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Green sulfur bacteria

February 15, 2024

The green sulfur bacteria are a phylum, Chlorobiota,[4] of obligately anaerobic photoautotrophic bacteria that metabolize sulfur.[5]

Green sulfur bacteria
Green sulfur bacteria in a Winogradsky column
Scientific classification
Domain: Bacteria
(unranked): Bacteroidota–Chlorobiota group
Phylum: Chlorobiota
Iino et al. 2021[3]
Class: "Chlorobia"
Garrity and Holt 2001[2]
Order: Chlorobiales
Gibbons and Murray 1978 (Approved Lists 1980)[1]
Families and Genera
Synonyms
  • Chlorobiota:
    • Chlorobi Iino et al. 2010
    • "Chlorobi" Garrity and Holt 2001
    • "Chlorobaeota" Oren et al. 2015
    • "Chlorobiota" Whitman et al. 2018
  • Chlorobiota:
    • "Chlorobia" Whitman et al. 2018
    • Chlorobea Cavalier-Smith 2002
    • "Chlorobiia" Cavalier-Smith 2020
  • Chlorobiales:
    • "Chlorobiales" Garrity and Holt 2001

Green sulfur bacteria are nonmotile (except Chloroherpeton thalassium, which may glide) and capable of anoxygenic photosynthesis.[5][6] They live in anaerobic aquatic environments.[7] In contrast to plants, green sulfur bacteria mainly use sulfide ions as electron donors.[8] They are autotrophs that utilize the reverse tricarboxylic acid cycle to perform carbon fixation.[9] They are also mixotrophs and reduce nitrogen.[10][11]

Characteristics edit

Green sulfur bacteria are gram-negative rod or spherical shaped bacteria. Some types of green sulfur bacteria have gas vacuoles that allow for movement. They are photolithoautotrophs, and use light energy and reduced sulfur compounds as the electron source.[12] Electron donors include H2, H2S, S. The major photosynthetic pigment in these bacteria is Bacteriochlorophylls c or d in green species and e in brown species, and is located in the chlorosomes and plasma membranes.[7] Chlorosomes are a unique feature that allow them to capture light in low-light conditions.[13]

Habitat edit

The majority of green sulfur bacteria are mesophilic, preferring moderate temperatures, and all live in aquatic environments. They require anaerobic conditions and reduced sulfur; they are usually found in the top millimeters of sediment. They are capable of photosynthesis in low light conditions.[7]

The Black Sea, an extremely anoxic environment, was found to house a large population of green sulfur bacteria at about 100 m depth. Due to the lack of light available in this region of the sea, most bacteria were photosynthetically inactive. The photosynthetic activity detected in the sulfide chemocline suggests that the bacteria need very little energy for cellular maintenance.[14]

A species of green sulfur bacteria has been found living near a black smoker off the coast of Mexico at a depth of 2,500 m in the Pacific Ocean. At this depth, the bacterium, designated GSB1, lives off the dim glow of the thermal vent since no sunlight can penetrate to that depth.[15]

Green sulfur bacteria has also been found living on coral reef colonies in Taiwan, they make up the majority of a "green layer" on these colonies. They likely play a role in the coral system, and there could be a symbiotic relationship between the bacteria and the coral host.[16] The coral could provide an anaerobic environment and  a source of carbon for the bacteria. The bacteria can provide nutrients and detoxify the coral by oxidizing sulfide.[17]

One type of green sulfur bacteria, Chlorobaculum tepidum, has been found in sulfur springs. These organisms are thermophilic, unlike most other green sulfur bacteria.[7]

Phylogeny edit

16S rRNA based LTP_08_2023[18][19][20] 120 marker proteins based GTDB 08-RS214[21][22][23]
Chlorobiaceae

Chloroherpeton thalassium

Prosthecochloris

P. aestuarii

P. marina

P. vibrioformis

Chlorobaculum

Chlorobaculum tepidum

C. thiosulfatiphilum

"Chlorobaculum chlorovibrioides"

Chlorobaculum parvum

Chlorobium

C. luteolum

C. limicola

C. phaeovibrioides

C. clathratiforme

. phaeobacteroides

Chlorobiales
"Thermochlorobacteraceae"

Chloroherpeton thalassium Gibson et al. 1985

"Ca. Thermochlorobacter aerophilum" Liu et al. 2012b

Chlorobiaceae
Prosthecochloris

P. marina Bryantseva et al. 2020

P. vibrioformis (Pelsh 1936) Imhoff 2003

P. aestuarii Gorlenko 1970 (type sp.)

P. ethylica Shaposhnikov, Kondrateva & Federov 1959 ex Kyndt, Van Beeumen & Meyer 2020

Chlorobaculum

C. parvum Imhoff 2003

C. tepidum (Wahlund et al. 1996) Imhoff 2003 (type sp.)

C. limnaeum Imhoff 2003

C. thiosulfatiphilum Imhoff 2022

Chlorobium

C. limicola Nadson 1906 emend. Imhoff 2003 (type sp.)

C. phaeobacteroides Pfennig 1968

C. luteolum (Schmidle 1901) emend. Imhoff 2003

C. phaeovibrioides Pfennig 1968

"C. chlorochromatii" Meschner 1957 ex Vogl et al. 2006

C. clathratiforme (Szafer 1911) Imhoff 2003

"C. ferrooxidans" Heising et al. 1998

"Ca. C. masyuteum" Lambrecht et al. 2021

Taxonomy edit

  • Family Chlorobiaceae Copeland 1956 ["Chlorobacteriaceae" Geitler & Pascher 1925]
    • ?Ancalochloris Gorlenko and Lebedeva 1971
    • Chlorobaculum Imhoff 2003
    • Chlorobium Nadson 1906
    • ?"Chloroplana" Dubinina and Gorlenko 1975
    • ?"Clathrochloris" Geitler 1925
    • Prosthecochloris Gorlenko 1970
  • Family "Thermochlorobacteriaceae" corrig. Liu et al. 2012 ["Chloroherpetonaceae" Bello et al. 2022]
    • Chloroherpeton Gibson et al. 1985
    • "Ca. Thermochlorobacter" Liu et al. 2012

Specific characteristics of genera edit

Green sulfur bacteria are family Chlorobiaceae. There are four genera; Chloroherpeton, Prosthecochloris, Chlorobium and Chlorobaculum. Characteristics used to distinguish between these genera include some metabolic properties, pigments, cell morphology and absorption spectra. However, it is difficult to distinguish these properties and therefore the taxonomic division is sometimes unclear.[24]

Generally, Chlorobium are rod or vibroid shaped and some species contain gas vesicles. They can develop as single or aggregate cells. They can be green or dark brown. The green strains use photosynthetic pigments Bchl c or d with chlorobactene carotenoids and the brown strains use photosynthetic pigment  Bchl e with isorenieratene carotenoids. Low amounts of salt are required for growth.[24]

Prosthecochloris are made up of vibroid, ovid or rod shaped cells. They start as single cells that form appendages that do not branch, referred to as non-branching prosthecae. They can also form gas vesicles. The photosynthetic pigments present include Bchl c, d or e. Furthermore, salt is necessary for growth.[24]

Chlorobaculum develop as single cells and are generally vibroid or rod-shaped. Some of these can form gas vesicles. The photosynthetic pigments in this genus are Bchl c, d or e. Some species require NaCl (sodium chloride) for growth. Members of this genus used to be a part of the genus Chlorobium, but have formed a separate lineage.[24]

The genus Chloroherpeton is unique because members of this genus are motile. They are flexing long rods, and can move by gliding. They are green in color and contain the photosynthetic pigment Bchl c as well as γ-carotene. Salt is required for growth.[24]

Metabolism edit

Photosynthesis edit

The green sulfur bacteria use a Type I reaction center for photosynthesis. Type I reaction centers are the bacterial homologue of photosystem I (PSI) in plants and cyanobacteria. The GSB reaction centers contain bacteriochlorophyll a and are known as P840 reaction centers due to the excitation wavelength of 840 nm that powers the flow of electrons. In green sulfur bacteria the reaction center is associated with a large antena complex called the chlorosome that captures and funnels light energy to the reaction center. The chlorosomes have a peak absorption in the far red region of the spectrum between 720 and 750 nm because they contain bacteriochlorophyll c, d and e.[25] A protein complex called the Fenna-Matthews-Olson complex (FMO) is physically located between the chlorosomes and the P840 RC. The FMO complex helps efficiently transfer the energy absorbed by the antena to the reaction center.

PSI and Type I reaction centers are able to reduce ferredoxin (Fd), a strong reductant that can be used to fix CO
2 and reduce NADPH. Once the reaction center (RC) has given an electron to Fd it becomes an oxidizing agent (P840+) with a reduction potential of around +300 mV. While this is not positive enough to strip electrons from water to synthesize O
2 (E
0 = +820 mV), it can accept electrons from other sources like H
2S, thiosulphate or Fe2+
 ions.[26] This transport of electrons from donors like H
2S to the acceptor Fd is called linear electron flow or linear electron transport. The oxidation of sulfide ions leads to the production of sulfur as a waste product that accumulates as globules on the extracellular side of the membrane. These globules of sulfur give green sulfur bacteria their name. When sulfide is depleted, the sulfur globules are consumed and further oxidized to sulfate. However, the pathway of sulfur oxidation is not well-understood.[8]

Instead of passing the electrons onto Fd, the Fe-S clusters in the P840 reaction center can transfer the electrons to menaquinone (MQ:MQH
2) which returns the electrons to the P840+ via an electron transport chain (ETC). On the way back to the RC the electrons from MQH2 pass through a cytochrome bc1 complex (similar to the complex III of mitochondria) that pumps H+
 ions across the membrane. The electrochemical potential of the protons across the membrane is used to synthesize ATP by the FoF1 ATP synthase. This cyclic electron transport is responsible for converting light energy into cellular energy in the form of ATP.[25]

Sulfur metabolism edit

Green sulfur bacteria oxidize inorganic sulfur compounds to use as electron donors for anaerobic photosynthesis, specifically in carbon dioxide fixation. They usually prefer to utilize sulfide over other sulfur compounds as an electron donor, however they can utilize thiosulfate or H2.[27] The intermediate is usually sulfur, which is deposited outside of the cell,[28] and the end product is sulfate. The sulfur, which is deposited extracellularly, is in the form of sulfur globules, which can be later oxidized completely.[27]

The mechanisms of sulfur oxidation in green sulfur bacteria are not well characterized. Some enzymes thought to be involved in sulfide oxidation include flavocytochrome c, sulfide:quinone oxidoreductase and the SO
x system. Flavocytochrome can catalyze the transfer of electrons to cytochromes from sulfide, and these cytochromes could then move the electrons to the photosynthetic reaction center. However, not all green sulfur bacteria produce this enzyme, demonstrating that it is not needed for the oxidation of sulfide. Sulfide:quinone oxidoreductase (SQR) also helps with electron transport, but, when alone, has been found to produce decreased rates of sulfide oxidation in green sulfur bacteria, suggesting that there is a different, more effective mechanism.[27] However, most green sulfur bacteria contain a homolog of the SQR gene.[29] The oxidation of thiosulfate to sulfate could be catalyzed by the enzymes in the SO
x system.[27]

It is thought that the enzymes and genes related to sulfur metabolism were obtained via horizontal gene transfer during the evolution of green sulfur bacteria.[29]

Carbon fixation edit

Green sulfur bacteria are photoautotrophs: they not only get energy from light, they can grow using carbon dioxide as their sole source of carbon. They fix carbon dioxide using the reverse tricarboxylic acid cycle (rTCA) cycle[9] where energy is consumed to reduce carbon dioxide, rather than oxidize as seen in the forward TCA cycle,[9] in order to synthesize pyruvate and acetate. These molecules are used as the raw materials to synthesize all the building blocks a cell needs to generate macromolecules. The rTCA cycle is highly energy efficient enabling the bacteria to grow under low light conditions.[30] However it has several oxygen sensitive enzymes that limits its efficiency in aerobic conditions.[30]

 
Reductive TCA Cycle Diagram

The reactions of reversal of the oxidative tricarboxylic acid cycle are catalyzed by four enzymes:[9]

  1. pyruvate:ferredoxin (Fd) oxidoreductase:
    acetyl-CoA + CO2 + 2Fdred + 2H+ ⇌ pyruvate + CoA + 2Fdox
  2. ATP citrate lyase:
    ACL, acetyl-CoA + oxaloacetate + ADP + Pi ⇌ citrate + CoA + ATP
  3. α-keto-glutarate:ferredoxin oxidoreductase:
    succinyl-CoA + CO2 + 2Fdred + 2H+ ⇌ α-ketoglutarate + CoA + 2Fdox
  4. fumarare reductase
    succinate + acceptor ⇌ fumarate + reduced acceptor

However, the oxidative TCA cycle (OTCA) still is present in green sulfur bacteria. The OTCA can assimilate acetate, however the OTCA appears to be incomplete in green sulfur bacteria due to the location and down regulation of the gene during phototrophic growth.[9]

Mixotrophy edit

Green sulfur bacteria are often referred to as obligate photoautotrophs as they cannot grow in the absence of light even if they are provided with organic matter.[9][26] However they exhibit a form of mixotrophy where they can consume simple organic compounds in the presence of light and CO2.[9] In the presence of CO2 or HCO3, some green sulfur bacteria can utilize acetate or pyruvate.[9]

Mixotrophy in green sulfur bacteria is best modeled by the representative green sulfur bacterium Chlorobaculum tepidum.[31] Mixotrophy occurs during amino acid biosynthesis/carbon utilization and energy metabolism.[32] The bacterium uses electrons, generated from the oxidation of sulfur, and the energy it captures from light to run the rTCA. C. tepidum also exhibits use of both pyruvate and acetate as an organic carbon source.[32]

An example of mixotrophy in C. tepidum that combines autotrophy and heterotrophy is in its synthesis of acetyl-CoA. C. tepidum can autotrophically generate acetyl-CoA through the rTCA cycle, or it can heterotrophically generate it from the uptake of acetate. Similar mixotrophic activity occurs when pyruvate is used for amino acid biosynthesis, but mixotrophic growth using acetate yields higher growth rates.[31][32]

In energy metabolism, C. tepidum relies on light reactions to produce energy (NADPH and NADH) because the pathways typically responsible for energy production (oxidative pentose phosphate pathway and normal TCA cycle) are only partly functional.[32] Photons absorbed from the light are used to produce NADPH and NADH, the cofactors of energy metabolism. C. tepidum also generates energy in the form of ATP using the proton motive force derived from sulfide oxidation.[31] Energy production from both sulfide oxidation and photon absorption via bacteriochlorophylls.[32]

Nitrogen fixation edit

The majority of green sulfur bacteria are diazotrophs: they can reduce nitrogen to ammonia which is then used to synthesize amino acids.[33] Nitrogen fixation among green sulfur bacteria is generally typical of an anoxygenic phototroph, and requires the presence of light. Green sulfur bacteria exhibit activity from a Type-1 secretion system and a ferredoxin-NADP+ oxidoreductase to generate reduced iron, a trait that evolved to support nitrogen fixation.[34] Like purple sulfur bacteria, they can regulate the activity of nitrogenase post-translationally in response to ammonia concentrations. Their possession of nif genes, even though evolutionarily distinct, may suggest their nitrogen fixation abilities arose in two different events or through a shared very distant ancestor.[35]

Examples of green sulfur bacteria capable of nitrogen fixation include the genus Chlorobium and Pelodictyon, excluding P. phaeoclathratiforme. Prosthecochloris aestuarii and Chloroherpeton thalassium also fall into this category.[35] Their N2 fixation is widespread and plays an important role in overall nitrogen availability for ecosystems. Green sulfur bacteria living in coral reefs, such as Prosthecochloris, are crucial in generating available nitrogen in the already nutrient-limited environment.[36]

See also edit

References edit

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  36. ^ Yang, Shan-Hua; Lee, Sonny T. M.; Huang, Chang-Rung; Tseng, Ching-Hung; Chiang, Pei-Wen; Chen, Chung-Pin; Chen, Hsing-Ju; Tang, Sen-Lin (May 2016). "Prevalence of potential nitrogen-fixing, green sulfur bacteria in the skeleton of reef-building coral Isopora palifera: Endolithic bacteria in coral skeletons". Limnology and Oceanography. 61 (3): 1078–1086. Bibcode:2016LimOc..61.1078Y. doi:10.1002/lno.10277. S2CID 87463811.

External links edit

  • . The Prokaryotes. Archived from the original on November 17, 2003. Retrieved July 5, 2005.

February 15, 2024
green, sulfur, bacteria, green, sulfur, bacteria, phylum, chlorobiota, obligately, anaerobic, photoautotrophic, bacteria, that, metabolize, sulfur, winogradsky, columnscientific, classificationdomain, bacteria, unranked, bacteroidota, chlorobiota, groupphylum,. The green sulfur bacteria are a phylum Chlorobiota 4 of obligately anaerobic photoautotrophic bacteria that metabolize sulfur 5 Green sulfur bacteriaGreen sulfur bacteria in a Winogradsky columnScientific classificationDomain Bacteria unranked Bacteroidota Chlorobiota groupPhylum ChlorobiotaIino et al 2021 3 Class Chlorobia Garrity and Holt 2001 2 Order ChlorobialesGibbons and Murray 1978 Approved Lists 1980 1 Families and GeneraChlorobiaceae Thermochlorobacteriaceae SynonymsChlorobiota Chlorobi Iino et al 2010 Chlorobi Garrity and Holt 2001 Chlorobaeota Oren et al 2015 Chlorobiota Whitman et al 2018 Chlorobiota Chlorobia Whitman et al 2018 Chlorobea Cavalier Smith 2002 Chlorobiia Cavalier Smith 2020 Chlorobiales Chlorobiales Garrity and Holt 2001Green sulfur bacteria are nonmotile except Chloroherpeton thalassium which may glide and capable of anoxygenic photosynthesis 5 6 They live in anaerobic aquatic environments 7 In contrast to plants green sulfur bacteria mainly use sulfide ions as electron donors 8 They are autotrophs that utilize the reverse tricarboxylic acid cycle to perform carbon fixation 9 They are also mixotrophs and reduce nitrogen 10 11 Contents 1 Characteristics 2 Habitat 3 Phylogeny 3 1 Taxonomy 3 2 Specific characteristics of genera 4 Metabolism 4 1 Photosynthesis 4 2 Sulfur metabolism 4 3 Carbon fixation 4 4 Mixotrophy 4 5 Nitrogen fixation 5 See also 6 References 7 External linksCharacteristics editGreen sulfur bacteria are gram negative rod or spherical shaped bacteria Some types of green sulfur bacteria have gas vacuoles that allow for movement They are photolithoautotrophs and use light energy and reduced sulfur compounds as the electron source 12 Electron donors include H2 H2S S The major photosynthetic pigment in these bacteria is Bacteriochlorophylls c or d in green species and e in brown species and is located in the chlorosomes and plasma membranes 7 Chlorosomes are a unique feature that allow them to capture light in low light conditions 13 Habitat editThe majority of green sulfur bacteria are mesophilic preferring moderate temperatures and all live in aquatic environments They require anaerobic conditions and reduced sulfur they are usually found in the top millimeters of sediment They are capable of photosynthesis in low light conditions 7 The Black Sea an extremely anoxic environment was found to house a large population of green sulfur bacteria at about 100 m depth Due to the lack of light available in this region of the sea most bacteria were photosynthetically inactive The photosynthetic activity detected in the sulfide chemocline suggests that the bacteria need very little energy for cellular maintenance 14 A species of green sulfur bacteria has been found living near a black smoker off the coast of Mexico at a depth of 2 500 m in the Pacific Ocean At this depth the bacterium designated GSB1 lives off the dim glow of the thermal vent since no sunlight can penetrate to that depth 15 Green sulfur bacteria has also been found living on coral reef colonies in Taiwan they make up the majority of a green layer on these colonies They likely play a role in the coral system and there could be a symbiotic relationship between the bacteria and the coral host 16 The coral could provide an anaerobic environment and a source of carbon for the bacteria The bacteria can provide nutrients and detoxify the coral by oxidizing sulfide 17 One type of green sulfur bacteria Chlorobaculum tepidum has been found in sulfur springs These organisms are thermophilic unlike most other green sulfur bacteria 7 Phylogeny edit16S rRNA based LTP 08 2023 18 19 20 120 marker proteins based GTDB 08 RS214 21 22 23 Chlorobiaceae Chloroherpeton thalassiumProsthecochloris P aestuariiP marinaP vibrioformisChlorobaculum Chlorobaculum tepidumC thiosulfatiphilum Chlorobaculum chlorovibrioides Chlorobaculum parvumChlorobium C luteolumC limicolaC phaeovibrioidesC clathratiforme phaeobacteroides Chlorobiales Thermochlorobacteraceae Chloroherpeton thalassium Gibson et al 1985 Ca Thermochlorobacter aerophilum Liu et al 2012bChlorobiaceae Prosthecochloris P marina Bryantseva et al 2020P vibrioformis Pelsh 1936 Imhoff 2003P aestuarii Gorlenko 1970 type sp P ethylica Shaposhnikov Kondrateva amp Federov 1959 ex Kyndt Van Beeumen amp Meyer 2020Chlorobaculum C parvum Imhoff 2003C tepidum Wahlund et al 1996 Imhoff 2003 type sp C limnaeum Imhoff 2003C thiosulfatiphilum Imhoff 2022Chlorobium C limicola Nadson 1906 emend Imhoff 2003 type sp C phaeobacteroides Pfennig 1968C luteolum Schmidle 1901 emend Imhoff 2003C phaeovibrioides Pfennig 1968 C chlorochromatii Meschner 1957 ex Vogl et al 2006C clathratiforme Szafer 1911 Imhoff 2003 C ferrooxidans Heising et al 1998 Ca C masyuteum Lambrecht et al 2021Taxonomy edit Family Chlorobiaceae Copeland 1956 Chlorobacteriaceae Geitler amp Pascher 1925 Ancalochloris Gorlenko and Lebedeva 1971 Chlorobaculum Imhoff 2003 Chlorobium Nadson 1906 Chloroplana Dubinina and Gorlenko 1975 Clathrochloris Geitler 1925 Prosthecochloris Gorlenko 1970 Family Thermochlorobacteriaceae corrig Liu et al 2012 Chloroherpetonaceae Bello et al 2022 Chloroherpeton Gibson et al 1985 Ca Thermochlorobacter Liu et al 2012Specific characteristics of genera edit Green sulfur bacteria are family Chlorobiaceae There are four genera Chloroherpeton Prosthecochloris Chlorobium and Chlorobaculum Characteristics used to distinguish between these genera include some metabolic properties pigments cell morphology and absorption spectra However it is difficult to distinguish these properties and therefore the taxonomic division is sometimes unclear 24 Generally Chlorobium are rod or vibroid shaped and some species contain gas vesicles They can develop as single or aggregate cells They can be green or dark brown The green strains use photosynthetic pigments Bchl c or d with chlorobactene carotenoids and the brown strains use photosynthetic pigment Bchl e with isorenieratene carotenoids Low amounts of salt are required for growth 24 Prosthecochloris are made up of vibroid ovid or rod shaped cells They start as single cells that form appendages that do not branch referred to as non branching prosthecae They can also form gas vesicles The photosynthetic pigments present include Bchl c d or e Furthermore salt is necessary for growth 24 Chlorobaculum develop as single cells and are generally vibroid or rod shaped Some of these can form gas vesicles The photosynthetic pigments in this genus are Bchl c d or e Some species require NaCl sodium chloride for growth Members of this genus used to be a part of the genus Chlorobium but have formed a separate lineage 24 The genus Chloroherpeton is unique because members of this genus are motile They are flexing long rods and can move by gliding They are green in color and contain the photosynthetic pigment Bchl c as well as g carotene Salt is required for growth 24 Metabolism editPhotosynthesis edit The green sulfur bacteria use a Type I reaction center for photosynthesis Type I reaction centers are the bacterial homologue of photosystem I PSI in plants and cyanobacteria The GSB reaction centers contain bacteriochlorophyll a and are known as P840 reaction centers due to the excitation wavelength of 840 nm that powers the flow of electrons In green sulfur bacteria the reaction center is associated with a large antena complex called the chlorosome that captures and funnels light energy to the reaction center The chlorosomes have a peak absorption in the far red region of the spectrum between 720 and 750 nm because they contain bacteriochlorophyll c d and e 25 A protein complex called the Fenna Matthews Olson complex FMO is physically located between the chlorosomes and the P840 RC The FMO complex helps efficiently transfer the energy absorbed by the antena to the reaction center PSI and Type I reaction centers are able to reduce ferredoxin Fd a strong reductant that can be used to fix CO2 and reduce NADPH Once the reaction center RC has given an electron to Fd it becomes an oxidizing agent P840 with a reduction potential of around 300 mV While this is not positive enough to strip electrons from water to synthesize O2 E0 820 mV it can accept electrons from other sources like H2 S thiosulphate or Fe2 ions 26 This transport of electrons from donors like H2 S to the acceptor Fd is called linear electron flow or linear electron transport The oxidation of sulfide ions leads to the production of sulfur as a waste product that accumulates as globules on the extracellular side of the membrane These globules of sulfur give green sulfur bacteria their name When sulfide is depleted the sulfur globules are consumed and further oxidized to sulfate However the pathway of sulfur oxidation is not well understood 8 Instead of passing the electrons onto Fd the Fe S clusters in the P840 reaction center can transfer the electrons to menaquinone MQ MQH2 which returns the electrons to the P840 via an electron transport chain ETC On the way back to the RC the electrons from MQH2 pass through a cytochrome bc1 complex similar to the complex III of mitochondria that pumps H ions across the membrane The electrochemical potential of the protons across the membrane is used to synthesize ATP by the FoF1 ATP synthase This cyclic electron transport is responsible for converting light energy into cellular energy in the form of ATP 25 Sulfur metabolism edit Green sulfur bacteria oxidize inorganic sulfur compounds to use as electron donors for anaerobic photosynthesis specifically in carbon dioxide fixation They usually prefer to utilize sulfide over other sulfur compounds as an electron donor however they can utilize thiosulfate or H2 27 The intermediate is usually sulfur which is deposited outside of the cell 28 and the end product is sulfate The sulfur which is deposited extracellularly is in the form of sulfur globules which can be later oxidized completely 27 The mechanisms of sulfur oxidation in green sulfur bacteria are not well characterized Some enzymes thought to be involved in sulfide oxidation include flavocytochrome c sulfide quinone oxidoreductase and the SOx system Flavocytochrome can catalyze the transfer of electrons to cytochromes from sulfide and these cytochromes could then move the electrons to the photosynthetic reaction center However not all green sulfur bacteria produce this enzyme demonstrating that it is not needed for the oxidation of sulfide Sulfide quinone oxidoreductase SQR also helps with electron transport but when alone has been found to produce decreased rates of sulfide oxidation in green sulfur bacteria suggesting that there is a different more effective mechanism 27 However most green sulfur bacteria contain a homolog of the SQR gene 29 The oxidation of thiosulfate to sulfate could be catalyzed by the enzymes in the SOx system 27 It is thought that the enzymes and genes related to sulfur metabolism were obtained via horizontal gene transfer during the evolution of green sulfur bacteria 29 Carbon fixation edit Green sulfur bacteria are photoautotrophs they not only get energy from light they can grow using carbon dioxide as their sole source of carbon They fix carbon dioxide using the reverse tricarboxylic acid cycle rTCA cycle 9 where energy is consumed to reduce carbon dioxide rather than oxidize as seen in the forward TCA cycle 9 in order to synthesize pyruvate and acetate These molecules are used as the raw materials to synthesize all the building blocks a cell needs to generate macromolecules The rTCA cycle is highly energy efficient enabling the bacteria to grow under low light conditions 30 However it has several oxygen sensitive enzymes that limits its efficiency in aerobic conditions 30 nbsp Reductive TCA Cycle DiagramThe reactions of reversal of the oxidative tricarboxylic acid cycle are catalyzed by four enzymes 9 pyruvate ferredoxin Fd oxidoreductase acetyl CoA CO2 2Fdred 2H pyruvate CoA 2Fdox ATP citrate lyase ACL acetyl CoA oxaloacetate ADP Pi citrate CoA ATP a keto glutarate ferredoxin oxidoreductase succinyl CoA CO2 2Fdred 2H a ketoglutarate CoA 2Fdox fumarare reductase succinate acceptor fumarate reduced acceptorHowever the oxidative TCA cycle OTCA still is present in green sulfur bacteria The OTCA can assimilate acetate however the OTCA appears to be incomplete in green sulfur bacteria due to the location and down regulation of the gene during phototrophic growth 9 Mixotrophy edit Green sulfur bacteria are often referred to as obligate photoautotrophs as they cannot grow in the absence of light even if they are provided with organic matter 9 26 However they exhibit a form of mixotrophy where they can consume simple organic compounds in the presence of light and CO2 9 In the presence of CO2 or HCO3 some green sulfur bacteria can utilize acetate or pyruvate 9 Mixotrophy in green sulfur bacteria is best modeled by the representative green sulfur bacterium Chlorobaculum tepidum 31 Mixotrophy occurs during amino acid biosynthesis carbon utilization and energy metabolism 32 The bacterium uses electrons generated from the oxidation of sulfur and the energy it captures from light to run the rTCA C tepidum also exhibits use of both pyruvate and acetate as an organic carbon source 32 An example of mixotrophy in C tepidum that combines autotrophy and heterotrophy is in its synthesis of acetyl CoA C tepidum can autotrophically generate acetyl CoA through the rTCA cycle or it can heterotrophically generate it from the uptake of acetate Similar mixotrophic activity occurs when pyruvate is used for amino acid biosynthesis but mixotrophic growth using acetate yields higher growth rates 31 32 In energy metabolism C tepidum relies on light reactions to produce energy NADPH and NADH because the pathways typically responsible for energy production oxidative pentose phosphate pathway and normal TCA cycle are only partly functional 32 Photons absorbed from the light are used to produce NADPH and NADH the cofactors of energy metabolism C tepidum also generates energy in the form of ATP using the proton motive force derived from sulfide oxidation 31 Energy production from both sulfide oxidation and photon absorption via bacteriochlorophylls 32 Nitrogen fixation edit The majority of green sulfur bacteria are diazotrophs they can reduce nitrogen to ammonia which is then used to synthesize amino acids 33 Nitrogen fixation among green sulfur bacteria is generally typical of an anoxygenic phototroph and requires the presence of light Green sulfur bacteria exhibit activity from a Type 1 secretion system and a ferredoxin NADP oxidoreductase to generate reduced iron a trait that evolved to support nitrogen fixation 34 Like purple sulfur bacteria they can regulate the activity of nitrogenase post translationally in response to ammonia concentrations Their possession of nif genes even though evolutionarily distinct may suggest their nitrogen fixation abilities arose in two different events or through a shared very distant ancestor 35 Examples of green sulfur bacteria capable of nitrogen fixation include the genus Chlorobium and Pelodictyon excluding P phaeoclathratiforme Prosthecochloris aestuarii and Chloroherpeton thalassium also fall into this category 35 Their N2 fixation is widespread and plays an important role in overall nitrogen availability for ecosystems Green sulfur bacteria living in coral reefs such as Prosthecochloris are crucial in generating available nitrogen in the already nutrient limited environment 36 See also editAnoxic event Purple sulfur bacteria Green non sulfur bacteria List of bacteria genera List of bacterial orderReferences edit Gibbons NE Murray RGE 1978 Proposals Concerning the Higher Taxa of Bacteria International Journal of Systematic Bacteriology 28 1 6 doi 10 1099 00207713 28 1 1 Garrity GM Holt JG 2001 Phylum BXI Chlorobi phy nov In Boone DR Castenholz RW Garrity GM eds Bergey s Manual of Systematic Bacteriology Vol 1 The Archaea and the deeply branching and phototrophic Bacteria 2nd ed New York NY Springer Verlag pp 601 623 Oren A Garrity GM 2021 Valid publication of the names of forty two phyla of prokaryotes Int J Syst Evol Microbiol 71 10 5056 doi 10 1099 ijsem 0 005056 PMID 34694987 S2CID 239887308 Phylum Chlorobiota List of Prokaryotic Names with Standing in Nomenclature 25907 Retrieved 22 August 2023 a b Bryant DA Frigaard NU November 2006 Prokaryotic photosynthesis and phototrophy illuminated Trends in Microbiology 14 11 488 96 doi 10 1016 j tim 2006 09 001 PMID 16997562 Green BR 2003 Light Harvesting Antennas in Photosynthesis p 8 ISBN 0792363353 a b c d Kushkevych Ivan Prochazka Jiri Gajdacs Mario Rittmann Simon K M R Vitezova Monika 2021 06 15 Molecular Physiology of Anaerobic Phototrophic Purple and Green Sulfur Bacteria International Journal of Molecular Sciences 22 12 6398 doi 10 3390 ijms22126398 ISSN 1422 0067 PMC 8232776 PMID 34203823 a b Sakurai H Ogawa T Shiga M Inoue K June 2010 Inorganic sulfur oxidizing system in green sulfur bacteria Photosynthesis Research 104 2 3 163 76 doi 10 1007 s11120 010 9531 2 PMID 20143161 S2CID 1091791 a b c d e f g h Tang KH Blankenship RE November 2010 Both forward and reverse TCA cycles operate in green sulfur bacteria The Journal of Biological Chemistry 285 46 35848 54 doi 10 1074 jbc M110 157834 PMC 2975208 PMID 20650900 Wahlund Thomas 1993 Nitrogen Fixation by the Thermophilic Green Sulfur Bacterium Chlorobium tepidum Journal of Bacteriology 175 2 474 478 doi 10 1128 jb 175 2 474 478 1993 PMC 196162 PMID 8093448 Feng Xueyang Tang Kuo Hsiang Blankenship Robert E Tang Yinjie J 2010 12 10 Metabolic Flux Analysis of the Mixotrophic Metabolisms in the Green Sulfur Bacterium Chlorobaculum tepidum Journal of Biological Chemistry 285 50 39544 39550 doi 10 1074 jbc M110 162958 ISSN 0021 9258 PMC 2998096 PMID 20937805 Green Sulfur Bacteria an overview ScienceDirect Topics www sciencedirect com Retrieved 2022 04 22 John Wiley amp Sons Ltd ed 2001 05 30 eLS 1 ed Wiley doi 10 1002 9780470015902 a0000458 pub2 ISBN 978 0 470 01617 6 S2CID 82067054 Marschall E Jogler M Hessge U Overmann J May 2010 Large scale distribution and activity patterns of an extremely low light adapted population of green sulfur bacteria in the Black Sea Environmental Microbiology 12 5 1348 62 doi 10 1111 j 1462 2920 2010 02178 x PMID 20236170 Beatty JT Overmann J Lince MT Manske AK Lang AS Blankenship RE Van Dover CL Martinson TA Plumley FG June 2005 An obligately photosynthetic bacterial anaerobe from a deep sea hydrothermal vent Proceedings of the National Academy of Sciences of the United States of America 102 26 9306 10 Bibcode 2005PNAS 102 9306B doi 10 1073 pnas 0503674102 PMC 1166624 PMID 15967984 Yang Shan Hua Lee Sonny T M Huang Chang Rung Tseng Ching Hung Chiang Pei Wen Chen Chung Pin Chen Hsing Ju Tang Sen Lin 2016 02 26 Prevalence of potential nitrogen fixing green sulfur bacteria in the skeleton of reef building coral Isopora palifera Limnology and Oceanography 61 3 1078 1086 Bibcode 2016LimOc 61 1078Y doi 10 1002 lno 10277 ISSN 0024 3590 S2CID 87463811 Cai Lin Zhou Guowei Tian Ren Mao Tong Haoya Zhang Weipeng Sun Jin Ding Wei Wong Yue Him Xie James Y Qiu Jian Wen Liu Sheng 2017 08 24 Metagenomic analysis reveals a green sulfur bacterium as a potential coral symbiont Scientific Reports 7 1 9320 Bibcode 2017NatSR 7 9320C doi 10 1038 s41598 017 09032 4 ISSN 2045 2322 PMC 5571212 PMID 28839161 The LTP Retrieved 20 November 2023 LTP all tree in newick format Retrieved 20 November 2023 LTP 08 2023 Release Notes PDF Retrieved 20 November 2023 GTDB release 08 RS214 Genome Taxonomy Database Retrieved 10 May 2023 bac120 r214 sp label Genome Taxonomy Database Retrieved 10 May 2023 Taxon History Genome Taxonomy Database Retrieved 10 May 2023 a b c d e Bryantseva Irina A Tarasov Alexey L Kostrikina Nadezhda A Gaisin Vasil A Grouzdev Denis S Gorlenko Vladimir M 2019 12 01 Prosthecochloris marina sp nov a new green sulfur bacterium from the coastal zone of the South China Sea Archives of Microbiology 201 10 1399 1404 doi 10 1007 s00203 019 01707 y ISSN 1432 072X PMID 31338544 S2CID 198190182 a b Hauska G Schoedl T Remigy H Tsiotis G October 2001 The reaction center of green sulfur bacteria 1 Biochimica et Biophysica Acta 1507 1 3 260 77 doi 10 1016 S0005 2728 01 00200 6 PMID 11687219 a b Ligrone Roberto 2019 Moving to the Light The Evolution of Photosynthesis In Roberto Ligrone ed Biological Innovations that Built the World A Four billion year Journey through Life and Earth History Cham Springer International Publishing pp 99 127 doi 10 1007 978 3 030 16057 9 4 ISBN 978 3 030 16057 9 S2CID 189992218 Retrieved 2021 01 29 a b c d Frigaard Niels Ulrik Dahl Christiane 2008 01 01 Poole Robert K ed Sulfur Metabolism in Phototrophic Sulfur Bacteria Advances in Microbial Physiology Academic Press vol 54 pp 103 200 retrieved 2022 04 22 van Gemerden Hans 1986 10 01 Production of elemental sulfur by green and purple sulfur bacteria Archives of Microbiology 146 1 52 56 doi 10 1007 BF00690158 ISSN 1432 072X S2CID 30812886 a b Gregersen Lea Bryant Donald Frigaard Niels Ulrik 2011 Mechanisms and Evolution of Oxidative Sulfur Metabolism in Green Sulfur Bacteria Frontiers in Microbiology 2 116 doi 10 3389 fmicb 2011 00116 ISSN 1664 302X PMC 3153061 PMID 21833341 a b Bar Even Arren Noor Elad Milo Ron 2012 A survey of carbon fixation pathways through a quantitative lens Journal of Experimental Botany 63 6 2325 2342 doi 10 1093 jxb err417 ISSN 1460 2431 PMID 22200662 a b c Frigaard Niels Ulrik Chew Aline Gomez Maqueo Li Hui Maresca Julia A Bryant Donald A 2003 Chlorobium Tepidum Insights into the Structure Physiology and Metabolism of a Green Sulfur Bacterium Derived from the Complete Genome Sequence Photosynthesis Research 78 2 93 117 doi 10 1023 B PRES 0000004310 96189 b4 ISSN 0166 8595 PMID 16245042 S2CID 30218833 a b c d e Feng Xueyang Tang Kuo Hsiang Blankenship Robert E Tang Yinjie J 2010 12 10 Metabolic Flux Analysis of the Mixotrophic Metabolisms in the Green Sulfur Bacterium Chlorobaculum tepidum Journal of Biological Chemistry 285 50 39544 39550 doi 10 1074 jbc M110 162958 ISSN 0021 9258 PMC 2998096 PMID 20937805 Madigan Michael T 1995 Microbiology of Nitrogen Fixation by Anoxygenic Photosynthetic Bacteria In Robert E Blankenship Michael T Madigan Carl E Bauer eds Anoxygenic Photosynthetic Bacteria Advances in Photosynthesis and Respiration Vol 2 Dordrecht Springer Netherlands pp 915 928 doi 10 1007 0 306 47954 0 42 ISBN 978 0 306 47954 0 Mus Florence Colman Daniel R Peters John W Boyd Eric S 2019 08 20 Geobiological feedbacks oxygen and the evolution of nitrogenase Free Radical Biology and Medicine Early Life on Earth and Oxidative Stress 140 250 259 doi 10 1016 j freeradbiomed 2019 01 050 ISSN 0891 5849 PMID 30735835 S2CID 73433517 a b Madigan Michael T 1995 Blankenship Robert E Madigan Michael T Bauer Carl E eds Microbiology of Nitrogen Fixation by Anoxygenic Photosynthetic Bacteria Anoxygenic Photosynthetic Bacteria Advances in Photosynthesis and Respiration Dordrecht Springer Netherlands vol 2 pp 915 928 doi 10 1007 0 306 47954 0 42 ISBN 978 0 306 47954 0 retrieved 2022 05 01 Yang Shan Hua Lee Sonny T M Huang Chang Rung Tseng Ching Hung Chiang Pei Wen Chen Chung Pin Chen Hsing Ju Tang Sen Lin May 2016 Prevalence of potential nitrogen fixing green sulfur bacteria in the skeleton of reef building coral Isopora palifera Endolithic bacteria in coral skeletons Limnology and Oceanography 61 3 1078 1086 Bibcode 2016LimOc 61 1078Y doi 10 1002 lno 10277 S2CID 87463811 External links edit The Family Chlorobiaceae The Prokaryotes Archived from the original on November 17 2003 Retrieved July 5 2005 Retrieved from https en wikipedia org w index php title Green sulfur bacteria amp oldid 1191668730, wikipedia, wiki, book, books, library,

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