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Magnetotaxis

From Wikipedia, the free encyclopedia

Magnetotaxis is a process implemented by a diverse group of Gram-negative bacteria that involves orienting and coordinating movement in response to Earth's magnetic field.[1] This process is mainly carried out by microaerophilic and anaerobic bacteria found in aquatic environments such as salt marshes, seawater, and freshwater lakes.[2] By sensing the magnetic field, the bacteria are able to orient themselves towards environments with more favorable oxygen concentrations. This orientation towards more favorable oxygen concentrations allows the bacteria to reach these environments faster as opposed to random movement through Brownian motion.[3]

Overview

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Magnetic bacteria (e.g. Magnetospirillum magnetotacticum) contain internal structures known as magnetosomes which are responsible for the process of magnetotaxis. After orienting to the magnetic field using the magnetosomes, the bacteria use flagella to swim along the magnetic field, towards the more favorable environment.[4] Magnetotaxis has no impact on the average speed of the bacteria.[3] However, magnetotaxis allows bacteria to guide their otherwise random movement. This process is similar in practice to aerotaxis, but governed by magnetic fields instead of oxygen concentrations.[5] Magnetotaxis and aerotaxis often function together, as bacteria can use both magnetotactic and aerotactic systems to find proper oxygen concentrations. This is referred to as magneto-aerotaxis.[6] By orienting towards the Earth's poles, marine bacteria are able to direct their movement downwards, towards the anaerobic/micro aerobic sediments. This allows bacteria to change metabolic environments, which can enable chemical cycles.[7]

Magnetosomes

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Magnetosomes contain crystals - often magnetite (Fe3O4).[8] Some extremophile bacteria from sulfurous environments have been isolated with greigite (an iron-sulfide compound Fe3S4).[9] Some magnetotactic bacteria also contain pyrite (FeS2) crystals, possibly as a transformation product of greigite.[10] These crystals are contained within a bilayer membrane called the magnetosome membrane which is embedded with specific proteins. There are many different shapes of crystals. Crystal shape is typically consistent within a bacterial species.[2] The most common arrangement of magnetosomes is in chains which allows a maximum magnetic dipole moment to be created.[1] Within bacteria, there can be many chains of magnetosomes of different lengths that tend to align along the long axis of bacterial cell.[4] The dipole moment created from the chains of magnetosomes allows the bacteria to align with the magnetic field as they move.[1] Once magnetic bacteria die, they are able to orient themselves to the Earth's magnetic field but they are incapable of migrating along the field.[4]

Hemispheres and magnetic fields

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In the northern hemisphere, north-seeking bacteria move downwards towards sediment (parallel to the magnetic field). In the southern hemisphere, south seeking bacteria dominate and move downwards toward the sediment (antiparallel to the magnetic field).[6] It was originally thought by scientists that south seeking bacteria would move upwards in the north hemisphere, towards very high concentrations of oxygen. This would negatively select south seeking bacteria; so that north seeking bacteria dominate in the northern hemisphere and vice versa. However, south-seeking bacteria have been found in the northern hemisphere. Additionally, both north and south seeking magnetic bacteria, are found even at the Earth's magnetic equator, where the field is directed horizontally.[1]

See also

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Notes and references

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  1. ^ a b c d Lefevre, C. T.; Bazylinski, D. A. (4 September 2013). "Ecology, Diversity, and Evolution of Magnetotactic Bacteria". Microbiology and Molecular Biology Reviews. 77 (3): 497–526. doi:10.1128/MMBR.00021-13. PMC 3811606. PMID 24006473.
  2. ^ a b Yan, Lei; Zhang, Shuang; Chen, Peng; Liu, Hetao; Yin, Huanhuan; Li, Hongyu (October 2012). "Magnetotactic bacteria, magnetosomes and their application". Microbiological Research. 167 (9): 507–519. doi:10.1016/j.micres.2012.04.002. PMID 22579104.
  3. ^ a b Smith, M.J.; Sheehan, P.E.; Perry, L.L.; O’Connor, K.; Csonka, L.N.; Applegate, B.M.; Whitman, L.J. (August 2006). "Quantifying the Magnetic Advantage in Magnetotaxis". Biophysical Journal. 91 (3): 1098–1107. Bibcode:2006BpJ....91.1098S. doi:10.1529/biophysj.106.085167. PMC 1563769. PMID 16714352.
  4. ^ a b c Frankel, Richard B (2003). "Biological Permanent Magnets". Hyperfine Interactions. 151 (1): 145–153. Bibcode:2003HyInt.151..145F. doi:10.1023/B:HYPE.0000020407.25316.c3. S2CID 41997803.
  5. ^ Bennet, Mathieu A.; Eder, Stephan H. K. (5 July 2016), Faivre, Damien (ed.), "Magnetoreception and Magnetotaxis", Iron Oxides (1 ed.), Wiley, pp. 567–590, doi:10.1002/9783527691395.ch22, ISBN 978-3-527-33882-5, retrieved 24 April 2022
  6. ^ a b Encyclopedia of microbiology. Moselio Schaechter (3rd ed.). [Amsterdam]: Elsevier. 2009. ISBN 978-0-12-373944-5. OCLC 399645273.{{cite book}}: CS1 maint: others (link)
  7. ^ Li, Jinhua; Liu, Peiyu; Wang, Jian; Roberts, Andrew P.; Pan, Yongxin (December 2020). "Magnetotaxis as an Adaptation to Enable Bacterial Shuttling of Microbial Sulfur and Sulfur Cycling Across Aquatic Oxic-Anoxic Interfaces". Journal of Geophysical Research: Biogeosciences. 125 (12). Bibcode:2020JGRG..12506012L. doi:10.1029/2020JG006012. ISSN 2169-8953. S2CID 228886950.
  8. ^ Lower, Brian H.; Bazylinski, Dennis A. (2013). "The Bacterial Magnetosome: A Unique Prokaryotic Organelle". Journal of Molecular Microbiology and Biotechnology. 23 (1–2): 63–80. doi:10.1159/000346543. ISSN 1660-2412. PMID 23615196. S2CID 25856024.
  9. ^ Dusenbery, David B. (2009). Living at micro scale : the unexpected physics of being small. Cambridge, Mass.: Harvard University Press. ISBN 9780674031166.
  10. ^ Mann, Stephen; Sparks, Nicholas H. C.; Frankel, Richard B.; et al. (1990). "Biomineralization of ferrimagnetic greigite (Fe3S4) and iron pyrite (FeS2) in a magnetotactic bacterium". Nature. 343 (6255) (published 18 January 1990): 258–261. Bibcode:1990Natur.343..258M. doi:10.1038/343258a0. S2CID 4351424.

Further reading

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