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Diazotroph

December 08, 2023

Diazotrophs are bacteria and archaea that fix gaseous nitrogen in the atmosphere into a more usable form such as ammonia.

A diazotroph is a microorganism that is able to grow without external sources of fixed nitrogen. Examples of organisms that do this are rhizobia and Frankia (in symbiosis) and Azospirillum. All diazotrophs contain iron-molybdenum or iron-vanadium nitrogenase systems. Two of the most studied systems are those of Klebsiella pneumoniae and Azotobacter vinelandii. These systems are studied because of their genetic tractability and their fast growth.[1]

Etymology edit

The word diazotroph is derived from the words diazo ("di" = two + "azo" = nitrogen) meaning "dinitrogen (N2)" and troph meaning "pertaining to food or nourishment", in summary dinitrogen utilizing. The word azote means nitrogen in French and was named by French chemist and biologist Antoine Lavoisier, who saw it as the part of air which cannot sustain life.[2]

Types edit

Diazotrophs are scattered across Bacteria taxonomic groups (as well as a couple of Archaea). Even within a species that can fix nitrogen there may be strains that do not.[3] Fixation is shut off when other sources of nitrogen are available, and, for many species, when oxygen is at high partial pressure. Bacteria have different ways of dealing with the debilitating effects of oxygen on nitrogenases, listed below.

Free-living diazotrophs edit

  • Anaerobes—these are obligate anaerobes that cannot tolerate oxygen even if they are not fixing nitrogen. They live in habitats low in oxygen, such as soils and decaying vegetable matter. Clostridium is an example. Sulphate-reducing bacteria are important in ocean sediments (e.g. Desulfovibrio), and some Archean methanogens, like Methanococcus, fix nitrogen in muds, animal intestines[3] and anoxic soils.[4]
  • Facultative anaerobes—these species can grow either with or without oxygen, but they only fix nitrogen anaerobically. Often, they respire oxygen as rapidly as it is supplied, keeping the amount of free oxygen low. Examples include Klebsiella pneumoniae, Paenibacillus polymyxa, Bacillus macerans, and Escherichia intermedia.[3]
  • Aerobes—these species require oxygen to grow, yet their nitrogenase is still debilitated if exposed to oxygen. Azotobacter vinelandii is the most studied of these organisms. It uses very high respiration rates, and protective compounds, to prevent oxygen damage. Many other species also reduce the oxygen levels in this way, but with lower respiration rates and lower oxygen tolerance.[3]
  • Oxygenic photosynthetic bacteria (cyanobacteria) generate oxygen as a by-product of photosynthesis, yet some are able to fix nitrogen as well. These are colonial bacteria that have specialized cells (heterocysts) that lack the oxygen generating steps of photosynthesis. Examples are Anabaena cylindrica and Nostoc commune. Other cyanobacteria lack heterocysts and can fix nitrogen only in low light and oxygen levels (e.g. Plectonema).[3] Some cyanobacteria, including the highly abundant marine taxa Prochlorococcus and Synechococcus do not fix nitrogen,[5] whilst other marine cyanobacteria, such as Trichodesmium and Cyanothece, are major contributors to oceanic nitrogen fixation.[6]
  • Anoxygenic photosynthetic bacteria do not generate oxygen during photosynthesis, having only a single photosystem which cannot split water. Nitrogenase is expressed under nitrogen limitation. Normally, the expression is regulated via negative feedback from the produced ammonium ion but in the absence of N2, the product is not formed, and the by-product H2 continues unabated [Biohydrogen]. Example species: Rhodobacter sphaeroides, Rhodopseudomonas palustris, Rhodobacter capsulatus.[7]

Symbiotic diazotrophs edit

  • Rhizobia—these are the species that associate with legumes, plants of the family Fabaceae. Oxygen is bound to leghemoglobin in the root nodules that house the bacterial symbionts, and supplied at a rate that will not harm the nitrogenase.[3]
  • Frankias—much less is known about/to these 'actinorhizal' nitrogen fixers. The bacteria also infect the roots leading to the formation of nodules. Actinorhizal nodules consist of several lobes, each lobe has a similar structure as a lateral root. Frankia is able to colonize in the cortical tissue of nodules where it fixes nitrogen.[8] Actinorhizal plants and Frankias also produce haemoglobins,[9] but their role is less well established than for rhizobia.[8] Although at first it appeared that they inhabit sets of unrelated plants (alders, Australian pines, California lilac, bog myrtle, bitterbrush, Dryas), revisions to the phylogeny of angiosperms show a close relatedness of these species and the legumes.[10][8] These footnotes suggest the ontogeny of these replicates rather than the phylogeny. In other words, an ancient gene (from before the angiosperms and gymnosperms diverged) that is unused in most species was reawakened and reused in these species.
  • Cyanobacteria—there are also symbiotic cyanobacteria. Some associate with fungi as lichens, with liverworts, with a fern, and with a cycad.[3] These do not form nodules (indeed most of the plants do not have roots). Heterocysts exclude the oxygen, as discussed above. The fern association is important agriculturally: the water fern Azolla harbouring Anabaena is an important green manure for rice culture.[3]
  • Association with animals—although diazotrophs have been found in many animal guts, there is usually sufficient ammonia present to suppress nitrogen fixation.[3] Termites on a low nitrogen diet allow for some fixation, but the contribution to the termite's nitrogen supply is negligible. Shipworms may be the only species that derive significant benefit from their gut symbionts.[3]

Cultivation edit

Under the laboratory conditions, extra nitrogen sources are not needed in free living diazotrophs, and carbon sources (such as sucrose, glucose) and a small amount of inorganic salt are needed to the medium. Free living diazotrophs can directly use nitrogen (N2) in the air as nitrogen nutrition. However, while cultivating several symbiotic diazotrophs such as rhizobia, it is necessary to add nitrogen nutrition, because rhizobia and other symbiotic nitrogen-fixing bacteria can not use molecular nitrogen (N2) in free living form.[11]

Application edit

Biofertilizer edit

Diazotroph fertilizer is a kind of biofertilizer that can use nitrogen-fixing microorganisms to convert molecular nitrogen (N2) into ammonia (which is the formation of nitrogen available for the crops to use). These nitrogen nutrients then can be used in the process of protein synthesis for the plants. This whole process of nitrogen fixation by diazotroph is called biological nitrogen fixation. This biochemical reaction can be carried out under normal temperature and pressure conditions. So it does not require extreme conditions and specific catalysts in fertilizer production. Therefore, produce available nitrogen in this way can be cheap, clean and efficient. Nitrogen-fixing bacteria fertilizer is an ideal and promising biofertilizer.[12]

From the ancient time, people grow the leguminous crops to make the soil more fertile. And the reason for this is: the root of leguminous crops are symbiotic with the rhizobia (a kind of diazotroph). These rhizobia can be considered as a natural biofertilizer to provide available nitrogen in the soil. After harvesting the leguminous crops, and then grow other crops (may not be leguminous), they can also use these nitrogen remain in the soil and grow better.

 
Leguminous plants used to fertilize an abandoned land

Diazotroph biofertilizers used today include Rhizobium, Azotobacter, Azospirilium and Blue green algae (a genus of cyanobacteria). These fertilizer are widely used and commenced into industrial production. So far in the market, nitrogen fixation biofertilizer can be divided into liquid fertilizer and solid fertilizer. Most of the fertilizers are fermented in the way of liquid fermentation. After fermentation, the liquid bacteria can be packaged, which is the liquid fertilizer, and the fermented liquid can also be adsorbed with sterilized peat and other carrier adsorbents to form a solid microbial fertilizer. These nitrogen-fixation fertilizer has a certain effect on increasing the production of cotton, rice, wheat, peanuts, rape, corn, sorghum, potatoes, tobacco, sugarcane and various vegetables.

Importance edit

In terms of generating nitrogen available to all organisms, the symbiotic associations greatly exceed the free-living species with the exception of cyanobacteria.[3]

Diazotroph plays an important roles in nitrogen cycle of the earth. In the terrestrial ecosystem, the diazotroph fix the (N2) from the atmosphere and provide the available nitrogen for the primary producer. Then the nitrogen is transferred to higher trophical levels and human beings. The formation and storage of nitrogen will all influenced by the transformation process. Also the available nitrogen fixed by the diazotroph is environmentally sustainable, which can reduce the use of fertilizer, which can be an important topic in agricultural research.

In marine ecosystem, prokaryotic phytoplankton (such as cyanobacteria) is the main nitrogen fixer, then the nitrogen consumed by higher trophical levels. The fixed N released from these organisms is a component of ecosystem N inputs. And also the fixed N is important for the coupled C cycle. A greater oceanic inventory of fixed N may increase the primary production and export of organic C to the deep ocean.[13][14]

References edit

  1. ^ Dixon R, Kahn D (August 2004). "Genetic regulation of biological nitrogen fixation". Nature Reviews. Microbiology. 2 (8): 621–31. doi:10.1038/nrmicro954. PMID 15263897. S2CID 29899253.
  2. ^ "Diazotroph - Biology-Online Dictionary | Biology-Online Dictionary". from the original on 2017-03-15. Retrieved 2017-04-05.
  3. ^ a b c d e f g h i j k Postgate, J (1998). Nitrogen Fixation, 3rd Edition. Cambridge University Press, Cambridge UK.
  4. ^ Bae HS, Morrison E, Chanton JP, Ogram A (April 2018). "Methanogens Are Major Contributors to Nitrogen Fixation in Soils of the Florida Everglades". Applied and Environmental Microbiology. 84 (7): e02222–17. Bibcode:2018ApEnM..84E2222B. doi:10.1128/AEM.02222-17. PMC 5861825. PMID 29374038.
  5. ^ Zehr JP (April 2011). "Nitrogen fixation by marine cyanobacteria". Trends in Microbiology. 19 (4): 162–73. doi:10.1016/j.tim.2010.12.004. PMID 21227699.
  6. ^ Bergman B, Sandh G, Lin S, Larsson J, Carpenter EJ (May 2013). "Trichodesmium--a widespread marine cyanobacterium with unusual nitrogen fixation properties". FEMS Microbiology Reviews. 37 (3): 286–302. doi:10.1111/j.1574-6976.2012.00352.x. PMC 3655545. PMID 22928644.
  7. ^ Blankenship RE, Madigan MT & Bauer CE (1995). Anoxygenic photosynthetic bacteria. Dordrecht, The Netherlands, Kluwer Academic.
  8. ^ a b c Vessey JK, Pawlowski, K and Bergman B (2005). "Root-based N2-fixing symbioses: Legumes, actinorhizal plants, Parasponia sp and cycads". Plant and Soil. 274 (1–2): 51–78. doi:10.1007/s11104-005-5881-5. S2CID 5035264.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  9. ^ Beckwith J, Tjepkema JD, Cashon RE, Schwintzer CR, Tisa LS (December 2002). "Hemoglobin in five genetically diverse Frankia strains". Canadian Journal of Microbiology. 48 (12): 1048–55. doi:10.1139/w02-106. PMID 12619816.
  10. ^ Soltis DE, Soltis PS, Morgan DR, Swensen SM, Mullin BC, Dowd JM, Martin PG (March 1995). "Chloroplast gene sequence data suggest a single origin of the predisposition for symbiotic nitrogen fixation in angiosperms". Proceedings of the National Academy of Sciences of the United States of America. 92 (7): 2647–51. Bibcode:1995PNAS...92.2647S. doi:10.1073/pnas.92.7.2647. PMC 42275. PMID 7708699.
  11. ^ Somasegaran, Padma; Hoden, Heinz.J (1994). Handbook for Rhizobia (1 ed.). New York, NY: Springer. p. 1. doi:10.1007/978-1-4613-8375-8. ISBN 978-1-4613-8375-8. S2CID 21924709.
  12. ^ Vessey, J.K. (2003). "Plant growth promoting rhizobacteria as biofertilizers". Plant and Soil. 255 (2): 571–586. doi:10.1023/A:1026037216893. S2CID 37031212.
  13. ^ Inomura, Keisuke; Deutsch, Curtis; Masuda, Takako; Prášil, Ondrej; Follows, Michael J. (2020). "Quantitative models of nitrogen-fixing organisms". Computational and Structural Biotechnology. 18: 3905–3924. doi:10.1016/j.csbj.2020.11.022. PMC 7733014. PMID 33335688.
  14. ^ Karl, David M.; Church, Matthew J.; Dore, John E.; Letelier, Richardo M.; Mahaffey, Claire (2012). "Predictable and efficient carbon sequestration in the North Pacific Ocean supported by symbiotic nitrogen fixation". PNAS. 109 (6): 1842–1849. doi:10.1073/pnas.1120312109. PMC 3277559. PMID 22308450.

External links edit

  • Marine Nitrogen Fixation - The Basics (USC Capone Lab)
  • Rhizobia

December 08, 2023
diazotroph, bacteria, archaea, that, gaseous, nitrogen, atmosphere, into, more, usable, form, such, ammonia, diazotroph, microorganism, that, able, grow, without, external, sources, fixed, nitrogen, examples, organisms, that, this, rhizobia, frankia, symbiosis. Diazotrophs are bacteria and archaea that fix gaseous nitrogen in the atmosphere into a more usable form such as ammonia A diazotroph is a microorganism that is able to grow without external sources of fixed nitrogen Examples of organisms that do this are rhizobia and Frankia in symbiosis and Azospirillum All diazotrophs contain iron molybdenum or iron vanadium nitrogenase systems Two of the most studied systems are those of Klebsiella pneumoniae and Azotobacter vinelandii These systems are studied because of their genetic tractability and their fast growth 1 Contents 1 Etymology 2 Types 2 1 Free living diazotrophs 2 2 Symbiotic diazotrophs 3 Cultivation 4 Application 4 1 Biofertilizer 5 Importance 6 References 7 External linksEtymology editThe word diazotroph is derived from the words diazo di two azo nitrogen meaning dinitrogen N2 and troph meaning pertaining to food or nourishment in summary dinitrogen utilizing The word azote means nitrogen in French and was named by French chemist and biologist Antoine Lavoisier who saw it as the part of air which cannot sustain life 2 Types editDiazotrophs are scattered across Bacteria taxonomic groups as well as a couple of Archaea Even within a species that can fix nitrogen there may be strains that do not 3 Fixation is shut off when other sources of nitrogen are available and for many species when oxygen is at high partial pressure Bacteria have different ways of dealing with the debilitating effects of oxygen on nitrogenases listed below Free living diazotrophs edit Anaerobes these are obligate anaerobes that cannot tolerate oxygen even if they are not fixing nitrogen They live in habitats low in oxygen such as soils and decaying vegetable matter Clostridium is an example Sulphate reducing bacteria are important in ocean sediments e g Desulfovibrio and some Archean methanogens like Methanococcus fix nitrogen in muds animal intestines 3 and anoxic soils 4 Facultative anaerobes these species can grow either with or without oxygen but they only fix nitrogen anaerobically Often they respire oxygen as rapidly as it is supplied keeping the amount of free oxygen low Examples include Klebsiella pneumoniae Paenibacillus polymyxa Bacillus macerans and Escherichia intermedia 3 Aerobes these species require oxygen to grow yet their nitrogenase is still debilitated if exposed to oxygen Azotobacter vinelandii is the most studied of these organisms It uses very high respiration rates and protective compounds to prevent oxygen damage Many other species also reduce the oxygen levels in this way but with lower respiration rates and lower oxygen tolerance 3 Oxygenic photosynthetic bacteria cyanobacteria generate oxygen as a by product of photosynthesis yet some are able to fix nitrogen as well These are colonial bacteria that have specialized cells heterocysts that lack the oxygen generating steps of photosynthesis Examples are Anabaena cylindrica and Nostoc commune Other cyanobacteria lack heterocysts and can fix nitrogen only in low light and oxygen levels e g Plectonema 3 Some cyanobacteria including the highly abundant marine taxa Prochlorococcus and Synechococcus do not fix nitrogen 5 whilst other marine cyanobacteria such as Trichodesmium and Cyanothece are major contributors to oceanic nitrogen fixation 6 Anoxygenic photosynthetic bacteria do not generate oxygen during photosynthesis having only a single photosystem which cannot split water Nitrogenase is expressed under nitrogen limitation Normally the expression is regulated via negative feedback from the produced ammonium ion but in the absence of N2 the product is not formed and the by product H2 continues unabated Biohydrogen Example species Rhodobacter sphaeroides Rhodopseudomonas palustris Rhodobacter capsulatus 7 Symbiotic diazotrophs edit Rhizobia these are the species that associate with legumes plants of the family Fabaceae Oxygen is bound to leghemoglobin in the root nodules that house the bacterial symbionts and supplied at a rate that will not harm the nitrogenase 3 Frankias much less is known about to these actinorhizal nitrogen fixers The bacteria also infect the roots leading to the formation of nodules Actinorhizal nodules consist of several lobes each lobe has a similar structure as a lateral root Frankia is able to colonize in the cortical tissue of nodules where it fixes nitrogen 8 Actinorhizal plants and Frankias also produce haemoglobins 9 but their role is less well established than for rhizobia 8 Although at first it appeared that they inhabit sets of unrelated plants alders Australian pines California lilac bog myrtle bitterbrush Dryas revisions to the phylogeny of angiosperms show a close relatedness of these species and the legumes 10 8 These footnotes suggest the ontogeny of these replicates rather than the phylogeny In other words an ancient gene from before the angiosperms and gymnosperms diverged that is unused in most species was reawakened and reused in these species Cyanobacteria there are also symbiotic cyanobacteria Some associate with fungi as lichens with liverworts with a fern and with a cycad 3 These do not form nodules indeed most of the plants do not have roots Heterocysts exclude the oxygen as discussed above The fern association is important agriculturally the water fern Azolla harbouring Anabaena is an important green manure for rice culture 3 Association with animals although diazotrophs have been found in many animal guts there is usually sufficient ammonia present to suppress nitrogen fixation 3 Termites on a low nitrogen diet allow for some fixation but the contribution to the termite s nitrogen supply is negligible Shipworms may be the only species that derive significant benefit from their gut symbionts 3 Cultivation editUnder the laboratory conditions extra nitrogen sources are not needed in free living diazotrophs and carbon sources such as sucrose glucose and a small amount of inorganic salt are needed to the medium Free living diazotrophs can directly use nitrogen N2 in the air as nitrogen nutrition However while cultivating several symbiotic diazotrophs such as rhizobia it is necessary to add nitrogen nutrition because rhizobia and other symbiotic nitrogen fixing bacteria can not use molecular nitrogen N2 in free living form 11 Application editBiofertilizer edit Diazotroph fertilizer is a kind of biofertilizer that can use nitrogen fixing microorganisms to convert molecular nitrogen N2 into ammonia which is the formation of nitrogen available for the crops to use These nitrogen nutrients then can be used in the process of protein synthesis for the plants This whole process of nitrogen fixation by diazotroph is called biological nitrogen fixation This biochemical reaction can be carried out under normal temperature and pressure conditions So it does not require extreme conditions and specific catalysts in fertilizer production Therefore produce available nitrogen in this way can be cheap clean and efficient Nitrogen fixing bacteria fertilizer is an ideal and promising biofertilizer 12 From the ancient time people grow the leguminous crops to make the soil more fertile And the reason for this is the root of leguminous crops are symbiotic with the rhizobia a kind of diazotroph These rhizobia can be considered as a natural biofertilizer to provide available nitrogen in the soil After harvesting the leguminous crops and then grow other crops may not be leguminous they can also use these nitrogen remain in the soil and grow better nbsp Leguminous plants used to fertilize an abandoned landDiazotroph biofertilizers used today include Rhizobium Azotobacter Azospirilium and Blue green algae a genus of cyanobacteria These fertilizer are widely used and commenced into industrial production So far in the market nitrogen fixation biofertilizer can be divided into liquid fertilizer and solid fertilizer Most of the fertilizers are fermented in the way of liquid fermentation After fermentation the liquid bacteria can be packaged which is the liquid fertilizer and the fermented liquid can also be adsorbed with sterilized peat and other carrier adsorbents to form a solid microbial fertilizer These nitrogen fixation fertilizer has a certain effect on increasing the production of cotton rice wheat peanuts rape corn sorghum potatoes tobacco sugarcane and various vegetables Importance editIn terms of generating nitrogen available to all organisms the symbiotic associations greatly exceed the free living species with the exception of cyanobacteria 3 Diazotroph plays an important roles in nitrogen cycle of the earth In the terrestrial ecosystem the diazotroph fix the N2 from the atmosphere and provide the available nitrogen for the primary producer Then the nitrogen is transferred to higher trophical levels and human beings The formation and storage of nitrogen will all influenced by the transformation process Also the available nitrogen fixed by the diazotroph is environmentally sustainable which can reduce the use of fertilizer which can be an important topic in agricultural research In marine ecosystem prokaryotic phytoplankton such as cyanobacteria is the main nitrogen fixer then the nitrogen consumed by higher trophical levels The fixed N released from these organisms is a component of ecosystem N inputs And also the fixed N is important for the coupled C cycle A greater oceanic inventory of fixed N may increase the primary production and export of organic C to the deep ocean 13 14 References edit Dixon R Kahn D August 2004 Genetic regulation of biological nitrogen fixation Nature Reviews Microbiology 2 8 621 31 doi 10 1038 nrmicro954 PMID 15263897 S2CID 29899253 Diazotroph Biology Online Dictionary Biology Online Dictionary Archived from the original on 2017 03 15 Retrieved 2017 04 05 a b c d e f g h i j k Postgate J 1998 Nitrogen Fixation 3rd Edition Cambridge University Press Cambridge UK Bae HS Morrison E Chanton JP Ogram A April 2018 Methanogens Are Major Contributors to Nitrogen Fixation in Soils of the Florida Everglades Applied and Environmental Microbiology 84 7 e02222 17 Bibcode 2018ApEnM 84E2222B doi 10 1128 AEM 02222 17 PMC 5861825 PMID 29374038 Zehr JP April 2011 Nitrogen fixation by marine cyanobacteria Trends in Microbiology 19 4 162 73 doi 10 1016 j tim 2010 12 004 PMID 21227699 Bergman B Sandh G Lin S Larsson J Carpenter EJ May 2013 Trichodesmium a widespread marine cyanobacterium with unusual nitrogen fixation properties FEMS Microbiology Reviews 37 3 286 302 doi 10 1111 j 1574 6976 2012 00352 x PMC 3655545 PMID 22928644 Blankenship RE Madigan MT amp Bauer CE 1995 Anoxygenic photosynthetic bacteria Dordrecht The Netherlands Kluwer Academic a b c Vessey JK Pawlowski K and Bergman B 2005 Root based N2 fixing symbioses Legumes actinorhizal plants Parasponia sp and cycads Plant and Soil 274 1 2 51 78 doi 10 1007 s11104 005 5881 5 S2CID 5035264 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Beckwith J Tjepkema JD Cashon RE Schwintzer CR Tisa LS December 2002 Hemoglobin in five genetically diverse Frankia strains Canadian Journal of Microbiology 48 12 1048 55 doi 10 1139 w02 106 PMID 12619816 Soltis DE Soltis PS Morgan DR Swensen SM Mullin BC Dowd JM Martin PG March 1995 Chloroplast gene sequence data suggest a single origin of the predisposition for symbiotic nitrogen fixation in angiosperms Proceedings of the National Academy of Sciences of the United States of America 92 7 2647 51 Bibcode 1995PNAS 92 2647S doi 10 1073 pnas 92 7 2647 PMC 42275 PMID 7708699 Somasegaran Padma Hoden Heinz J 1994 Handbook for Rhizobia 1 ed New York NY Springer p 1 doi 10 1007 978 1 4613 8375 8 ISBN 978 1 4613 8375 8 S2CID 21924709 Vessey J K 2003 Plant growth promoting rhizobacteria as biofertilizers Plant and Soil 255 2 571 586 doi 10 1023 A 1026037216893 S2CID 37031212 Inomura Keisuke Deutsch Curtis Masuda Takako Prasil Ondrej Follows Michael J 2020 Quantitative models of nitrogen fixing organisms Computational and Structural Biotechnology 18 3905 3924 doi 10 1016 j csbj 2020 11 022 PMC 7733014 PMID 33335688 Karl David M Church Matthew J Dore John E Letelier Richardo M Mahaffey Claire 2012 Predictable and efficient carbon sequestration in the North Pacific Ocean supported by symbiotic nitrogen fixation PNAS 109 6 1842 1849 doi 10 1073 pnas 1120312109 PMC 3277559 PMID 22308450 External links editMarine Nitrogen Fixation The Basics USC Capone Lab Azotobacter Rhizobia Frankia amp Actinorhizal Plants Retrieved from https en wikipedia org w index php title Diazotroph amp oldid 1176800262, wikipedia, wiki, book, books, library,

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