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O(2) and Other High-Energy Molecules in Photosynthesis: Why Plants Need Two Photosystems

The energetics of photosynthesis in plants have been re-analyzed in a framework that represents the relatively high energy of O(2) correctly. Starting with the photon energy exciting P680 and “loosening an electron”, the energy transfer and electron transport are represented in a comprehensive, self...

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Detalles Bibliográficos
Autor principal: Schmidt-Rohr, Klaus
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2021
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8621363/
https://www.ncbi.nlm.nih.gov/pubmed/34833066
http://dx.doi.org/10.3390/life11111191
Descripción
Sumario:The energetics of photosynthesis in plants have been re-analyzed in a framework that represents the relatively high energy of O(2) correctly. Starting with the photon energy exciting P680 and “loosening an electron”, the energy transfer and electron transport are represented in a comprehensive, self-explanatory sequence of redox energy transfer and release diagrams. The resulting expanded Z-scheme explicitly shows charge separation as well as important high-energy species such as O(2), Tyr(Z)˙, and P680(+)˙, whose energies are not apparent in the classical Z-scheme of photosynthesis. Crucially, the energetics of the three important forms of P680 and of P700 are clarified. The relative free energies of oxidized and reduced species are shown explicitly in kJ/mol, not encrypted in volts. Of the chemical energy produced in photosynthesis, more is stored in O(2) than in glucose. The expanded Z-scheme introduced here provides explanatory power lacking in the classical scheme. It shows that P680* is energetically boosted to P680(+)˙ by the favorable electron affinity of pheophytin and that Photosystem I (PSI) has insufficient energy to split H(2)O and produce O(2) because P700* is too easily ionized. It also avoids the Z-scheme’s bewildering implication, according to the “electron waterfall” concept, that H(2)O gives off electrons that spontaneously flow to chlorophyll while releasing energy. The new analysis explains convincingly why plants need two different photosystems in tandem: (i) PSII mostly extracts hydrogen from H(2)O, producing PQH(2) (plastoquinol), and generates the energetically expensive product O(2); this step provides little energy directly to the plant; (ii) PSI produces chemical energy for the organism, by pumping protons against a concentration gradient and producing less reluctant hydrogen donors. It also documents that electron transport and energy transfer occur in opposite directions and do not involve redox voltages. The analysis makes it clear that the high-energy species in photosynthesis are unstable, electron-deficient species such as P680(+)˙ and Tyr(Z)˙, not putative high-energy electrons.