Nanobacterium

Nanobacterium (/ˌnænbækˈtɪəriəm/ NAN-oh-bak-TEER-ee-əm, pl. nanobacteria /ˌnænbækˈtɪəriə/ NAN-oh-bak-TEER-ee-ə) is the unit or member name of a former proposed class of living organisms, specifically cell-walled microorganisms, now discredited, with a size much smaller than the generally accepted lower limit for life (about 200 nm for bacteria, like mycoplasma). Originally based on observed nano-scale structures in geological formations (including one meteorite), the status of nanobacteria was controversial, with some researchers suggesting they are a new class of living organism[2][3] capable of incorporating radiolabeled uridine,[4] and others attributing to them a simpler, abiotic nature.[5][6] One skeptic dubbed them "the cold fusion of microbiology", in reference to a notorious episode of supposed erroneous science.[7] The term "calcifying nanoparticles" (CNPs) has also been used as a conservative name regarding their possible status as a life form.

"Nanobacterium"
Scientific classification
Domain:
Phylum:
Class:
Order:
[not assigned]
Family:
[not assigned]
Genus:
"Nanobacterium"

Ciftcioglu et al. 1997[1]
Species
Structures found on meteorite fragment Allan Hills 84001

Research tends to agree that these structures exist, and appear to replicate in some way.[8] However, the idea that they are living entities has now largely been discarded, and the particles are instead thought to be nonliving crystallizations of minerals and organic molecules.[9]

1981–2000

In 1981 Francisco Torella and Richard Y. Morita described very small cells called ultramicrobacteria.[10] Defined as being smaller than 300 nm, by 1982 MacDonell and Hood found that some could pass through a 200 nm membrane. Early in 1989, geologist Robert L. Folk found what he later identified as nannobacteria (written with double "n"), that is, nanoparticles isolated from geological specimens[11] in travertine from hot springs of Viterbo, Italy. Initially searching for a bacterial cause for travertine deposition, scanning electron microscope examination of the mineral where no bacteria were detectable revealed extremely small objects which appeared to be biological. His first oral presentation elicited what he called "mostly a stony silence", at the 1992 Geological Society of America's annual convention.[12] He proposed that nanobacteria are the principal agents of precipitation of all minerals and crystals on Earth formed in liquid water, that they also cause all oxidation of metals, and that they are abundant in many biological specimens.[12]

In 1996, NASA scientist David McKay published a study suggesting the existence of nanofossils — fossils of Martian nanobacteria — in ALH84001, a meteorite originating from Mars and found in Antarctica.[13]

Nanobacterium sanguineum was proposed in 1998 as an explanation of certain kinds of pathologic calcification (apatite in kidney stones) by Finnish researcher Olavi Kajander and Turkish researcher Neva Çiftçioğlu, working at the University of Kuopio in Finland. According to the researchers, the particles self-replicated in microbiological culture, and the researchers further reported having identified DNA in these structures by staining.[14]

A paper published in 2000 by a team led by NIH scientist John Cisar further tested these ideas. It stated that what had previously been described as "self-replication" was a form of crystalline growth. The only DNA detected in his specimens was identified as coming from the bacteria Phyllobacterium myrsinacearum, which is a common contaminant in PCR reactions.[5]

2001–present

In 2004, a Mayo Clinic team led by Franklin Cockerill, John Lieske, and Virginia M. Miller reported to have isolated nanobacteria from diseased human arteries and kidney stones. Their results were published in 2004 and 2006 respectively.[4][15] Similar findings were obtained in 2005 by László Puskás at the University of Szeged, Hungary. Dr. Puskás identified these particles in cultures obtained from human atherosclerotic aortic walls and blood samples of atherosclerotic patients but the group was unable to detect DNA in these samples.[16]

In 2005, Ciftcioglu and her research team at NASA used a rotating cell culture flask, which simulates some aspects of low-gravity conditions, to culture nanobacteria suspected of rapidly forming kidney stones in astronauts. In this environment, they were found to multiply five times faster than in normal Earth gravity. The study concluded that nanobacteria potentially have a role in forming kidney stones and may need to be screened for in crews pre-flight.[17]

An article published to the Public Library of Science Pathogens (PLOS Pathogens) in February 2008 focused on the comprehensive characterization of nanobacteria. The authors claim that their results rule out the existence of nanobacteria as living entities and that they are instead a unique self-propagating entity, namely self-propagating mineral-fetuin complexes.[18]

An article published to the Proceedings of the National Academy of Sciences (PNAS) in April 2008 also reported that blood nanobacteria are not living organisms, and stated that "CaCO3 precipitates prepared in vitro are remarkably similar to purported nanobacteria in terms of their uniformly sized, membrane-delineated vesicular shapes, with cellular division-like formations and aggregations in the form of colonies."[6] The growth of such "biomorphic" inorganic precipitates was studied in detail in a 2009 Science paper, which showed that unusual crystal growth mechanisms can produce witherite precipitates from barium chloride and silica solutions that closely resemble primitive organisms.[19] The authors commented on the close resemblance of these crystals to putative nanobacteria, stating that their results showed that evidence for life cannot rest on morphology alone.

Further work on the importance of nanobacteria in geology by R. L. Folk and co-workers includes study of calcium carbonate Bahama ooids,[20] silicate clay minerals,[21] metal sulfides,[22] and iron oxides.[23] In all of these chemically diverse minerals, the putative nanobacteria are approximately the same size, mainly 0.05–0.2 μm. This suggests a commonality of origin. At least for the type locality at Viterbo, Italy, the biogenicity of these minute cells has been supported by transmission electron microscopy (TEM).[24] Slices through a green bioslime showed entities 0.09–0.4 μm in diameter with definite cell walls and interior dots resembling ribosomes, and even smaller objects with cell walls and lucent interiors with diameters of 0.05 μm.[25] Culturable organisms on earth are the same 0.05 μm size as the supposed nanobacteria on Mars.[26]

See also

References

  1. Ciftcioglu N, Kuronen I, Åkerman K, Hiltunen E, Laukkanen J, Kajander EO (1997). "A new potential threat in antigen and antibody products: Nanobacteria". In Brown F, Burton D, Doherty P, Mekalanos J, Norrby E (eds.). Vaccines 97. Molecular approaches to the control of infectious diseases. New York: Cold Spring Harbor Laboratory Press. pp. 99–103. ISBN 0-87969-516-1.
  2. Kajander E (2006). "Nanobacteria—propagating calcifying nanoparticles". Lett Appl Microbiol. 42 (6): 549–52. doi:10.1111/j.1472-765X.2006.01945.x. PMID 16706890. S2CID 20169194.
  3. Ciftcioglu N, McKay D, Mathew G, Kajander E (2006). "Nanobacteria: fact or fiction? Characteristics, detection, and medical importance of novel self-replicating, calcifying nanoparticles". J Investig Med. 54 (7): 385–94. doi:10.2310/6650.2006.06018. hdl:2060/20060028181. PMID 17169260. S2CID 35400477.
  4. Miller V, Rodgers G, Charlesworth J, Kirkland B, Severson S, Rasmussen T, Yagubyan M, Rodgers J, Cockerill F, Folk R, Rzewuska-Lech E, Kumar V, Farell-Baril G, Lieske J (2004). "Evidence of nanobacterial-like structures in calcified human arteries and cardiac valves". Am J Physiol Heart Circ Physiol. 287 (3): H1115–24. doi:10.1152/ajpheart.00075.2004. PMID 15142839.
  5. Cisar J, Xu D, Thompson J, Swaim W, Hu L, Kopecko D (2000). "An alternative interpretation of nanobacteria-induced biomineralization". Proc Natl Acad Sci USA. 97 (21): 11511–5. Bibcode:2000PNAS...9711511C. doi:10.1073/pnas.97.21.11511. PMC 17231. PMID 11027350.
  6. Martel J, Young JD (April 2008). "Purported nanobacteria in human blood as calcium carbonate nanoparticles". Proc. Natl. Acad. Sci. U.S.A. 105 (14): 5549–54. Bibcode:2008PNAS..105.5549M. doi:10.1073/pnas.0711744105. PMC 2291092. PMID 18385376.
  7. Jack Maniloff, quoted in "The Rise and Fall of Nanobacteria", Young and Martel, Scientific American, January 2010
  8. Raoult, D; Drancourt, M; Azza, S; Nappez, C; Guieu, R; Rolain, JM; Fourquet, P; Campagna, B; et al. (2008). "Nanobacteria Are Mineralo Fetuin Complexes". PLOS Pathogens. 4 (2): e41. doi:10.1371/journal.ppat.0040041. PMC 2242841. PMID 18282102.
  9. "The Rise and Fall of Nanobacteria", Young and Martel, Scientific American, January 2010
  10. Torella, Francisco; Morita, Richard Y. (1 February 1981). "Microcultural Study of Bacterial Size Changes and Microcolony and Ultramicrocolony Formation by Heterotrophic Bacteria in Seawater". Appl. Environ. Microbiol. 41 (2): 518–527. doi:10.1128/aem.41.2.518-527.1981. PMC 243725. PMID 16345721.
  11. A convention has been adopted between researchers to name -or spell- the nanoparticles isolated from geological specimens as nannobacteria, and those from biological specimens as nanobacteria.
  12. Folk, Robert L. (March 4, 1997). "Nanobacteria: surely not figments, but what under heaven are they?". naturalSCIENCE. Archived from the original on December 9, 2008. Retrieved 2008-12-20.
  13. McKay, David S.; et al. (1996). "Search for Past Life on Mars: Possible Relic Biogenic Activity in Martian Meteorite ALH84001". Science. 273 (5277): 924–930. Bibcode:1996Sci...273..924M. doi:10.1126/science.273.5277.924. PMID 8688069. S2CID 40690489.
  14. Kajander E, Ciftçioglu N (1998). "Nanobacteria: An alternative mechanism for pathogenic intra- and extracellular calcification and stone formation". Proc Natl Acad Sci USA. 95 (14): 8274–9. Bibcode:1998PNAS...95.8274K. doi:10.1073/pnas.95.14.8274. PMC 20966. PMID 9653177.
  15. Kumar V, Farell G, Yu S, et al. (November 2006). "Cell biology of pathologic renal calcification: contribution of crystal transcytosis, cell-mediated calcification, and nanoparticles". J. Investig. Med. 54 (7): 412–24. doi:10.2310/6650.2006.06021. PMID 17169263. S2CID 26068331.
  16. Puskás L, Tiszlavicz L, Rázga Z, Torday L, Krenács T, Papp J (2005). "Detection of nanobacteria-like particles in human atherosclerotic plaques". Acta Biol Hung. 56 (3–4): 233–45. doi:10.1556/ABiol.56.2005.3-4.7. PMID 16196199.
  17. Ciftçioglu N, Haddad R, Golden D, Morrison D, McKay D (2005). "A potential cause for kidney stone formation during space flights: enhanced growth of nanobacteria in microgravity". Kidney Int. 67 (2): 483–91. doi:10.1111/j.1523-1755.2005.67105.x. PMID 15673296.
  18. Raoult D, Drancourt M, Azza S, et al. (February 2008). "Nanobacteria Are Mineralo Fetuin Complexes". PLOS Pathog. 4 (2): e41. doi:10.1371/journal.ppat.0040041. PMC 2242841. PMID 18282102.
  19. García-Ruiz JM, Melero-García E, Hyde ST (January 2009). "Morphogenesis of self-assembled nanocrystalline materials of barium carbonate and silica" (PDF). Science. 323 (5912): 362–5. Bibcode:2009Sci...323..362G. doi:10.1126/science.1165349. PMID 19150841. S2CID 11977001. Archived from the original (PDF) on 2012-03-01. Retrieved 2009-12-03.
  20. Folk, RL and Lynch. FL (2001) Organic matter, putative nanobacteria and the formation of oolites and hard grounds, Sedimentology, 48:215-229.
  21. Folk, RL and Lynch, FL, (1997) The possible role of nanobacteria (dwarf bacteria) in clay-mineral diagenesis, Journal of Sedimentary Research, 67:583-589.
  22. Folk, RL (2005) nanobacteria and the formation of framboidal pyrite, Journal Earth System Science, 114:369-374
  23. Folk, RL and Carlin J (2006) Adventures in an iron birdbath: nanostructure of iron oxide and the nanobacteria connection, Geological Society of America, Abstracts with programs, v. 38 (3), p. 6.
  24. Kirkland, B and Lynch, FL (2005) nanobacteria, Big Foot and the Loch Ness Monster—what are you supposed to believe?, Geological Society of America, abs. with progr., v. 37:253.
  25. Folk, RL and Kirkland, B, (2007) On the smallness of life: new TEM evidence from biofilm in hot springs, Viterbo, Italy, Geological Society of America, abs. with proper., v. 39 (6) 421.
  26. Folk, RL and Taylor, L (2002) nanobacterial alteration of pyroxenes in Martian meteorite ALH84001, Meteorology and Planetary Science, v. 37:1057-1070.
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