Why Photosystem II first before Photosystem I?
Another student asked me why is it that the flow of energized electron proceeds from PSII to PSI in the light dependent reaction of photosynthesis. I threw the question back to them and some answers were unfounded. Like for example, someone said it's because two factors are affected by light in PS II, the water and the chlorophyll whereas in PS I, it was just the chlorophyll.
Being a generalist again, I said well, that was a very relevant question, let's see what literatures tell us about that. Here's what I've got:
"It was just that photosystem I was discovered before Photosystem II."
The details are as follows:
For oxygenic photosynthesis, both photosystems I and II are required.
Oxygenic photosynthesis can be performed by plants and cyanobacteria which are believed to be the progenitors of the photosystem-containing chloroplasts of eukaryotes. Photosynthetic bacteria which cannot produce oxygen have a single photosystem called BRC, bacterial reaction center.
((((Historically photosystem I was named "I" since it was discovered before photosystem II, but this does not represent the order of the electron flow.))))))
When photosystem II absorbs light, electrons in the reaction-center chlorophyll are excited to a higher energy level and are trapped by the primary electron acceptors.
To replenish the deficit of electrons, electrons are extracted from water by a cluster of four Manganese ions in photosystem II and supplied to the chlorophyll via a redox-active tyrosine.
Photoexcited electrons travel through the cytochrome b6f complex to photosystem I via an electron transport chain set in the thylakoid membrane.
This energy fall is harnessed, (the whole process termed chemiosmosis), to transport hydrogen (H+) through the membrane, to the lumen, to provide a proton-motive force to generate ATP.
The protons are transported by the plastoquinone. If electrons only pass through once, the process is termed noncyclic photophosphorylation.
When the electron reaches photosystem I, it fills the electron deficit of the reaction-center chlorophyll of photosystem I.
The deficit is due to photo-excitation of electrons which are again trapped in an electron acceptor molecule, this time that of photosystem I.
ATP is generated when the ATP synthetase transports the protons present in the lumen to the stroma, through the membrane.
The electrons may either continue to go through cyclic electron transport around PS I, or pass, via ferredoxin, to the enzyme NADP+ reductase.
Electrons and hydrogen ions are added to NADP+ to form NADPH. This reducing agent is transported to the Calvin cycle to react with glycerate 3-phosphate, along with ATP to form glyceraldehyde 3-phosphate, the basic building block from which plants can make a variety of substances.
click the links below for more =
http://en.wikipedia.org/wiki/Photosystem
Being a generalist again, I said well, that was a very relevant question, let's see what literatures tell us about that. Here's what I've got:
"It was just that photosystem I was discovered before Photosystem II."
The details are as follows:
For oxygenic photosynthesis, both photosystems I and II are required.
Oxygenic photosynthesis can be performed by plants and cyanobacteria which are believed to be the progenitors of the photosystem-containing chloroplasts of eukaryotes. Photosynthetic bacteria which cannot produce oxygen have a single photosystem called BRC, bacterial reaction center.
((((Historically photosystem I was named "I" since it was discovered before photosystem II, but this does not represent the order of the electron flow.))))))
When photosystem II absorbs light, electrons in the reaction-center chlorophyll are excited to a higher energy level and are trapped by the primary electron acceptors.
To replenish the deficit of electrons, electrons are extracted from water by a cluster of four Manganese ions in photosystem II and supplied to the chlorophyll via a redox-active tyrosine.
Photoexcited electrons travel through the cytochrome b6f complex to photosystem I via an electron transport chain set in the thylakoid membrane.
This energy fall is harnessed, (the whole process termed chemiosmosis), to transport hydrogen (H+) through the membrane, to the lumen, to provide a proton-motive force to generate ATP.
The protons are transported by the plastoquinone. If electrons only pass through once, the process is termed noncyclic photophosphorylation.
When the electron reaches photosystem I, it fills the electron deficit of the reaction-center chlorophyll of photosystem I.
The deficit is due to photo-excitation of electrons which are again trapped in an electron acceptor molecule, this time that of photosystem I.
ATP is generated when the ATP synthetase transports the protons present in the lumen to the stroma, through the membrane.
The electrons may either continue to go through cyclic electron transport around PS I, or pass, via ferredoxin, to the enzyme NADP+ reductase.
Electrons and hydrogen ions are added to NADP+ to form NADPH. This reducing agent is transported to the Calvin cycle to react with glycerate 3-phosphate, along with ATP to form glyceraldehyde 3-phosphate, the basic building block from which plants can make a variety of substances.
click the links below for more =
http://en.wikipedia.org/wiki/Photosystem
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