes (reaction center, light-harvesting BChl I and II complexes)/cell and per membrane protein increased immediately. Also the size of the photosynthetic unit and the amount of intracytoplasmic membranes/cell increased.The activities of photophosphorylation, succinate dehydrogenase, NADH dehydrogenase and NADH oxidation (respiratory chain)/membrane protein are higher in membrane preparations isolated from cells grown at high light intensities than in such preparations from cells grown at low light intensities.