Desulfobulbus propionicus

Desulfobulbus propionicus
Scientific classification
Domain:	Bacteria
Phylum:	Thermodesulfobacteriota
Class:	Desulfobacteria
Order:	Desulfobacterales
Family:	Desulfobulbaceae
Genus:	Desulfobulbus
Species:	D. propionicus
Binomial name
	Desulfobulbus propionicus; Pagani et al. 2011
Type strain
	1pr3T (DSM 2032, ATCC 33891, VKM B-1956)

Desulfobulbus propionicus is a Gram-negative, anaerobic chemoorganotroph.^[1]^[2] Three separate strains have been identified: 1pr3^T, 2pr4, and 3pr10.^[2] It is also the first pure culture example of successful disproportionation of elemental sulfur to sulfate and sulfide.^[3] Desulfobulbus propionicus has the potential to produce free energy (in the form of electrons) and chemical products.^[4]

Discovery

Desulfobulbus propionicus was discovered in 1982 by Friedrich Widdel and Norbert Pfenning.^[2] Desulfobulbus propionicus was isolated from samples taken from anaerobic mud in a village ditch, pond, and marine mud flat in Germany.^[2] All three strains were isolated using the agar shake dilution method on a basal medium with added sulfate, mineral salts, iron, trace elements, bicarbonate, sulfide, and seven vitamins.^[2]

Strain	Geographical Location^[2]	Habitat Type^[2]
1pr3^T	Lindhort, Germany	Freshwater ditch mud
2pr4	Hannover, Germany	Freshwater pond mud
3pr10	Jadebusen, Germany (North Sea)	Marine mud flat

Etymology

The genus Desulfobulbus can be derived from the Latin words -de meaning from, -sulfo meaning sulfur, and -bulbus meaning onion shaped literally meaning onion-shaped sulfate reducer.^[2] The species name propionicus is derived from the organisms electron donor propionate.^[2]

Taxonomic and phylogenetic description

Desulfobulbus propionicus possesses three strains: 1pr3^T, 2pr4, and 3pr10.^[2] Similarly, all three strains are Gram-negative, sulfur-reducers with the ability to grow exclusively on lactate or pyruvate without any external electron or carbon sources.^[2] What separates 1pr3^T from its sister strains is its ability to reduce sulfite and thiosulfate to hydrogen sulfide (H₂S); reduce nitrate to ammonia; lastly, its presence of cytochrome types b- and c-.^[2] Furthermore, strain 1pr3^T differentiated from the others in shape (1pr3^T possesses pointed ends compared to ovoid or ellipsoidal shaped ends), motility (1pr3^T lacks motility, whereas the others possess flagella), and the presence of fimbriae (2pr4 and 3pr10 strains do not).^[2]

In terms of the genus Desulfobulbus, the closest relatives of D. propionicus are D. elongatus with an identity of 96.9%, followed by D. rhabdoformis, and then D. mediterraneus and D. japonicas with equal relation respective to the phylogenetic tree constructed using 16S rRNA sequences.^[1]

Characterization

Morphology

Desulfobulbus propionicus is a Gram-negative, ellipsoidal to lemon-shaped bacteria, with an average length of 1.0 to 1.3μm and a width of 1.8 to 2.0μm.^[1] D. propionicus functions as an anaerobic chemoorganotroph.^[1] The three strains differ in shape, motility, and presence of fimbriae.^[2]

Strain	Shape	Motility	Fimbriae
1pr3^T	Lemon-shaped	Non-motile	+
2pr4	Ovoid	Single polar flagella	-
3pr10	Ellipsoidal	Single polar flagella	-

Metabolism

Desulfobulbus propionicus is an anaerobic chemoorganotroph.^[1] D. propionicus uses the methylmalony-CoA pathway to ferment 3 moles of pyruvate to 2 moles of acetate and 1 mole of propionate.^[1] Desulfobulbus propionicus utilizes propionate, lactate, pyruvate, and alcohols from the environment as not only electron sources, but for carbon sources as well.^[2] Hydrogen gas (H₂) is only utilized as an electron donor in the presence of carbon dioxide and acetate.^[2] As assumed by its name, Desulfobulbus propionicus reduces sulfate, sulfite, and thiosulfate to hydrogen sulfide (H₂S), but does not reduce elemental sulfur, malate, and fumarate.^[2] When sulfate is absent ethanol is fermented to propionate and acetate.^[1] In the absence of an electron acceptor, D. propionicus produces sulfate and sulfide from elemental sulfur and water.^[3] Also, Desulfobulbus propionicus strains 1pr3^T and 3pr10 can only grow in defined minimal media with the addition of a vitamin 4-aminobenzoic acid, whereas strain 2pr4 does not show this additional requirement.^[1]^[2] Furthermore, the 2pr4 strain is the only of the three to show growth with butyrate as an electron donor and carbon source, however, the growth is slow compared to other substrates.^[2]

Genome

Of the three strains within Desulfobulbus propionicus, 1pr3^T is the only to have its genome completely sequenced.^[1] It was sequenced in 2011 by Pagani et al.^[1] Strain 1pr3^T was found to encompass a genome size of 3,851,869 bp, with a G-C content of 58.93%.^[1] Pagani et al. predicted 3,408 genes in the genome of 1pr3^T, with 3,351 genes that encode proteins.^[1] The genome contains 57 RNA genes and two rRNA operons.^[1] Furthermore, there is 68 pseudo genes which makes up 2.0% of the total genome size.^[1]

Ecology

Desulfobulbus propionicus inhabits anaerobic freshwaters and marine sediments.^[1] Among the three strains, they differ in: temperature ranges, optimal temperature, pH range, optimal pH, and NaCl concentration requirements (1pr3^T and 2pr4 show slowed growth above a NaCl concentration of 15 g/L, and 3pr10 shows no growth below 15 g/L).^[1]^[2]

Strain	Temperate Range (°C)^[2]	Temperature Optimum (°C)^[2]	pH Range^[2]	pH Optimum^[2]	NaCl Concentration Requirement (g/L)^[2]
1pr3^T	10 - 43	39	6.0 - 8.6	7.2	<15
2pr4	10 - 36	30	6.6 - 8.1	7.2	<15
3pr10	15 - 36	29	6.6 - 8.1	7.4	>15

Application

Desulfobulbus propionicus can serve as a biocatalyst in microbial electrosynthesis.^[4] Microbial electrosynthesis is the usage of electrons by microorganism to reduce carbon dioxide to organic molecules.^[4] Desulfobulbus propionicus, when present at the anode, oxidizes elemental sulfur to sulfate, which creates free electrons in the process.^[4] The free electrons flow to the organism located at the cathode.^[4] The microbe present at the cathode utilizes the electron energy transferred from Desulfobulbus propionicus to create organic matter (e.g. acetate) by reducing carbon dioxide.^[4] The use of microbial electrosynthesis has potential to aid in the production and waste maintenance of industrial chemicals and energy production.^[4]

References

^ ^a ^b ^c ^d ^e ^f ^g ^h ⁱ ^j ^k ^l ^m ⁿ ^o ^p ^q ^r Pagani, Ioanna; Lapidus, Alla; Nolan, Matt; Lucas, Susan; Hammon, Nancy; Deshpande, Shweta; Cheng, Jan-Fang; Chertkov, Olga; Davenport, Karen; Tapia, Roxane; Han, Cliff; Goodwin, Lynne; Pitluck, Sam; Liolios, Konstantinos; Mavromatis, Konstantinos; Ivanova, Natalia; Mikhailova, Natalia; Pati, Amrita; Chen, Amy; Palaniappan, Krishna; Land, Miriam; Hauser, Loren; Chang, Yun-Juan; Jeffries, Cynthia D.; Detter, John C.; Brambilla, Evelyne; Kannan, K. Palani; Ngatchou Djao, Olivier D.; Rohde, Manfred; Pukall, Rüdiger; Spring, Stefan; Göker, Markus; Sikorski, Johannes; Woyke, Tanja; Bristow, James; Eisen, Jonathan A.; Markowitz, Victor; Hugenholtz, Philip; Kyrpides, Nikos C.; Klenk, Hans-Peter (2011). "Complete genome sequence of Desulfobulbus propionicus type strain (1pr3T)". Standards in Genomic Sciences. 4 (1): 100–110. doi:10.4056/sigs.1613929. PMC 3072085. PMID 21475592.
^ ^a ^b ^c ^d ^e ^f ^g ^h ⁱ ^j ^k ^l ^m ⁿ ^o ^p ^q ^r ^s ^t ^u ^v ^w ^x ^y Widdel, F.; Pfenning, N. (1982). "Studies on Dissimilatory Sulfate-Reducing Bacteria that Decompose Fatty Acids II. Incomplete Oxidation of Propionate byDesulfobulbuspropionicusgen. nov., sp. nov". Arch Microbiol. 131 (4): 360–365. doi:10.1007/BF00411187. S2CID 52801829.
^ ^a ^b Lovely, Derek R.; Phillips, Elizabeth J. P. (1994). "Novel processes for anae- robic sulfate production from elemental sulfur by sulfate-reducing bacteria". Applied and Environmental Microbiology. 60 (7): 2394–2399. Bibcode:1994ApEnM..60.2394L. doi:10.1128/AEM.60.7.2394-2399.1994. PMC 201662. PMID 16349323.
^ ^a ^b ^c ^d ^e ^f ^g Gong, Yanming; Ebrahim, Ali; Feist, Adam M.; Embree, Mallory; Zhang, Tian; Lovely, Derek; Zengler, Karsten (2013). "Sulfide-Driven Microbial Electrosynthesis". Environmental Science & Technology. 47 (1): 568–573. Bibcode:2013EnST...47..568G. doi:10.1021/es303837j. PMID 23252645.

External links

Holmes, D. E.; Bond, D. R.; Lovley, D. R. (2004). "Electron Transfer by Desulfobulbus propionicus to Fe(III) and Graphite Electrodes". Applied and Environmental Microbiology. 70 (2): 1234–1237. Bibcode:2004ApEnM..70.1234H. doi:10.1128/AEM.70.2.1234-1237.2004. ISSN 0099-2240. PMC 348862. PMID 14766612.
Laanbroek, Hendrikus J.; Abee, Tjakko; Voogd, Irma L. (1982). "Alcohol conversion by Desulfobulbus propionicus Lindhorst in the presence and absence of sulfate and hydrogen". Archives of Microbiology. 133 (3): 178–184. doi:10.1007/BF00414998. ISSN 0302-8933. S2CID 13646178.
Anandkumar, B.; George, R. P.; Maruthamuthu, S.; Palaniswamy, N.; Dayal, R. K. (2012). "Corrosion behavior of SRB Desulfobulbus propionicus isolated from an Indian petroleum refinery on mild steel". Materials and Corrosion. 63 (4): 355–362. doi:10.1002/maco.201005883. ISSN 0947-5117. S2CID 96758067.
Kremer, D.R.; Hansen, T.A. (1988). "Pathway of propionate degradation inDesulfobulbus propionicus". FEMS Microbiology Letters. 49 (2): 273–277. doi:10.1111/j.1574-6968.1988.tb02729.x. ISSN 0378-1097.
Benoit, J. M.; Gilmour, C. G.; Mason, R. P. (February 2001). "The Influence of Sulfide on Solid-Phase Mercury Bioavailability for Methylation by Pure Cultures of Desulfobulbus propionicus (1pr3)". Environmental Science and Technology. 35 (1): 127–135. Bibcode:2001EnST...35..127B. doi:10.1021/es001415n. PMID 11351996.
Moreau, J. W.; Gionfriddo, C. M.; Krabbenhoft, D. P.; Ogorek, J. M.; DeWild, J. F.; Aiken, G. R.; Roden, E. E. (2015). "The Effect of Natural Organic Matter on Mercury Methylation by Desulfobulbus propionicus 1pr3". Frontiers in Microbiology. 6: 1389. doi:10.3389/fmicb.2015.01389. PMC 4683176. PMID 26733947.
Mehrotra, A. S.; Horne, A. J.; Sedlak, D. L. (2003). "Reductionof Net Mercury MethylationbyIronin Desulfobulbus propionicus (1pr3) Cultures: Implications for EngineeredWetlands". Environmental Science and Technology. 37 (13): 3018–3023. Bibcode:2003EnST...37.3018M. doi:10.1021/es0262838. PMID 12875409.

[:0-1] ^ ^a ^b ^c ^d ^e ^f ^g ^h ⁱ ^j ^k ^l ^m ⁿ ^o ^p ^q ^r Pagani, Ioanna; Lapidus, Alla; Nolan, Matt; Lucas, Susan; Hammon, Nancy; Deshpande, Shweta; Cheng, Jan-Fang; Chertkov, Olga; Davenport, Karen; Tapia, Roxane; Han, Cliff; Goodwin, Lynne; Pitluck, Sam; Liolios, Konstantinos; Mavromatis, Konstantinos; Ivanova, Natalia; Mikhailova, Natalia; Pati, Amrita; Chen, Amy; Palaniappan, Krishna; Land, Miriam; Hauser, Loren; Chang, Yun-Juan; Jeffries, Cynthia D.; Detter, John C.; Brambilla, Evelyne; Kannan, K. Palani; Ngatchou Djao, Olivier D.; Rohde, Manfred; Pukall, Rüdiger; Spring, Stefan; Göker, Markus; Sikorski, Johannes; Woyke, Tanja; Bristow, James; Eisen, Jonathan A.; Markowitz, Victor; Hugenholtz, Philip; Kyrpides, Nikos C.; Klenk, Hans-Peter (2011). "Complete genome sequence of Desulfobulbus propionicus type strain (1pr3T)". Standards in Genomic Sciences. 4 (1): 100–110. doi:10.4056/sigs.1613929. PMC 3072085. PMID 21475592.

[:1-2] ^ ^a ^b ^c ^d ^e ^f ^g ^h ⁱ ^j ^k ^l ^m ⁿ ^o ^p ^q ^r ^s ^t ^u ^v ^w ^x ^y Widdel, F.; Pfenning, N. (1982). "Studies on Dissimilatory Sulfate-Reducing Bacteria that Decompose Fatty Acids II. Incomplete Oxidation of Propionate byDesulfobulbuspropionicusgen. nov., sp. nov". Arch Microbiol. 131 (4): 360–365. doi:10.1007/BF00411187. S2CID 52801829.

[:3-3] Lovely, Derek R.; Phillips, Elizabeth J. P. (1994). "Novel processes for anae- robic sulfate production from elemental sulfur by sulfate-reducing bacteria". Applied and Environmental Microbiology. 60 (7): 2394–2399. Bibcode:1994ApEnM..60.2394L. doi:10.1128/AEM.60.7.2394-2399.1994. PMC 201662. PMID 16349323.

[:2-4] ^ ^a ^b ^c ^d ^e ^f ^g Gong, Yanming; Ebrahim, Ali; Feist, Adam M.; Embree, Mallory; Zhang, Tian; Lovely, Derek; Zengler, Karsten (2013). "Sulfide-Driven Microbial Electrosynthesis". Environmental Science & Technology. 47 (1): 568–573. Bibcode:2013EnST...47..568G. doi:10.1021/es303837j. PMID 23252645.

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