Rhizobium
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| Rhizobium | |
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| File:Rhizobium tropici strain BR816 on TY agar.JPG | |
| Rhizobium tropici on an agar plate. | |
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Rhizobium
Frank 1889
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| Type species | |
| Rhizobium leguminosarum |
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| Species[1] | |
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Rhizobium is a genus of Gram-negative soil bacteria that fix nitrogen. Rhizobium forms an endosymbiotic nitrogen fixing association with roots of legumes and Parasponia.
The bacteria colonize plant cells within root nodules where they convert atmospheric nitrogen into ammonia and then provide organic nitrogenous compounds such as glutamine or ureides to the plant. The plant in turn provides the bacteria with organic compounds made by photosynthesis.[2] This mutually beneficial relationship is true of all of the rhizobia, of which the Rhizobium genus is a typical example.
History
Beijerinck in the Netherlands was the first to isolate and cultivate a microorganism from the nodules of legumes in 1888. He named it Bacillus radicicola, which is now placed in Bergey's Manual of Determinative Bacteriology under the genus Rhizobium.
Research
Rhizobium forms a symbiotic relationship with certain plants such as legumes. The Rhizobium fixes nitrogen from the air into ammonia, which acts as a natural fertilizer for the plants. Current research is being conducted by Agricultural Research Service microbiologists to discover a way to utilize Rhizobium’s biological nitrogen fixation. This research involves the genetic mapping of various rhizobial species with its respective symbiotic plant species, like alfalfa or soybean. The goal of this research is to increase the plants’ productivity without using fertilizers. [1]
In molecular biology, Rhizobium has also been identified as a contaminant of DNA extraction kit reagents and ultra-pure water systems, which may lead to its erroneous appearance in microbiota or metagenomic datasets.[3] The presence of nitrogen fixing bacteria as contaminants may be due to the use of nitrogen gas in ultra-pure water production to inhibit microbial growth in storage tanks.[4]
Species
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- R. aggregatum (Hirsch and Müller 1986) Kaur et al. 2011[5]
- R. alamii Berge et al. 2009
- R. alkalisoli Lu et al. 2009
- R. alvei Sheu et al. 2015
- R. anhuiense Zhang et al. 2015
- R. azibense Mnasri et al. 2014
- R. bangladeshense Harun-or Rashid et al. 2015
- R. binae Harun-or Rashid et al. 2015
- R. borbori Zhang et al. 2011
- R. calliandrae Rincón-Rosales et al. 2013
- R. cauense Liu et al. 2012
- R. cellulosilyticum García-Fraile et al. 2007
- R. daejeonense Quan et al. 2005
- R. endolithicum Parag et al. 2014
- R. endophyticum López-López et al. 2010
- R. etli Segovia et al. 1993[6]
- R. e. sv. mimosae
- R. e. sv. phaseoli
- R. fabae Tian et al. 2008
- R. flavum Gu et al. 2014
- R. freirei Dall'Agnol et all. 2013
- R. galegae Lindström 1989
- R. gallicum Amarger et al. 1997
- R. giardinii Amarger et al. 1997
- R. grahamii López-López et al. 2011
- R. hainanense Chen et al. 1997
- R. halophytocola Bibi et al. 2012
- R. halotolerans Diange and Lee 2013[10]
- R. helanshanense Qin et al. 2012
- R. herbae Ren et al. 2011[11]
- R. huautlense Wang et al. 1998
- R. indigoferae Wei et al. 2002
- R. jaguaris Rincón-Rosales et al. 2013
- R. kunmingense Shen et al. 2010
- R. laguerreae Saïdi et al. 2014
- R. larrymoorei (Bouzar and Jones 2001) Young 2004[12]
- R. leguminosarum (Frank 1879) Frank 1889
- R. l. sv. trifolii
- R. l. sv. viciae
- R. lemnae Kittiwongwattana & Thawai 2014
- R. lentis Harun-or Rashid et al. 2015
- R. leucaenae Ribeiro et al. 2011
- R. loessense Wei et al. 2003
- R. lusitanum Valverde et al. 2006
- "Candidatus Rhizobium massiliae" Greub et al. 2004.
- R. mayense Rincón-Rosales et al. 2013
- R. mesoamericanum López-López et al. 2011
- R. mesosinicum Lin et al. 2009
- R. metallidurans Grison et al. 2015
- R. miluonense Gu et al. 2008
- R. mongolense Van Berkum et al. 1998[9]
- R. multihospitium Han et al. 2008
- R. naphthalenivorans Kaiya et al. 2012
- R. nepotum Pulawska et al. 2012
- R. oryzae Peng et al. 2008
- R. pakistanensis Khalid et al. 2014
- R. paknamense Kittiwongwattana & Thawai 2013
- R. paranaense Dall'Agnol et al. 2014
- R. petrolearium Zhang et al. 2012
- R. phaseoli Dangeard 1926 emend. Ramírez-Bahena et al. 2008
- R. phenanthrenilyticum Wen et al. 2011
- R. pisi Ramírez-Bahena et al. 2008
- R. pongamiae Kesari et al. 2013[14]
- R. populi Rozahon et al. 2014
- R. pseudoryzae Zhang et al. 2011
- R. pusense Panday et al. 2011
- R. qilianshanense Xu et al. 2013[15]
- R. radiobacter (Beijerinck and van Delden 1902) Young et al. 2001[12]
- R. rhizogenes (Riker et al. 1930) Young et al. 2001[12]
- R. rhizoryzae Zhang et al. 2014
- R. rosettiformans Kaur et al. 2011
- R. rubi (Hildebrand 1940) Young et al. 2001[12]
- R. selenitireducens corrig. Hunter et al. 2008
- R. skierniewicense Puławska et al. 2012
- R. smilacinae Zhang et al. 2014
- R. soli Yoon et al. 2010
- R. sophorae Jiao et al. 2014
- R. sophoriradicis Jiao et al. 2014
- R. sphaerophysae Xu et al. 2012
- R. straminoryzae Lin et al. 2014
- R. subbaraonis Ramana et al. 2013
- R. sullae Squartini et al. 2002
- R. taibaishanense Yao et al. 2012
- R. tarimense Turdahon et al. 2012[16]
- R. tibeticum Hou et al. 2009
- R. tropici Martínez-Romero et al. 1991
- R. tubonense Zhang et al. 2011
- R. undicola (de Lajudie et al. 1998) Young et al. 2001
- R. vallis Wang et all. 2011[17]
- R. vignae Ren et al. 2011
- R. vitis (Ophel and Kerr 1990) Young et al. 2001[12]
- R. yanglingense Tan et al. 2001[9]
- R. yantingense Chen et al. 2014
Phylogeny
The currently accepted taxonomy is based on the List of Prokaryotic names with Standing in Nomenclature (LPSN) [1] and National Center for Biotechnology Information (NCBI)[18] and the phylogeny is based on 16S rRNA-based LTP release 106 by The All-Species Living Tree Project [19]
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References
- ↑ 1.0 1.1 Lua error in package.lua at line 80: module 'strict' not found.
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- ↑ NOTE: This strain was formerly named Blastobacter aggregatus.
- ↑ NOTE: This species was formerly known as R. leguminosarum sv. phaseoli.
- ↑ 7.0 7.1 Lua error in package.lua at line 80: module 'strict' not found.
- ↑ 8.0 8.1 8.2 8.3 Lua error in package.lua at line 80: module 'strict' not found.
- ↑ 9.0 9.1 9.2 NOTE: R. gallicum and R. mongolense are 99.2% identical in their rDNA and may be the same species. It has been proposed by Silva et al. that R. mongolense and R. yanglingense be reclassified as R. gallicum sv. orientale.
- ↑ Lua error in package.lua at line 80: module 'strict' not found.
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- ↑ 12.0 12.1 12.2 12.3 12.4 12.5 12.6 NOTE: These strains were formerly placed in the genus Agrobacterium. Cite error: Invalid
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- ↑ Lua error in package.lua at line 80: module 'strict' not found.
- ↑ Lua error in package.lua at line 80: module 'strict' not found.
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- ↑ Lua error in package.lua at line 80: module 'strict' not found.
- ↑ All-Species Living Tree Project.Lua error in package.lua at line 80: module 'strict' not found.
- ↑ This is the type species for the genus.
- ↑ Arthrobacter viscosus is currently classified in the Micrococcaceae. See Arthrobacter.
