Characterization of mercury(II)-induced inhibition of photochemistry in the reaction center of photosynthetic bacteria.

Characterization of mercury(II)-induced inhibition of photochemistry in the reaction center of photosynthetic bacteria.

Mercuric contamination of aqueous cultures results in impairment of viability of photosynthetic bacteria primarily by inhibition of the photochemistry of the reaction center (RC) protein. Isolated reaction centers (RCs) from Rhodobacter sphaeroides were exposed to Hg(2+) ions up to saturation concen...

Teljes leírás

Elmentve itt :
Bibliográfiai részletek
Szerzők: Sipka Gábor
Kis Mariann
Maróti Péter
Dokumentumtípus: Cikk
Megjelent: 2018
Sorozat:PHOTOSYNTHESIS RESEARCH 136 No. 3
doi:10.1007/s11120-017-0474-8

mtmt:3310856
Online Access:http://publicatio.bibl.u-szeged.hu/17101
Leíró adatok
Tartalmi kivonat:Mercuric contamination of aqueous cultures results in impairment of viability of photosynthetic bacteria primarily by inhibition of the photochemistry of the reaction center (RC) protein. Isolated reaction centers (RCs) from Rhodobacter sphaeroides were exposed to Hg(2+) ions up to saturation concentration (~ 10(3) [Hg(2+)]/[RC]) and the gradual time- and concentration-dependent loss of the photochemical activity was monitored. The vast majority of Hg(2+) ions (about 500 [Hg(2+)]/[RC]) had low affinity for the RC [binding constant Kb ~ 5 mM(-1)] and only a few (~ 1 [Hg(2+)]/[RC]) exhibited strong binding (Kb ~ 50 muM(-1)). Neither type of binding site had specific and harmful effects on the photochemistry of the RC. The primary charge separation was preserved even at saturation mercury(II) concentration, but essential further steps of stabilization and utilization were blocked already in the 5 < [Hg(2+)]/[RC] < 50 range whose locations were revealed. (1) The proton gate at the cytoplasmic site had the highest affinity for Hg(2+) binding (Kb ~ 0.2 muM(-1)) and blocked the proton uptake. (2) Reduced affinity (Kb ~ 0.05 muM(-1)) was measured for the mercury(II)-binding site close to the secondary quinone that resulted in inhibition of the interquinone electron transfer. (3) A similar affinity was observed close to the bacteriochlorophyll dimer causing slight energetic changes as evidenced by a ~ 30 nm blue shift of the red absorption band, a 47 meV increase in the redox midpoint potential, and a ~ 20 meV drop in free energy gap of the primary charge pair. The primary quinone was not perturbed upon mercury(II) treatment. Although the Hg(2+) ions attack the RC in large number, the exertion of the harmful effect on photochemistry is not through mass action but rather a couple of well-defined targets. Bound to these sites, the Hg(2+) ions can destroy H-bond structures, inhibit protein dynamics, block conformational gating mechanisms, and modify electrostatic profiles essential for electron and proton transfer.
Terjedelem/Fizikai jellemzők:379-392
ISSN:0166-8595

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