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This article was the subject of a Wiki Education Foundation-supported course assignment, between 17 January 2022 and 1 May 2022. Further details are available on the course page. Student editor(s): Rachelkr24 (article contribs). Peer reviewers: Weile112, Pjaml, Glshobert, Aflucke.
Wiki Education Foundation-supported course assignment
This article was the subject of a Wiki Education Foundation-supported course assignment, between 23 September 2020 and 14 December 2020. Further details are available on the course page. Student editor(s): Peterju2. Peer reviewers: Lia adroli.
Above undated message substituted from Template:Dashboard.wikiedu.org assignment by PrimeBOT (talk) 17:23, 17 January 2022 (UTC)
Cyclic electron transport, etc
I highly doubt it's the SAME electron that recombines with P840, etc. The hole will likely be filled almost immediately before that electron completes the chain (primary donor should be S or Fe). In fact, it's likely a chain reaction of electron transfers at the appropriate energy levels. Perhaps the simple explanation is more understandable though.
As to the restriction to cyclic electron flow - I believe the terminal electron acceptor is CO2 (after Cytochromes, Quinones and NADPH) so where's the cycle? Perhaps I'm incorrect or missing the point here as well. AFAIK, FAPs can grow photomixotrophically, so they should be able to fix carbon. GSBs definitely should be able to fix carbon - there's no supplied carbon source aside from calcium carbonate (which is just dissolved CO2) in the media.
I don't know if there's an intrinsic restriction on PSII not being able to split water in the absence of PSI. My impression was the little buggers would never want to invest in the extra C-terminal domain protein if it ended up producing a toxin for their growth - most of these guys shy away from oxygen. Additionally, isn't producing oxygen a "waste of energy?" (I'd have to look again at my energy diagrams for delta G/E) There'd be no selective advantage (besides killing your neighbors with oxygen toxicity) to re-inventing the water-splitting wheel. Obviously if they split water into oxygen, they would, by definition no longer be anoxygenic phototrophs.
Pagelm (talk) 04:01, 5 April 2012 (UTC)
Retinalophototrophy not a word
This article has a passage that Wikilinks to "Bacterial rhodopsins" piped to "rhodopsin-based retinalophototrophy." The problem is that there is nothing in the "Bacterial rhodopsins" article that discusses "retinalophototrophy." Furthermore, the word "retinalophototrophy" gets no hits on Google Scholar. On Google Search it gets hits, but mainly to the entire sentence found here, suggesting those hits are just quoting this article. The exception is some dissertations, which don't carry a lot of weight. I would like to recommend using more widely recognized terminology. Zyxwv99 (talk) 22:17, 4 October 2015 (UTC)
Retinalophototrophy was a term used by D. Bryant (and/or D. Ward) in lectures and seminars circa 2010 - especially to distinguish it from chlorophototrophy. My apologies for using a word not entered into the peer-reviewed literature. Pagelm (talk) 19:55, 5 October 2016 (UTC)
Figure 1 Kreb's cycle should be Calvin Cycle
The Kreb's cycle (a.k.a. the Citric acid cycle) oxidizes acetyl-CoA to CO2. It is the Calvin Cycle that reduces CO2 into sugar.
- Not exactly. Some anoxygenic phototrophic bacteria use Calvin cycle (the same as in plants), but green sulfur bacteria use the inverse citric acid cycle (not the normal citric acid cycle nor the Calvin cycle), and Chloroflexus uses the hydroxypropionate pathway.--Miguelferig (talk) 17:35, 22 July 2020 (UTC)
segnalazione di errore
nella figura 1 si parla di ciclo di krebbs ma deve essere scritto Calvin 93.57.250.128 (talk) 08:03, 25 October 2023 (UTC)