Investigation of the redox interaction between Mn-bicarbonate complexes and reaction centers from Rhodobacter sphaeroides R-26, Chromatium minutissimum, and Chloroflexus aurantiacus.

The change in the dark reduction rate of photooxidized reaction centers (RC) of type II from three anoxygenic bacteria (Rhodobacter sphaeroides R-26, Chromatium minutissimum, and Chloroflexus aurantiacus) having different redox potentials of the P(+)/P pair and availability of RC for exogenous electron donors was investigated upon the addition of Mn(2+) and HCO(3)(-). It was found that the dark reduction of P(870)(+) from Rb. sphaeroides R-26 is considerably accelerated upon the combined addition of 0.5 mM MnCl(2) and 30-75 mM NaHCO(3) (as a result of formation of "low-potential" complexes [Mn(HCO(3))(2)]), while MnCl(2) and NaHCO(3) added separately had no such effect. The effect is not observed either in RC from Cf. aurantiacus (probably due to the low oxidation potential of the primary electron donor, P(865), which results in thermodynamic difficulties of the redox interaction between P(865)(+) and Mn(2+)) or in RC from Ch. minutissimum (apparently due to the presence of the RC-bound cytochrome preventing the direct interaction between P(870)(+) and Mn(2+)). The absence of acceleration of the dark reduction of P(870)(+) in the RC of Rb. sphaeroides R-26 when Mn(2+) and HCO(3)(-) were replaced by Mg(2+) or Ca(2+) and by formate, oxalate, or acetate, respectively, reveals the specificity of the Mn2+-bicarbonate complexes for the redox interaction with P(+). The results of this work might be considered as experimental evidence for the hypothesis of the participation of Mn(2+) complexes in the evolutionary origin of the inorganic core of the water oxidizing complex of photosystem II.

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.

Circular dichroism of bacteriochlorophyll a in light harvesting bacteriochlorophyll protein complexes from Chromatium vinosum.

Bacteriochlorophyll (Bchl) protein complexes containing light harvesting (LH) Bchls were isolated from Chromatium vinosum, and their CD spectra were measured in the near-infrared region. These isolated Bchl protein complexes retained the CD signals of LH Bchls that were observed in situ in chromatophores. The CD spectrum of fraction A (containing B890) consisted of paired positive and negative bands (a double CD) having a zero-crossing at 800 nm and a single negative band at around 900 nm attributed to the B890. For low 850 fraction B (B800 and B850), a double CD having a zero-crossing at 795 nm and a single negative band at around 850 nm attributed to the B850 were found. High 850 fraction B exhibited a double CD having a zero-crossing at 795 nm, a negative band at around 860 nm and a positive band at around 840 nm. For fraction C (B800 and B820), a double CD having a zero-crossing at 795 nm and a single negative band at around 830 nm, which was attributed to the B820, were found. The double CD was attributed to the B800 in fractions A, B, and C. There was no additional CD besides the CD of the isolated Bchl protein complexes in the CD spectra of chromatophores.

[Effect of light intensity on the content of bacteriochlorophyll and on the growth of phototrophic marine sulfur bacteria]. / Influence de l'intensité lumineuse sur la teneur en bactériochlorophylle et sur la croissance de sulfobactéries phototrophes marines.

Eight strains of Chromatiaceae isolated from marine sediments are cultivated under light intensities of 50-5000 lx. A decreased in the light intensity brings about an increase in the specific bacteriochlorophyll content and also in the length of development. In certain strains, the increase in pigment contents partly compensates for the loss in light intensity, up to the maximum concentration of bacteriochlorophyll. This mechanism is only a physiological compatibility which ensures the survival of these organisms under feeble light intensities.

The effects of uncoupler on the rates of cytochrome oxidation and reduction in the photosynthetic bacterium, Chromatium. Evidence for a possible cytochrome switching.

The uncoupler, m-chlorocarbonyl cyanide phenylhydrazone (CCCP) added to anerobic, dark-adapted whole cells of Chromatium vinosum is found to speed the reduction of cytochrome after oxidation by laser or by steady illumination and, subject to unknown factors, to slow the laser-induced oxidation. There is considerable evidence, including spectra and loss of low-temperature oxidizability that this results from a switch of the identity of the cytochrome oxidized from the low-potential cytochrome c-552 to the high-potential cytochrome c555. Redox control and/or control by conformational movements of the cytochromes, either being coupled to energy transduction in the cyclic system, are suggested as mechanisms for the switching. If the switching hypothesis is not accepted, the increased rate of reduction could alternatively be explained by postulating a phosphorylation site in the reduction pathway.

Light-induced generation of electric potential difference in membranes of purple and green sulfur bacteria.

When associated with a planar phospholipid membrane, chromatophores isolated from photosynthetic sulfur bacteria Chromatium minutissimum, Ectothiorhodospira shaposhnikovii, and Chlorobium limicola f. thiosulfatophilum were shown to generate a light-induced transmembrane electric potential difference measured by a direct method using macroelectrodes and a voltmeter. The maximal photoelectric responses were observed upon the addition of 1,4-naphthoquinone in combination with phenazine methosulfate (or TMPD) and ascorbate. The photoeffects were inhibited by CCCP and gramicidin. The data demonstrate that similar mechanisms of photoelectric generation function in membranes of the different bacteria studied.

Triplet states of bacteriochlorophyll and carotenoids in chromatophores of photosynthetic bacteria.

Chromatophores from photosynthetic bacteria were excited with flashes lasting approx. 15 ns. Transient optical absorbance changes not associated with the photochemical electron-transfer reactions were interpreted as reflecting the conversion of bacteriochlorophyll or carotenoids into triplet states. Triplet states of various carotenoids were detected in five strains of bacteria; triplet states of bacteriochlorophyll, in two strains that lack carotenoids. Triplet states of antenna pigments could be distinguished from those of pigments specifically associated with the photochemical reaction centers. Antenna pigments were converted into their triplet states if the photochemical apparatus was oversaturated with light, if the primary photochemical reaction was blocked by prior chemical oxidation of P-870 or reduction of the primary electron acceptor, or if the bacteria were genetically devoid of reaction centers. Only the reduction of the electron acceptor appeared to lead to the formation of triplet states in the reaction centers. In the antenna bacteriochlorophyll, triplet states probably arise from excited singlet states by intersystem crossing. The antenna carotenoid triplets probably are formed by energy transfer from triplet antenna bacteriochlorophyll. The energy transfer process has a half time of approx. 20 ns, and is about 1 X 10(3) times more rapid than the reaction of the bacteriochlorophyll triplet states with O2. This is consistent with a role of carotenoids in preventing the formation of singlet O2 in vivo. In the absence of carotenoids and O2, they decay half times of the triplet states are 70 mus for the antenna bacteriochlorophyll and 6-10 mus for the reaction center bacteriochlorophyll. The carotenoid triplets decay with half times of 2-8 mus. With eak flashes, the quantum yields of the antenna triplet states are in the order of 0.02. The quantum yields decline severely after approximately one triplet state is formed per photosynthetic unit, so that even extremely strong flashes convert only a very small fraction of the antenna pigments into triplet states. The yield of fluorescence from the antenna bacteriochlorophyll declines similarly. These observations can be explained by the proposal that single-triplet fusion causes rapid quenching of excited single states in the antenna bacteriochlorophyll.