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'''Anoxygenic photosynthesis''' is the metabolic process of reducing carbon without producing oxygen. Though such organisms require niche ecological conditions to thrive, the community of anoxygenic phototrophs is diverse. [[Bacteria]] that can do anoxygenic photosynthesis employ a variety of strategies with differing photosynthetic complexes and [[Biological pigment|pigments]]<ref name=":0">{{Cite journal|last=Johnston|first=D. T.|last2=Wolfe-Simon|first2=F.|last3=Pearson|first3=A.|last4=Knoll|first4=A. H.|date=2009-09-28|title=Anoxygenic photosynthesis modulated Proterozoic oxygen and sustained Earth's middle age|url=http://dx.doi.org/10.1073/pnas.0909248106|journal=Proceedings of the National Academy of Sciences|volume=106|issue=40|pages=16925–16929|doi=10.1073/pnas.0909248106|issn=0027-8424}}</ref>. Studies suggest that anoxygenic photosynthesis was the first anabolic process of harnessing solar energy to evolve<ref>{{Cite journal|last=Mulkidjanian|first=Armen Y.|last2=Koonin|first2=Eugene V.|last3=Makarova|first3=Kira S.|last4=Mekhedov|first4=Sergey L.|last5=Sorokin|first5=Alexander|last6=Wolf|first6=Yuri I.|last7=Dufresne|first7=Alexis|last8=Partensky|first8=Frédéric|last9=Burd|first9=Henry|last10=Kaznadzey|first10=Denis|last11=Haselkorn|first11=Robert|date=2006|title=The Cyanobacterial Genome Core and the Origin of Photosynthesis|url=https://www.jstor.org/stable/30050725|journal=Proceedings of the National Academy of Sciences of the United States of America|volume=103|issue=35|pages=13126–13131|issn=0027-8424}}</ref>. Certain organisms were likely utilizing anoxygenic photosynthesis 3 billion years ago when the planet had extremely low levels of oxygen and organisms thrived under [[Redox|reduced]] conditions. Anoxygenic phototrophs contain photosynthetic enzymes called Reaction Centers (RC) 1 and 2. RC 1 and 2 are the ancient analogs to [[Photosynthesis|Photosystem I and II]] found in oxygenic phototrophs and likely evolved in sequence as the availability of FeS became more limited and the planet more [[Redox|oxidized]]<ref name=":0" />.
'''Anoxygenic photosynthesis''' is the metabolic process of reducing [[carbon]] without producing [[oxygen]]. The community of anoxygenic phototrophs is diverse even though such organisms require niche ecological conditions to thrive. Anoxygenic photosynthesizing [[bacteria]] employ a variety of strategies with differing photosynthetic complexes and [[Biological pigment|pigments]].<ref name=":0">{{Cite journal|last=Johnston|first=D. T.|last2=Wolfe-Simon|first2=F.|last3=Pearson|first3=A.|last4=Knoll|first4=A. H.|date=2009-09-28|title=Anoxygenic photosynthesis modulated Proterozoic oxygen and sustained Earth's middle age|url=http://dx.doi.org/10.1073/pnas.0909248106|journal=Proceedings of the National Academy of Sciences|volume=106|issue=40|pages=16925–16929|doi=10.1073/pnas.0909248106|issn=0027-8424}}</ref> Studies suggest that anoxygenic photosynthesis was the first anabolic process of harnessing solar energy to evolve.<ref>{{Cite journal|last=Mulkidjanian|first=Armen Y.|last2=Koonin|first2=Eugene V.|last3=Makarova|first3=Kira S.|last4=Mekhedov|first4=Sergey L.|last5=Sorokin|first5=Alexander|last6=Wolf|first6=Yuri I.|last7=Dufresne|first7=Alexis|last8=Partensky|first8=Frédéric|last9=Burd|first9=Henry|last10=Kaznadzey|first10=Denis|last11=Haselkorn|first11=Robert|date=2006|title=The Cyanobacterial Genome Core and the Origin of Photosynthesis|url=https://www.jstor.org/stable/30050725|journal=Proceedings of the National Academy of Sciences of the United States of America|volume=103|issue=35|pages=13126–13131|issn=0027-8424}}</ref> Certain organisms were likely utilizing anoxygenic photosynthesis 3 billion years ago when the planet had extremely low levels of oxygen and organisms thrived under [[Redox|reduced]] conditions. Anoxygenic phototrophs contain one of two enzymes called Reaction Centers (RC) 1 and 2. RC 1 and 2 are the ancient analogs to [[Photosynthesis|Photosystem I and II]] found in oxygenic phototrophs and likely evolved in sequence as the availability of [[Iron(II) sulfide|Iron (II) Sulfide (FeS)]] became more limited and the planet more [[Redox|oxidized]].<ref name=":0" />


== Organisms ==
== Molecular structure ==
[[File:Green Sulfur Bacteria Image.png|thumb|Green Sulfur Bacteria]]

=== Bacteria ===
While oxygenic photosynthesis only exists in one bacteria phylum Cyanobacteria, anoxygenic photosynthesis is widespread in bacteria<ref name=":1">{{Cite journal|last=Hanada|first=Satoshi|date=2016-3|title=Anoxygenic Photosynthesis —A Photochemical Reaction That Does Not Contribute to Oxygen Reproduction—|url=https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4791109/|journal=Microbes and Environments|volume=31|issue=1|pages=1–3|doi=10.1264/jsme2.ME3101rh|issn=1342-6311|pmc=4791109|pmid=27021204}}</ref>. Some examples of bacteria phylum that can utilize anoxygenic photosynthesis are Chlorobi, Chloroflexi, Acidobacteria, and Heliobacterium<ref name=":2">{{Cite web|title=Green Sulfur Bacteria - an overview {{!}} ScienceDirect Topics|url=https://www.sciencedirect.com/topics/agricultural-and-biological-sciences/green-sulfur-bacteria#:~:text=Green%20sulfur%20bacteria|access-date=2020-11-08|website=www.sciencedirect.com}}</ref><ref name=":1" /><ref>{{Cite web|title=Photoheterotrophs - an overview {{!}} ScienceDirect Topics|url=https://www.sciencedirect.com/topics/agricultural-and-biological-sciences/photoheterotrophs|access-date=2020-11-08|website=www.sciencedirect.com}}</ref>.

Within each phylum there are many bacteria that do not rely on anoxygenic photosynthesis for ATP production, and the ones that do go about its production in unique ways. Various anoxic bacteria use different chemicals and compounds as electron donors. [[Green sulfur bacteria|Green Sulfur Bacteria]] (phyla: Chlorobi) utilize sulfur or sulfide instead of water <ref name=":2" /><ref name=":3">{{Cite web|title=Green Sulfur Bacteria - an overview {{!}} ScienceDirect Topics|url=https://www.sciencedirect.com/topics/agricultural-and-biological-sciences/green-sulfur-bacteria#:~:text=Green%20sulfur%20bacteria%20(the%20family,clustering%20separately%20from%20marine%20strains.|access-date=2020-11-08|website=www.sciencedirect.com}}</ref>. Other species of Green Bacteria such as Filamentous Anoxygenic Phototrophic Bacteria (Green Non-sulfur Bacteria), use thiosulfate, molecular hydrogen, or reduced iron as their electron donors<ref name=":3" /><ref name=":1" />. Most anoxygenic phototrophs use one or multiple of the listed electron donors and the specific electron donor used is dependent on the type of pigment and reaction centers employed by the specific bacteria.
[[File:Purple Bacteria Image.png|thumb|Purple Bacteria]]
[[Green sulfur bacteria|Green Sulfur Bacteria]] use [[bacteriochlorophyll]] (Bchl) c, d, or e which is what gives them their green color<ref name=":2" />. On the other side, (anoxygenic) [[Purple bacteria|Purple Bacteria]] use bacteriochlorophyll a or b which gives them their red-purplish color<ref name=":4">{{Citation|last=Imhoff|first=Johannes F.|title=Anoxygenic Phototrophic Purple Bacteria|date=2005|url=https://doi.org/10.1007/0-387-28021-9_15|work=Bergey’s Manual® of Systematic Bacteriology: Volume Two: The Proteobacteria, Part A Introductory Essays|pages=119–132|editor-last=Brenner|editor-first=Don J.|place=Boston, MA|publisher=Springer US|language=en|doi=10.1007/0-387-28021-9_15|isbn=978-0-387-28021-9|access-date=2020-11-09|last2=Hiraishi|first2=Akira|last3=Süling|first3=Jörg|editor2-last=Krieg|editor2-first=Noel R.|editor3-last=Staley|editor3-first=James T.|editor4-last=Garrity|editor4-first=George M.}}</ref>. There are also the [[Green non-sulfur bacteria|Green Non-sulfur Bacteria]] which use similar bacteriochlorophyll as Green Sulfur Bacteria but use RC2 like Purple Bacteria<ref name=":4" /><ref name=":1" />. Some [[cyanobacteria]] can do both anoxygenic and oxygenic photosynthesis. When these organisms are in an environment with abundant sulfur, they will preferentially oxidize sulfide rather than water. This is because sulfide is more thermodynamically favorable. Cyanobacteria will temporarily turn off PSII and utilize the reaction centers.<ref name=":0" />

A similar phenomenon was observed in a study by Shiba et al 1979. They isolated a subclass of the Proteobacteria from oxic conditions and documented their ability to synthesize Bchl-a in the presence of oxygen and carry out photosynthesis under oxic conditions, but not produce oxygen in the process. This bacteria are part of a different category of aerobic anoxygenic photosynthetic bacteria. (Harashima et al. 1989; Yurkov and Beatty1998). [2aw]

[[Heliobacteria]] are also [[Nitrogen fixation|nitrogen fixers]]. They are similar to Green Sulfur Bacteria in that they conduct a type 1 photosynthesis reaction (RC1), except they use bacteriochlorophyll g unlike any other bacterium<ref name=":2" /><ref>{{Cite journal|last=Gest|first=Howard|last2=Favinger|first2=Jeffrey L.|date=1983-10-01|title=Heliobacterium chlorum, an anoxygenic brownish-green photosynthetic bacterium containing a “new” form of bacteriochlorophyll|url=https://doi.org/10.1007/BF00415602|journal=Archives of Microbiology|language=en|volume=136|issue=1|pages=11–16|doi=10.1007/BF00415602|issn=1432-072X}}</ref>.  

=== Archaea ===
Some [[archaea]] (e.g. ''[[Halobacterium]]'') capture light energy for metabolic function and are thus phototrophic but none are known to "fix" carbon (i.e. be photosynthetic). Instead of a chlorophyll-type receptor and electron transport chain, proteins such as halorhodopsin capture light energy with the aid of [[Diterpene|diterpenes]] to move ions against the gradient and produce [[Adenosine triphosphate|ATP]] via [[chemiosmosis]] in the manner of mitochondria.

== Function ==


=== Pigments ===
=== Pigments ===
The pigments used to carry out anaerobic photosynthesis are similar to [[chlorophyll]] but differ in molecular detail and peak wavelength of light absorbed. [[Bacteriochlorophyll|Bacteriochlorophylls]] ''a'' through ''g'' absorb electromagnetic radiation maximally in the [[near-infrared]] within their natural membrane milieu. This differs from chlorophyll a, the predominant plant and [[cyanobacteria]] pigment, which has peak absorption wavelength approximately 100 nanometers shorter (in the red portion of the visible spectrum).
The pigments used to carry out anaerobic photosynthesis are similar to [[chlorophyll]] but differ in molecular detail and peak wavelength of light absorbed. [[Bacteriochlorophyll|Bacteriochlorophylls]] (Bchl) ''a'' through ''g'' absorb electromagnetic radiation maximally in the [[near-infrared]] within their natural membrane milieu. This differs from [[Chlorophyll a|chlorophyll ''a'']], the predominant plant and [[cyanobacteria]] pigment, which has peak absorption wavelength approximately 100 nanometers shorter (in the red and blue portion of the visible spectrum).


=== Reaction Centers ===
=== Reaction Centers ===
[[File:Anoxygenic Photosynthesis in Green Sulfur Bacteria.svg|thumb|Example of Anoxygenic Photosynthesis (in Green Sulfur Bacteria)]]
[[File:Anoxygenic Photosynthesis in Green Sulfur Bacteria.svg|thumb|Example of Anoxygenic Photosynthesis (in Green Sulfur Bacteria)]]
There are two main types of anaerobic photosynthetic electron transport chains in bacteria. The type I reaction centers (RC1) found in GSB, Chloracidobacterium, and Heliobacteria and the type II reaction centers (RC2) found in [[Chloroflexi (class)|FAPs]] and purple bacteria. RC1 uses low-potential FeS clusters as electron acceptors to reduce NADP+ to NADPH. RC2 uses quinones as the ultimate electron acceptor and is similar to PSII, but without the oxygen-evolving complex.
There are two main types of anaerobic photosynthetic electron transport chains in bacteria. The type I reaction centers (RC1) are found in [[green sulfur bacteria]], [[Chloracidobacterium]]. The type II reaction centers (RC2) are found in [[Chloroflexi (class)|FAPs]] and [[purple bacteria]]. RC1 uses low-potential FeS clusters as electron acceptors to reduce NADP+ to NADPH. RC2 receives electrons from small soluble proteins such as cytochrome ''c'', cupredoxins and ferredoxins. RC2 uses electron donors such as ferrous iron, reduced sulfur compounds, and molecular hydrogen. It is similar to Photosystem II (PSII), but without the oxygen-evolving complex.<ref>{{Cite journal|last=Fischer|first=Woodward W.|last2=Hemp|first2=James|last3=Johnson|first3=Jena E.|date=2015-09|title=Manganese and the Evolution of Photosynthesis|url=http://link.springer.com/10.1007/s11084-015-9442-5|journal=Origins of Life and Evolution of Biospheres|language=en|volume=45|issue=3|pages=351–357|doi=10.1007/s11084-015-9442-5|issn=0169-6149}}</ref> Detailed below are the reaction centers found in green sulfur bacteria and purple bacteria.


The electron transport chain of green sulfur bacteria, present in model organism, ''Chlorobaculum tepidum'' — uses the reaction center bacteriochlorophyll pair, P840. When light is absorbed by the reaction center, P840 enters an excited state with a large negative reduction potential, and so readily donates the electron to bacteriochlorophyll 663 which passes it on down the electron chain. The electron is transferred through a series of electron carriers and complexes until it is used to reduce [[ferredoxin]]. P840 regeneration is accomplished with the oxidation of sulfide ion from hydrogen sulfide (or hydrogen or ferrous iron) by [[cytochrome]] c<sub>555.</sub><ref name=":12">{{Cite journal|last=Chen|first=Jing-Hua|last2=Wu|first2=Hangjun|last3=Xu|first3=Caihuang|last4=Liu|first4=Xiao-Chi|last5=Huang|first5=Zihui|last6=Chang|first6=Shenghai|last7=Wang|first7=Wenda|last8=Han|first8=Guangye|last9=Kuang|first9=Tingyun|last10=Shen|first10=Jian-Ren|last11=Zhang|first11=Xing|date=2020-11-20|title=Architecture of the photosynthetic complex from a green sulfur bacterium|url=https://www.sciencemag.org/lookup/doi/10.1126/science.abb6350|journal=Science|language=en|volume=370|issue=6519|pages=eabb6350|doi=10.1126/science.abb6350|issn=0036-8075}}</ref>
==== Type I reaction centers ====
The electron transport chain of green sulfur bacteria — such as is present in model organism ''Chlorobaculum tepidum'' — uses the [[Photosynthetic reaction centre|reaction center]] bacteriochlorophyll pair, P840. When light is absorbed by the reaction center, P840 enters an excited state with a large negative reduction potential, and so readily donates the electron to bacteriochlorophyll 663 which passes it on down the electron chain. The electron is transferred through a series of electron carriers and complexes until it is used to reduce NAD<sup>+</sup>. P840 regeneration is accomplished with the oxidation of sulfide ion from hydrogen sulfide (or hydrogen or ferrous iron) by [[cytochrome]] c<sub>555</sub><sup>[''[[wikipedia:Citation needed|citation needed]]'']</sup>.


The electron transport chain of purple non-sulfur bacteria begins when the reaction center bacteriochlorophyll pair, P870, becomes excited from the absorption of light. Excited P870 will then [[Electron transfer|donate an electron]] to bacteriopheophytin, which then passes it on to a series of electron carriers down the [[Electron transport chain|electron chain]]. In the process, it will generate an [[electrochemical gradient]] which can then be used to synthesize ATP by [[chemiosmosis]]. P870 has to be regenerated (reduced) to be available again for a photon reaching the reaction-center to start the process anew.
==== Type II reaction centers ====
Although the type II reaction centers are structurally and sequentially analogous to [[Photosystem II]] (PSII) in plant chloroplasts and cyanobacteria, known organisms that exhibit anoxygenic photosynthesis do not have a region analogous to the [[oxygen-evolving complex]] of PSII.


== Organisms ==
The electron transport chain of purple non-sulfur bacteria begins when the [[Photosynthetic reaction centre|reaction center]] bacteriochlorophyll pair, P870, becomes excited from the absorption of light. Excited P870 will then [[Electron transfer|donate an electron]] to [[bacteriopheophytin]], which then passes it on to a series of electron carriers down the [[Electron transport chain|electron chain]]. In the process, it will generate an [[electrochemical gradient]] which can then be used to synthesize ATP by [[chemiosmosis]]. P870 has to be regenerated (reduced) to be available again for a photon reaching the reaction-center to start the process anew. Molecular [[hydrogen]] in the bacterial environment is the usual electron donor.


== History ==
=== Bacteria ===
While oxygenic photosynthesis only exists in one bacterial [[phylum]] (cyanobacteria), anoxygenic photosynthesis is widespread in the bacterial kingdom.<ref name=":1">{{Cite journal|last=Hanada|first=Satoshi|date=2016-3|title=Anoxygenic Photosynthesis —A Photochemical Reaction That Does Not Contribute to Oxygen Reproduction—|url=https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4791109/|journal=Microbes and Environments|volume=31|issue=1|pages=1–3|doi=10.1264/jsme2.ME3101rh|issn=1342-6311|pmc=4791109|pmid=27021204}}</ref> Some examples of phyla that can utilize anoxygenic photosynthesis are [[Chlorobi]], [[Chloroflexi_(phylum)|Chloroflexi]], and [[Roseobacter|Proteobacteria]].<ref name=":2">{{Cite web|title=Green Sulfur Bacteria - an overview {{!}} ScienceDirect Topics|url=https://www.sciencedirect.com/topics/agricultural-and-biological-sciences/green-sulfur-bacteria#:~:text=Green%20sulfur%20bacteria|access-date=2020-11-08|website=www.sciencedirect.com}}</ref><ref name=":1" /><ref>{{Cite web|title=Photoheterotrophs - an overview {{!}} ScienceDirect Topics|url=https://www.sciencedirect.com/topics/agricultural-and-biological-sciences/photoheterotrophs|access-date=2020-11-08|website=www.sciencedirect.com}}</ref> These bacteria use different chemical compounds as [[Electron donor|electron donors]]. Green Sulfur Bacteria (phyla: Chlorobi) utilize [[sulfur]] or sulfide instead of water.<ref name=":2" /><ref name=":3">{{Cite web|title=Green Sulfur Bacteria - an overview {{!}} ScienceDirect Topics|url=https://www.sciencedirect.com/topics/agricultural-and-biological-sciences/green-sulfur-bacteria#:~:text=Green%20sulfur%20bacteria%20(the%20family,clustering%20separately%20from%20marine%20strains.|access-date=2020-11-08|website=www.sciencedirect.com}}</ref> Other species of Green Bacteria such as Filamentous Anoxygenic Phototrophic Bacteria (Green Non-sulfur Bacteria), use molecular hydrogen or reduced iron as their electron donors.<ref name=":3" /><ref name=":1" /> Most anoxygenic phototrophs use one or multiple of the listed electron donors and the specific electron donor used is dependent on the type of pigment and reaction centers employed by the specific bacteria.
[[File:Timeline showing the Boring Billion.png|thumb|Geologic Timeline showing the Boring Billion]]
Anoxygenic photosynthesis evolved in bacteria approximately 3.5 billion years ago during the Archaen. One billion years later, oxygenic photosynthesis evolved and the Great Oxidation Event occurred. While this produced substantial levels of atmospheric oxygen for the first time in Earth's history, it took approximately 900 million years before the atmosphere contained oxygen concentrations conducive for the life we see today (often called the [[Boring Billion]]). The [[Canfield ocean|Canfield Ocean]] is a theorized model that explains how the feedback mechanisms associated with anoxygenic photosynthesis made it difficult for the planet to fully oxidize for nearly 1 billion years following the onset of oxygenic photosynthesis.<ref name=":5">{{Cite journal|last=Lyons|first=T. W.|last2=Reinhard|first2=C. T.|date=2009-10-21|title=An early productive ocean unfit for aerobics|url=https://doi.org/10.1073/pnas.0910345106|journal=Proceedings of the National Academy of Sciences|language=en|volume=106|issue=43|pages=18045–18046|doi=10.1073/pnas.0910345106|issn=0027-8424|pmc=PMC2775325|pmid=19846788}}</ref>


There are a variety of pigments among anoxygenic phototrophs. Green Sulfur Bacteria use Bchl-''a'' and chlorophyll ''a'', absorbing visible light in the blue and red, and reflecting green light (which gives them their green color).<ref name=":2" /><ref name=":12" /> Purple Bacteria use Bchl-''a'' or -''b,'' resulting in a color ranging from purple to orange-red.<ref name=":4">{{Citation|last=Imhoff|first=Johannes F.|title=Anoxygenic Phototrophic Purple Bacteria|date=2005|url=https://doi.org/10.1007/0-387-28021-9_15|work=Bergey’s Manual® of Systematic Bacteriology: Volume Two: The Proteobacteria, Part A Introductory Essays|pages=119–132|editor-last=Brenner|editor-first=Don J.|place=Boston, MA|publisher=Springer US|language=en|doi=10.1007/0-387-28021-9_15|isbn=978-0-387-28021-9|access-date=2020-11-09|last2=Hiraishi|first2=Akira|last3=Süling|first3=Jörg|editor2-last=Krieg|editor2-first=Noel R.|editor3-last=Staley|editor3-first=James T.|editor4-last=Garrity|editor4-first=George M.}}</ref> [[Green non-sulfur bacteria|Green Non-sulfur Bacteria]] use similar bacteriochlorophyll as Green Sulfur Bacteria but use RC2 like Purple Bacteria.<ref name=":4" /><ref name=":1" /> Heliobacteria are [[Nitrogen fixation|nitrogen fixers.]] They are similar to Green Sulfur Bacteria in that they conduct a type 1 photosynthesis reaction (RC1), except they use bacteriochlorophyll g unlike any other bacterium.<ref name=":2" /><ref>{{Cite journal|last=Gest|first=Howard|last2=Favinger|first2=Jeffrey L.|date=1983-10-01|title=Heliobacterium chlorum, an anoxygenic brownish-green photosynthetic bacterium containing a “new” form of bacteriochlorophyll|url=https://doi.org/10.1007/BF00415602|journal=Archives of Microbiology|language=en|volume=136|issue=1|pages=11–16|doi=10.1007/BF00415602|issn=1432-072X}}</ref>  
=== Canfield Ocean ===
[[File:Biogeochemical processes in the Boring Billion.png|thumb|Biogeochemical processes in the Boring Billion]]
The [[Canfield ocean|Canfield Ocean]] is one theory on why oxygen levels were so low in the ocean during the [[Boring Billion|boring billion]]. Though the Great Oxidation event that occurred approximately 2.7 billion years ago produced substantial atmospheric oxygen concentrations, the ocean did not experience substantial oxidation and rather stayed reduced. The Canfield Ocean model explains how the oxygen levels in the ocean were intertwined with the marine sulfide budget. The weathering of pyrite and sulfate brought high amounts of iron and sulfur to the ocean. The healthy input of sulfur to the marine environment provided anoxygenic phototrophs with the ingredients they needed to continue to thrive. This healthy input lasted several thousands of years.<ref name=":0" />


Some cyanobacteria can do both anoxygenic and oxygenic photosynthesis. When these organisms are in an environment with abundant sulfur, they will preferentially oxidize sulfide rather than water.<ref name=":0" /> A similar phenomenon was observed in a study by Shiba et al 1979.<ref>{{Cite journal|last=Shiba|first=Tsuneo|last2=Simidu|first2=Usio|last3=Taga|first3=Nobuo|date=1979|title=Distribution of Aerobic Bacteria Which Contain Bacteriochlorophyll a|url=https://aem.asm.org/content/38/1/43|journal=Applied and Environmental Microbiology|language=en|volume=38|issue=1|pages=43–45|doi=10.1128/AEM.38.1.43-45.1979|issn=0099-2240}}</ref> They isolated a subclass of the Proteobacteria in [[Oxic|oxic conditions]] and found they could synthesize Bchl-''a'' without producing oxygen in the process. This bacterium is part of a different category of aerobic anoxygenic photosynthetic bacteria.<ref name=":7" />
During the proterozoic, anoxygenic cyanobacteria maintained highly [[Euxinia|euxinic]] conditions in the world’s oceans. In the anoxic OMZ, nitrogen falls below the necessary [[Redfield ratio|Redfield Ratio]] of 16:1, N:P, respectively, needed for [[Photosynthesis|oxygenic photosynthesis]]. Anoxygenic photoautotrophs would have taken up all the free nitrogen in the middle ocean before oxygenic photoautotrophs would have consumed all the nitrogen which led to nitrogen being limited in the euphotic zone<ref name=":0" />. This would have limited oxygenic photosynthesis in the surface waters and produced a severe [[chemocline]]. Molecular fossils from the Proterozoic oceans show pigments derived from anoxygenic photosynthesizers which is direct evidence for photic zone [[euxinia]] as Canfield theorizes.  Anoxygenic photosynthesizers were the dominant photosynthesizers in the ocean at that time.<ref name=":0" />


=== Geologic Timescale ===
=== Archaea ===
Some [[archaea]] (e.g. ''[[Halobacterium]]'') capture light energy for metabolic function and are thus phototrophic but none are known to "fix" carbon (i.e. be photosynthetic). Instead of a chlorophyll-type receptor and electron transport chain, proteins such as [[bacteriorhodopsin]] and halorhodopsin capture light energy with the aid of [[Diterpene|diterpenes]] to move ions against the gradient and produce adenosine triphosphate ([[Adenosine triphosphate|ATP]]) via [[chemiosmosis]] in the manner of mitochondria.
The [[Canfield ocean|Canfield Ocean]] model provides an explanation for the Boring Billion through feedback mechanisms associated with euxinia. [[Euxinia|Euxinic]] conditions are maintained by a high prevalence of anoxygenic phototrophs. When these organisms die, they sink to the ocean floor, and are buried as organic, carbon-rich material. When euxinia was rampant in the Boring Billion, there was a large burial of this organic material, and the Canfield Ocean theorized that a significant amount of sulfide was released. Sulfide would have reacted with dissolved iron in the water to form pyrite ([[pyritization]])<ref name=":6">{{Cite journal|last=Mukherjee|first=Indrani|last2=Large|first2=Ross R.|last3=Corkrey|first3=Ross|last4=Danyushevsky|first4=Leonid V.|date=2018-03-13|title=The Boring Billion, a slingshot for Complex Life on Earth|url=https://www.nature.com/articles/s41598-018-22695-x|journal=Scientific Reports|language=en|volume=8|issue=1|pages=4432|doi=10.1038/s41598-018-22695-x|issn=2045-2322|pmc=PMC5849639|pmid=29535324}}</ref>. As more carbon was buried due to the increased production from anoxygenic phototrophs, more pyritization occurred. As more organic material decays, sulfide (S<sup>2-</sup>) was released, which reacted with dissolved iron in the water and the outer layer of the organism was  replaced with Iron pyrite (FeS<sub>2</sub>)<ref name=":6" />. A positive feedback loop occurred because as anoxygenic photosynthesizers increased because of the abundant sulfur in the oceans meant more sinking biomass which increased  carbon burial in the sediment and the more carbon burial led to more pyritization which in turn lowered the sulfur budget in the ocean<ref name=":5" />. A strong negative feedback loop was present because as anoxia increased, the organic matter decaying increased the fraction of organic matter that escaped decay by burial in the sediments<ref name=":5" />.


== Environments ==





== Present-day examples ==


=== Marine ===
=== Marine ===
[[File:How oceans become euxinic.png|thumb|Marine Euxinia]]
[[File:How oceans become euxinic.png|thumb|Marine Euxinia]]
Anoxygenic photosynthesis by marine algae (cyanobacteria/dinoflagellates) and bacteria is potentially of great ecological importance to the world's oceans where they are abundant<ref>{{Cite journal|last=Allgaier|first=Martin|last2=Uphoff|first2=Heike|last3=Felske|first3=Andreas|last4=Wagner-Döbler|first4=Irene|date=2003-09|title=Aerobic Anoxygenic Photosynthesis in Roseobacter Clade Bacteria from Diverse Marine Habitats|url=https://aem.asm.org/content/69/9/5051|journal=Applied and Environmental Microbiology|language=en|volume=69|issue=9|pages=5051–5059|doi=10.1128/AEM.69.9.5051-5059.2003|issn=0099-2240|pmc=PMC194994|pmid=12957886}}</ref> <ref name=":7">{{Cite journal|last=Goericke|first=Ralf|date=2002-01|title=Bacteriochlorophyll a
Anoxygenic photosynthesis by marine cyanobacteria, [[dinoflagellates]] and bacteria is potentially of great ecological importance to the world's oceans where they are abundant.<ref>{{Cite journal|last=Allgaier|first=Martin|last2=Uphoff|first2=Heike|last3=Felske|first3=Andreas|last4=Wagner-Döbler|first4=Irene|date=2003-09|title=Aerobic Anoxygenic Photosynthesis in Roseobacter Clade Bacteria from Diverse Marine Habitats|url=https://aem.asm.org/content/69/9/5051|journal=Applied and Environmental Microbiology|language=en|volume=69|issue=9|pages=5051–5059|doi=10.1128/AEM.69.9.5051-5059.2003|issn=0099-2240|pmc=PMC194994|pmid=12957886}}</ref><ref name=":7">{{Cite journal|last=Goericke|first=Ralf|date=2002-01|title=Bacteriochlorophyll a
in the ocean: Is anoxygenic bacterial photosynthesis important?|url=http://dx.doi.org/10.4319/lo.2002.47.1.0290|journal=Limnology and Oceanography|volume=47|issue=1|pages=290–295|doi=10.4319/lo.2002.47.1.0290|issn=0024-3590}}</ref>. Anoxygenic photosynthetic bacteria facilitate the process in photic, anoxic marine environments where hydrogen sulfide is available and light intensity is low <ref name=":8">{{Cite journal|last=Proctor|first=LM|date=1997|title=Nitrogen-fixing, photosynthetic, anaerobic bacteria associated with pelagic copepods|url=http://dx.doi.org/10.3354/ame012105|journal=Aquatic Microbial Ecology|volume=12|pages=105–113|doi=10.3354/ame012105|issn=0948-3055}}</ref>. Optimal habitats include stratified seas [xxxx], sediment layers<ref name=":9">{{Cite journal|date=2009|editor-last=Hunter|editor-first=C. Neil|editor2-last=Daldal|editor2-first=Fevzi|editor3-last=Thurnauer|editor3-first=Marion C.|editor4-last=Beatty|editor4-first=J. Thomas|title=The Purple Phototrophic Bacteria|url=http://dx.doi.org/10.1007/978-1-4020-8815-5|journal=Advances in Photosynthesis and Respiration|doi=10.1007/978-1-4020-8815-5|issn=1572-0233}}</ref>, salt marshes<ref name=":10">{{Cite journal|last=Paterek|first=J. Robert|last2=Paynter|first2=M. J. B.|date=1988|title=Populations of Anaerobic Phototrophic Bacteria in a Spartina alterniflora Salt Marsh|url=https://aem.asm.org/content/54/6/1360|journal=Applied and Environmental Microbiology|language=en|volume=54|issue=6|pages=1360–1364|doi=10.1128/AEM.54.6.1360-1364.1988|issn=0099-2240}}</ref> , intertidal microbial mats<ref name=":9" />, anoxic microzones associated with particulate matter<ref name=":7" />, and even within the guts of zooplankton (though not their fecal pellets)<ref name=":8" />.
in the ocean: Is anoxygenic bacterial photosynthesis important?|url=http://dx.doi.org/10.4319/lo.2002.47.1.0290|journal=Limnology and Oceanography|volume=47|issue=1|pages=290–295|doi=10.4319/lo.2002.47.1.0290|issn=0024-3590}}</ref> Anoxygenic photosynthetic organisms live in photic, anoxic marine environments where hydrogen sulfide is available and light intensity is low.<ref name=":8">{{Cite journal|last=Proctor|first=LM|date=1997|title=Nitrogen-fixing, photosynthetic, anaerobic bacteria associated with pelagic copepods|url=http://dx.doi.org/10.3354/ame012105|journal=Aquatic Microbial Ecology|volume=12|pages=105–113|doi=10.3354/ame012105|issn=0948-3055}}</ref> Optimal habitats include stratified seas, sediment layers, intertidal [[Microbial mat|microbial mats]], and even within the guts of zooplankton (though not their fecal pellets), salt marshes, anoxic microzones associated with particulate matter. <ref name=":5">{{Cite journal|last=Lyons|first=T. W.|last2=Reinhard|first2=C. T.|date=2009-10-21|title=An early productive ocean unfit for aerobics|url=https://doi.org/10.1073/pnas.0910345106|journal=Proceedings of the National Academy of Sciences|language=en|volume=106|issue=43|pages=18045–18046|doi=10.1073/pnas.0910345106|issn=0027-8424|pmc=PMC2775325|pmid=19846788}}</ref><ref name=":9">{{Cite journal|date=2009|editor-last=Hunter|editor-first=C. Neil|editor2-last=Daldal|editor2-first=Fevzi|editor3-last=Thurnauer|editor3-first=Marion C.|editor4-last=Beatty|editor4-first=J. Thomas|title=The Purple Phototrophic Bacteria|url=http://dx.doi.org/10.1007/978-1-4020-8815-5|journal=Advances in Photosynthesis and Respiration|doi=10.1007/978-1-4020-8815-5|issn=1572-0233}}</ref><ref name=":10">{{Cite journal|last=Paterek|first=J. Robert|last2=Paynter|first2=M. J. B.|date=1988|title=Populations of Anaerobic Phototrophic Bacteria in a Spartina alterniflora Salt Marsh|url=https://aem.asm.org/content/54/6/1360|journal=Applied and Environmental Microbiology|language=en|volume=54|issue=6|pages=1360–1364|doi=10.1128/AEM.54.6.1360-1364.1988|issn=0099-2240}}</ref> <ref name=":9" /><ref name=":7" /><ref name=":8" /> Organisms  capable of anoxygenic photosynthesis are more abundant than previously thought, as evidenced by widespread detection of [[bacteriochlorophyll a|bacteriochlorophyll ''a'']] in the worlds aerobic open oceans oceans.<ref name=":8" /> [[Photoheterotrophic]] [[Alphaproteobacteria|alpha-bacteria]] capable of anoxygenic photosynthesis account for as much as 10% of the bacterial biomass off the coast of Washington and Oregon. <ref>{{cite journal |last1=Kolber |first1=Z.S. |title=Contribution of aerobic photoheterotrophic bacteria to the carbon cycle in the ocean |journal=science |date=07/29/2001 |volume=292 |pages=2492-5 |doi=10.1126/science.1059707 |url=https://pubmed.ncbi.nlm.nih.gov/11431568/ |accessdate=11/15/2020}}</ref> Their ability for anoxygenic photosynthesis may be more important in oligotrophic waters where photoheterotrophic bacteria are more likely to be limited by the availability of reduced carbon, as photoheterotrophs do not need to use light at all if all organic compounds are sufficiently available,<ref name=":7" /> however their abundance throughout the oceans suggest that they may contribute to marine sulfur, [[Nitrogen_cycle|nitrogen]], and [[Oceanic_carbon_cycle|carbon cycles]].<ref name=":8" />


One of the best known examples of sustained anoxygenic photosynthesis is the [[Black Sea]].<ref name=":5" /> The feedback mechanisms described in the [[Canfield ocean|Canfield Ocean]] are evident in the Black Sea. Though it is 2000m deep, the majority of the water column is euxinic and there is a steep chemocline with an overlying oxic surface layer of approximately 100m.[[File:IRON REDUCTION.jpg|thumb|Iron reduction by microbes in a marine intertidal environment suitable for anoxygenic photosynthesis. ]]
Some aerobic photoheterotrophic alpha-bacteria are also capable of anoxygenic photosynthesis and account for as much as 10% of the bacterial biomass off the coast of Washington and Oregon [kolber 2001]. Their ability for anoxygenic photosynthesis may be more important in oligotrophic waters where [[Photoheterotroph|photoheterotrophic]] bacteria are more likely to be limited by the availability of reduced carbon<ref name=":7" />.

One of the best known examples of sustained anoxygenic photosynthesis is the [[Black Sea]].<ref name=":5" /> The feedback mechanisms described above maintain a shallow oxic surface layer overlying a steep chemocline and a euxinic deep sea.


=== Intertidal ===
=== Intertidal ===
Anoxygenic photosynthesis has the potential to be substantial in intertidal mudflats and salt marsh systems where ideal conditions for anoxygenic photosynthesis exist, with large sulfur and iron redox gradients in near surface sediments and there is ample light availability<ref>{{Cite journal|last=Wang|first=Shiyu Rachel|last2=Iorio|first2=Daniela Di|last3=Cai|first3=Wei-Jun|last4=Hopkinson|first4=Charles S.|date=2018|title=Inorganic carbon and oxygen dynamics in a marsh-dominated estuary|url=https://aslopubs.onlinelibrary.wiley.com/doi/abs/10.1002/lno.10614|journal=Limnology and Oceanography|language=en|volume=63|issue=1|pages=47–71|doi=10.1002/lno.10614|issn=1939-5590|pmc=PMC5812098|pmid=29456267}}</ref>.
Anoxygenic photosynthetic organisms are abundant in [[Intertidal zone|intertidal]] [[Mudflat|mudflats]] and [[salt marsh]] systems. These habitats can have large sulfur and iron redox gradients in near surface sediments. Coupled with a reliable availability of light, interidal zones are ideal environments for anoxygenic photosynthesis.<ref>{{Cite journal|last=Wang|first=Shiyu Rachel|last2=Iorio|first2=Daniela Di|last3=Cai|first3=Wei-Jun|last4=Hopkinson|first4=Charles S.|date=2018|title=Inorganic carbon and oxygen dynamics in a marsh-dominated estuary|url=https://aslopubs.onlinelibrary.wiley.com/doi/abs/10.1002/lno.10614|journal=Limnology and Oceanography|language=en|volume=63|issue=1|pages=47–71|doi=10.1002/lno.10614|issn=1939-5590|pmc=PMC5812098|pmid=29456267}}</ref>


=== Freshwater ===
=== Freshwater ===
Anoxygenic photosynthetic bacteria typically stratify in anoxic water, such as shallow ponds of stagnant water<ref name=":10" />, hot springs<ref name=":10" />, or stratified sulfuric lakes<ref name=":11">{{Cite journal|last=Pedrós-Alió|first=Carlos|title=Phototrophic sulfur bacteria in two Spanish lakes: Vertical distribution and limiting factors|url=https://www.academia.edu/6396552/Phototrophic_sulfur_bacteria_in_two_Spanish_lakes_Vertical_distribution_and_limiting_factors|journal=Limnology and Oceanography|language=en}}</ref>, forming thick brown, green, or pink aggregations at the mixing layer, where very sharp gradients in temperature, light, and chemical concentrations (e.g. Oxygen and sulfide) favor their growth<ref name=":11" />. The mixing layer depth within lakes may vary seasonally and cause changes in anaerobic primary production due to the intensity of ambient light. Optimal growth conditions may be self-limiting as a reduction of light intensity from self-shading can limit growth even when nutrients are non-limiting.<ref name=":11" />
Anoxygenic photosynthetizing bacteria typically stratify in anoxic water, such as shallow ponds of stagnant water, [[Hot spring|hot springs]], or stratified sulfuric lakes, forming thick brown, green, or pink aggregations at the [[chemocline]], where very sharp gradients in temperature, light, and chemical concentrations (e.g. oxygen and sulfide) favor their growth.<ref name=":10" /><ref name=":10" /><ref name=":11">{{Cite journal|last=Pedrós-Alió|first=Carlos|title=Phototrophic sulfur bacteria in two Spanish lakes: Vertical distribution and limiting factors|url=https://www.academia.edu/6396552/Phototrophic_sulfur_bacteria_in_two_Spanish_lakes_Vertical_distribution_and_limiting_factors|journal=Limnology and Oceanography|language=en}}</ref> The chemocline depth within lakes may vary seasonally and cause changes in anaerobic primary production due to the intensity of ambient light. Optimal growth conditions may be self-limiting as a reduction of light intensity from self-shading can limit growth even when nutrients are non-limiting.<ref name=":11" />


=== Terrestrial ===
=== Terrestrial ===
Aerobic anoxygenic phototrophic bacteria have been reported to exist in biological soils, comprising 0.1–5.9% of the cultivable bacterial community in moss, lichen and cyanobacteria‐dominated crust from sand dunes and sandy soils, and could accelerate organic carbon cycling in nutrient-poor arid soils. Their effects will be especially important as global climate change enhances soil erosion and consequent nutrient loss.<ref>{{Cite journal|last=Csotonyi|first=Julius T.|last2=Swiderski|first2=Jolantha|last3=Stackebrandt|first3=Erko|last4=Yurkov|first4=Vladimir|date=2010-10|title=A new environment for aerobic anoxygenic phototrophic bacteria: biological soil crusts: Anoxygenic phototrophs in biological soil crusts|url=http://doi.wiley.com/10.1111/j.1758-2229.2010.00151.x|journal=Environmental Microbiology Reports|language=en|volume=2|issue=5|pages=651–656|doi=10.1111/j.1758-2229.2010.00151.x}}</ref> <ref>{{Cite journal|last=Lehours|first=Anne-Catherine|last2=Enault|first2=François|last3=Boeuf|first3=Dominique|last4=Jeanthon|first4=Christian|date=2018-12|title=Biogeographic patterns of aerobic anoxygenic phototrophic bacteria reveal an ecological consistency of phylogenetic clades in different oceanic biomes|url=http://www.nature.com/articles/s41598-018-22413-7|journal=Scientific Reports|language=en|volume=8|issue=1|pages=4105|doi=10.1038/s41598-018-22413-7|issn=2045-2322|pmc=PMC5841314|pmid=29515205}}</ref>
Aerobic anoxygenic phototrophic bacteria have been reported to exist in biological soils, comprising 0.1–5.9% of the cultivable bacterial community in [[moss]], [[lichen]] and cyanobacteria‐dominated crust from [[sand dunes]] and sandy soils, and could accelerate organic carbon cycling in nutrient-poor arid soils. Their effects will be especially important as global climate change enhances [[soil erosion]] and consequent nutrient loss.<ref>{{Cite journal|last=Csotonyi|first=Julius T.|last2=Swiderski|first2=Jolantha|last3=Stackebrandt|first3=Erko|last4=Yurkov|first4=Vladimir|date=2010-10|title=A new environment for aerobic anoxygenic phototrophic bacteria: biological soil crusts: Anoxygenic phototrophs in biological soil crusts|url=http://doi.wiley.com/10.1111/j.1758-2229.2010.00151.x|journal=Environmental Microbiology Reports|language=en|volume=2|issue=5|pages=651–656|doi=10.1111/j.1758-2229.2010.00151.x}}</ref> <ref>{{Cite journal|last=Lehours|first=Anne-Catherine|last2=Enault|first2=François|last3=Boeuf|first3=Dominique|last4=Jeanthon|first4=Christian|date=2018-12|title=Biogeographic patterns of aerobic anoxygenic phototrophic bacteria reveal an ecological consistency of phylogenetic clades in different oceanic biomes|url=http://www.nature.com/articles/s41598-018-22413-7|journal=Scientific Reports|language=en|volume=8|issue=1|pages=4105|doi=10.1038/s41598-018-22413-7|issn=2045-2322|pmc=PMC5841314|pmid=29515205}}</ref>

== History ==
[[File:Timeline showing the Boring Billion.png|thumb|Geologic Timeline showing the Boring Billion]]
Anoxygenic photosynthesis likely evolved in bacteria approximately 3.5 billion years ago during the [[Archean|Archaen]].<ref name=":0" /> One billion years later, oxygenic photosynthesis evolved and the [[Great Oxidation Event]] occurred. While this produced substantial levels of atmospheric oxygen for the first time in Earth's history, it took approximately 900 million years before the atmosphere contained oxygen concentrations conducive for the life we see today (often called the [[Boring Billion]]). The [[Canfield ocean|Canfield Ocean]] is a theorized model that explains how the feedback mechanisms associated with anoxygenic photosynthesis made it difficult for the planet to fully oxidize for nearly 1 billion years following the onset of oxygenic photosynthesis.<ref name=":5" />During the [[Proterozoic]], anoxygenic cyanobacteria maintained highly [[Euxinia|euxinic]] conditions in the world’s oceans. Molecular fossils from the Proterozoic oceans show pigments derived from anoxygenic photosynthesizers which is direct evidence for photic zone euxinia as Canfield theorizes.  Anoxygenic photosynthesizers were the dominant photosynthesizers in the ocean at that time.<ref name=":0" />[[File:Biogeochemical processes in the Boring Billion.png|thumb|Biogeochemical processes in the Boring Billion]]

=== Geologic Timescale ===
The Canfield Ocean is one theory on why oxygen levels were so low in the ocean during the Boring Billion. Though the Great Oxidation Event that occurred approximately 2.7 billion years ago produced substantial atmospheric oxygen concentrations, the ocean did not experience substantial oxidation and rather stayed reduced.<ref>{{Cite journal|last=Ozaki|first=Kazumi|last2=Thompson|first2=Katharine J.|last3=Simister|first3=Rachel L.|last4=Crowe|first4=Sean A.|last5=Reinhard|first5=Christopher T.|date=2019-12|title=Anoxygenic photosynthesis and the delayed oxygenation of Earth’s atmosphere|url=http://www.nature.com/articles/s41467-019-10872-z|journal=Nature Communications|language=en|volume=10|issue=1|pages=3026|doi=10.1038/s41467-019-10872-z|issn=2041-1723|pmc=PMC6616575|pmid=31289261}}</ref> During this time, surface waters were nitrogen-limited because of the efficient utilization of nitrogen by anoxygenic phototrophs. As nitrogen-rich deep waters upwelled, anoxygenic phototrophs were likely to utilize it first, consequently making the upper photic zone a difficult place for oxygenic phototrophs to thrive.<ref name=":0" /> This would have limited oxygenic photosynthesis in the surface waters and produced a severe [[chemocline]].The Canfield Ocean model explains how the oxygen levels in the ocean were intertwined with the marine sulfide budget. The weathering of pyrite and sulfate brought high amounts of iron and sulfur to the ocean. The high oxygen rates in the atmosphere led to oxidative weathering of sulfides which filled the ocean with sulfates.<ref>{{Cite journal|last=Lane|first=Nick|date=2010-08-07|title=Without oxygen: Rewriting life's history|url=http://www.sciencedirect.com/science/article/pii/S0262407910619239|journal=New Scientist|language=en|volume=207|issue=2772|pages=36–39|doi=10.1016/S0262-4079(10)61923-9|issn=0262-4079}}</ref> The substantial input of sulfur to the marine environment provided anoxygenic phototrophs with the ingredients they needed to continue to thrive. This healthy input lasted several thousands of years.<ref name=":0" /> In the mid-Proterozoic, subchemocline anoxygenic photosynthesizers dominated the ocean which created a sulfide rich ocean.<ref name=":0" />

Feedback mechanisms helped maintain the euxinic environment that lasted through the Boring Billion. Euxinic conditions would have allowed for high rates of anoxygenic photosynthesis and thus high production of elemental sulfur. Consequently, there would be an increased flux of organic material and sulfur to the ocean floor. In the deep ocean, this exported sulfur would have reacted with dissolved iron in the water to form pyrite ([[pyritization]]).<ref name=":6">{{Cite journal|last=Mukherjee|first=Indrani|last2=Large|first2=Ross R.|last3=Corkrey|first3=Ross|last4=Danyushevsky|first4=Leonid V.|date=2018-03-13|title=The Boring Billion, a slingshot for Complex Life on Earth|url=https://www.nature.com/articles/s41598-018-22695-x|journal=Scientific Reports|language=en|volume=8|issue=1|pages=4432|doi=10.1038/s41598-018-22695-x|issn=2045-2322|pmc=PMC5849639|pmid=29535324}}</ref> Iron pyrite would also have been used by organisms to produce their outer layer.<ref name=":6" /> A positive feedback loop occurred because as anoxygenic photosynthesizers increased, the abundant sulfur in the oceans also increased. This was followed by a strong negative feedback loop, because an increase in sulfur production led to more sinking biomass, which increased carbon burial in the sediment. The more carbon burial led to more pyritization which in turn lowered the sulfur budget in the ocean. The dynamic between these two feedbacks is how a reduced ocean with limited oxygenic photosynthesis could be sustained for such a long time after the Great Oxidation Event<ref name=":5" />


== See also ==
== See also ==
Line 79: Line 59:
* [[Canfield ocean|Canfield Ocean]]
* [[Canfield ocean|Canfield Ocean]]
* [[Purple sulfur bacteria|Purple-Sulfur Bacteria]]
* [[Purple sulfur bacteria|Purple-Sulfur Bacteria]]
* [[Roseobacter]]
* [[Black Sea|The Black Sea]]
* [[Black Sea|The Black Sea]]
* [[Aerobic_anoxygenic_phototrophic_bacteria]]


== References ==
== References ==

Latest revision as of 23:51, 30 November 2020

Anoxygenic photosynthesis is the metabolic process of reducing carbon without producing oxygen. The community of anoxygenic phototrophs is diverse even though such organisms require niche ecological conditions to thrive. Anoxygenic photosynthesizing bacteria employ a variety of strategies with differing photosynthetic complexes and pigments.[1] Studies suggest that anoxygenic photosynthesis was the first anabolic process of harnessing solar energy to evolve.[2] Certain organisms were likely utilizing anoxygenic photosynthesis 3 billion years ago when the planet had extremely low levels of oxygen and organisms thrived under reduced conditions. Anoxygenic phototrophs contain one of two enzymes called Reaction Centers (RC) 1 and 2. RC 1 and 2 are the ancient analogs to Photosystem I and II found in oxygenic phototrophs and likely evolved in sequence as the availability of Iron (II) Sulfide (FeS) became more limited and the planet more oxidized.[1]

Molecular structure

[edit]

Pigments

[edit]

The pigments used to carry out anaerobic photosynthesis are similar to chlorophyll but differ in molecular detail and peak wavelength of light absorbed. Bacteriochlorophylls (Bchl) a through g absorb electromagnetic radiation maximally in the near-infrared within their natural membrane milieu. This differs from chlorophyll a, the predominant plant and cyanobacteria pigment, which has peak absorption wavelength approximately 100 nanometers shorter (in the red and blue portion of the visible spectrum).

Reaction Centers

[edit]
Example of Anoxygenic Photosynthesis (in Green Sulfur Bacteria)

There are two main types of anaerobic photosynthetic electron transport chains in bacteria. The type I reaction centers (RC1) are found in green sulfur bacteria, Chloracidobacterium. The type II reaction centers (RC2) are found in FAPs and purple bacteria. RC1 uses low-potential FeS clusters as electron acceptors to reduce NADP+ to NADPH. RC2 receives electrons from small soluble proteins such as cytochrome c, cupredoxins and ferredoxins. RC2 uses electron donors such as ferrous iron, reduced sulfur compounds, and molecular hydrogen. It is similar to Photosystem II (PSII), but without the oxygen-evolving complex.[3] Detailed below are the reaction centers found in green sulfur bacteria and purple bacteria.

The electron transport chain of green sulfur bacteria, present in model organism, Chlorobaculum tepidum — uses the reaction center bacteriochlorophyll pair, P840. When light is absorbed by the reaction center, P840 enters an excited state with a large negative reduction potential, and so readily donates the electron to bacteriochlorophyll 663 which passes it on down the electron chain. The electron is transferred through a series of electron carriers and complexes until it is used to reduce ferredoxin. P840 regeneration is accomplished with the oxidation of sulfide ion from hydrogen sulfide (or hydrogen or ferrous iron) by cytochrome c555.[4]

The electron transport chain of purple non-sulfur bacteria begins when the reaction center bacteriochlorophyll pair, P870, becomes excited from the absorption of light. Excited P870 will then donate an electron to bacteriopheophytin, which then passes it on to a series of electron carriers down the electron chain. In the process, it will generate an electrochemical gradient which can then be used to synthesize ATP by chemiosmosis. P870 has to be regenerated (reduced) to be available again for a photon reaching the reaction-center to start the process anew.

Organisms

[edit]

Bacteria

[edit]

While oxygenic photosynthesis only exists in one bacterial phylum (cyanobacteria), anoxygenic photosynthesis is widespread in the bacterial kingdom.[5] Some examples of phyla that can utilize anoxygenic photosynthesis are Chlorobi, Chloroflexi, and Proteobacteria.[6][5][7] These bacteria use different chemical compounds as electron donors. Green Sulfur Bacteria (phyla: Chlorobi) utilize sulfur or sulfide instead of water.[6][8] Other species of Green Bacteria such as Filamentous Anoxygenic Phototrophic Bacteria (Green Non-sulfur Bacteria), use molecular hydrogen or reduced iron as their electron donors.[8][5] Most anoxygenic phototrophs use one or multiple of the listed electron donors and the specific electron donor used is dependent on the type of pigment and reaction centers employed by the specific bacteria.

There are a variety of pigments among anoxygenic phototrophs. Green Sulfur Bacteria use Bchl-a and chlorophyll a, absorbing visible light in the blue and red, and reflecting green light (which gives them their green color).[6][4] Purple Bacteria use Bchl-a or -b, resulting in a color ranging from purple to orange-red.[9] Green Non-sulfur Bacteria use similar bacteriochlorophyll as Green Sulfur Bacteria but use RC2 like Purple Bacteria.[9][5] Heliobacteria are nitrogen fixers. They are similar to Green Sulfur Bacteria in that they conduct a type 1 photosynthesis reaction (RC1), except they use bacteriochlorophyll g unlike any other bacterium.[6][10]  

Some cyanobacteria can do both anoxygenic and oxygenic photosynthesis. When these organisms are in an environment with abundant sulfur, they will preferentially oxidize sulfide rather than water.[1] A similar phenomenon was observed in a study by Shiba et al 1979.[11] They isolated a subclass of the Proteobacteria in oxic conditions and found they could synthesize Bchl-a without producing oxygen in the process. This bacterium is part of a different category of aerobic anoxygenic photosynthetic bacteria.[12]

Archaea

[edit]

Some archaea (e.g. Halobacterium) capture light energy for metabolic function and are thus phototrophic but none are known to "fix" carbon (i.e. be photosynthetic). Instead of a chlorophyll-type receptor and electron transport chain, proteins such as bacteriorhodopsin and halorhodopsin capture light energy with the aid of diterpenes to move ions against the gradient and produce adenosine triphosphate (ATP) via chemiosmosis in the manner of mitochondria.

Environments

[edit]

Marine

[edit]
Marine Euxinia

Anoxygenic photosynthesis by marine cyanobacteria, dinoflagellates and bacteria is potentially of great ecological importance to the world's oceans where they are abundant.[13][12] Anoxygenic photosynthetic organisms live in photic, anoxic marine environments where hydrogen sulfide is available and light intensity is low.[14] Optimal habitats include stratified seas, sediment layers, intertidal microbial mats, and even within the guts of zooplankton (though not their fecal pellets), salt marshes, anoxic microzones associated with particulate matter. [15][16][17] [16][12][14] Organisms  capable of anoxygenic photosynthesis are more abundant than previously thought, as evidenced by widespread detection of bacteriochlorophyll a in the worlds aerobic open oceans oceans.[14] Photoheterotrophic alpha-bacteria capable of anoxygenic photosynthesis account for as much as 10% of the bacterial biomass off the coast of Washington and Oregon. [18] Their ability for anoxygenic photosynthesis may be more important in oligotrophic waters where photoheterotrophic bacteria are more likely to be limited by the availability of reduced carbon, as photoheterotrophs do not need to use light at all if all organic compounds are sufficiently available,[12] however their abundance throughout the oceans suggest that they may contribute to marine sulfur, nitrogen, and carbon cycles.[14]

One of the best known examples of sustained anoxygenic photosynthesis is the Black Sea.[15] The feedback mechanisms described in the Canfield Ocean are evident in the Black Sea. Though it is 2000m deep, the majority of the water column is euxinic and there is a steep chemocline with an overlying oxic surface layer of approximately 100m.

Iron reduction by microbes in a marine intertidal environment suitable for anoxygenic photosynthesis.

Intertidal

[edit]

Anoxygenic photosynthetic organisms are abundant in intertidal mudflats and salt marsh systems. These habitats can have large sulfur and iron redox gradients in near surface sediments. Coupled with a reliable availability of light, interidal zones are ideal environments for anoxygenic photosynthesis.[19]

Freshwater

[edit]

Anoxygenic photosynthetizing bacteria typically stratify in anoxic water, such as shallow ponds of stagnant water, hot springs, or stratified sulfuric lakes, forming thick brown, green, or pink aggregations at the chemocline, where very sharp gradients in temperature, light, and chemical concentrations (e.g. oxygen and sulfide) favor their growth.[17][17][20] The chemocline depth within lakes may vary seasonally and cause changes in anaerobic primary production due to the intensity of ambient light. Optimal growth conditions may be self-limiting as a reduction of light intensity from self-shading can limit growth even when nutrients are non-limiting.[20]

Terrestrial

[edit]

Aerobic anoxygenic phototrophic bacteria have been reported to exist in biological soils, comprising 0.1–5.9% of the cultivable bacterial community in moss, lichen and cyanobacteria‐dominated crust from sand dunes and sandy soils, and could accelerate organic carbon cycling in nutrient-poor arid soils. Their effects will be especially important as global climate change enhances soil erosion and consequent nutrient loss.[21] [22]

History

[edit]
Geologic Timeline showing the Boring Billion

Anoxygenic photosynthesis likely evolved in bacteria approximately 3.5 billion years ago during the Archaen.[1] One billion years later, oxygenic photosynthesis evolved and the Great Oxidation Event occurred. While this produced substantial levels of atmospheric oxygen for the first time in Earth's history, it took approximately 900 million years before the atmosphere contained oxygen concentrations conducive for the life we see today (often called the Boring Billion). The Canfield Ocean is a theorized model that explains how the feedback mechanisms associated with anoxygenic photosynthesis made it difficult for the planet to fully oxidize for nearly 1 billion years following the onset of oxygenic photosynthesis.[15]During the Proterozoic, anoxygenic cyanobacteria maintained highly euxinic conditions in the world’s oceans. Molecular fossils from the Proterozoic oceans show pigments derived from anoxygenic photosynthesizers which is direct evidence for photic zone euxinia as Canfield theorizes.  Anoxygenic photosynthesizers were the dominant photosynthesizers in the ocean at that time.[1]

Biogeochemical processes in the Boring Billion

Geologic Timescale

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The Canfield Ocean is one theory on why oxygen levels were so low in the ocean during the Boring Billion. Though the Great Oxidation Event that occurred approximately 2.7 billion years ago produced substantial atmospheric oxygen concentrations, the ocean did not experience substantial oxidation and rather stayed reduced.[23] During this time, surface waters were nitrogen-limited because of the efficient utilization of nitrogen by anoxygenic phototrophs. As nitrogen-rich deep waters upwelled, anoxygenic phototrophs were likely to utilize it first, consequently making the upper photic zone a difficult place for oxygenic phototrophs to thrive.[1] This would have limited oxygenic photosynthesis in the surface waters and produced a severe chemocline.The Canfield Ocean model explains how the oxygen levels in the ocean were intertwined with the marine sulfide budget. The weathering of pyrite and sulfate brought high amounts of iron and sulfur to the ocean. The high oxygen rates in the atmosphere led to oxidative weathering of sulfides which filled the ocean with sulfates.[24] The substantial input of sulfur to the marine environment provided anoxygenic phototrophs with the ingredients they needed to continue to thrive. This healthy input lasted several thousands of years.[1] In the mid-Proterozoic, subchemocline anoxygenic photosynthesizers dominated the ocean which created a sulfide rich ocean.[1]

Feedback mechanisms helped maintain the euxinic environment that lasted through the Boring Billion. Euxinic conditions would have allowed for high rates of anoxygenic photosynthesis and thus high production of elemental sulfur. Consequently, there would be an increased flux of organic material and sulfur to the ocean floor. In the deep ocean, this exported sulfur would have reacted with dissolved iron in the water to form pyrite (pyritization).[25] Iron pyrite would also have been used by organisms to produce their outer layer.[25] A positive feedback loop occurred because as anoxygenic photosynthesizers increased, the abundant sulfur in the oceans also increased. This was followed by a strong negative feedback loop, because an increase in sulfur production led to more sinking biomass, which increased carbon burial in the sediment. The more carbon burial led to more pyritization which in turn lowered the sulfur budget in the ocean. The dynamic between these two feedbacks is how a reduced ocean with limited oxygenic photosynthesis could be sustained for such a long time after the Great Oxidation Event[15]

See also

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References

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