Magnetospirillum Explained

Magnetospirillum is a Gram-negative, microaerophilic genus of magnetotactic bacteria, first isolated from pond water by the microbiologist R. P. Blakemore in 1975.[1] [2] They have a spiral (helical) shape and are propelled by a polar flagellum at each end of their cells. The three main species identified are M. magnetotacticum strain MS-1, M. griphiswaldense strain MSR-1, and M. magneticum strain AMB-1.[3]

Habitat

The first discovered magnetotactic bacteria came from various environments including seawater, lakes, ponds, silt and soils in 1975 – including Magnetospirillum.[4] The typical habitat of Magnetospirillum species consists of shallow fresh water and sediments, characterized by low concentrations of oxygen for growth (microaerophilic) where they live in the upper portion of the sediment (oxic/anoxic interface) and prefer an oxygen gradient of around 1–3%.

Magnetotaxis

Probably the most peculiar characteristic of Magnetospirillum species is their capacity to orient themselves according to Earth's magnetic field, magnetotaxis. However, they are also impacted by artificial magnetic fields. This is achieved through the presence of special organelles called magnetosomes in the bacterium's cytoplasm. Because the magnetosomes in Magnetospirillum are arranged in chains, the bacteria are able to move with magnetic fields to find a favorable growth environment.[5] However, species also resort to aerotaxis, to remain in favorable O2 concentration conditions. When the bacteria ingest iron, proteins inside their cells interact with it to produce tiny crystals of the mineral magnetite, the most magnetic mineral on Earth.[6]

Purification of magnetosomes is accomplished by use of a magnetic separation column after disruption of the cell membrane. If a detergent is used on purified magnetosomes, they tend to agglomerate rather than staying in chain form. Due to the high quality of the single-domain magnetic crystals, a commercial interest has developed in the bacteria. The crystals are thought to have the potential to produce magnetic tapes and magnetic target drugs.[2]

Species

Potential Applications

Due to the presence of magnetotaxis and magnetosomes within Magnetospirillum, some species have been studied in how they may be beneficial for use in a wide range of different fields such as those with medicinal and engineering practices.[9] One example is the recent research about how their magnetic properties could potentially introduce a new way of treating wastewater contaminated with heavy metals or be used for tumor hyperthermia due to their coupling abilities.[10] However, it is a challenge to begin to test and apply their unique abilities because of the difficulty with growing large amounts of Magnetospirillum cells and magnetosomes – this could be due to most species being microaerophilic and having specific O2 concentration requirements.[11]

Notes and References

    • 10.1126/science.170679. Blakemore75. Blakemore. 170679. Richard. 1975. Magnetotactic bacteria. Science. 190. 4212. 377–379. 1975Sci...190..377B. 5139699.
  1. Maratea. D.. Blakemore, R. P.. Aquaspirillum magnetotacticum sp. nov., a Magnetic Spirillum. International Journal of Systematic Bacteriology. 1981. 31. 4. 452–455. 10.1099/00207713-31-4-452. free.
  2. Web site: Encyclopedia of Microbiology . 2023-11-08 . ScienceDirect . en.
  3. Web site: Methods in Microbiology Book series ScienceDirect.com by Elsevier . 2023-11-08 . www.sciencedirect.com . en-us.
  4. Web site: Microbiological Research Journal ScienceDirect.com by Elsevier . 2023-11-08 . www.sciencedirect.com . en-us.
  5. News: Magnetic bacteria may help build future bio-computers . 7 May 2012 . BBC News .
  6. Parte. A.C.. Magnetospirillum. LPSN.
  7. Noguchi. Yasushi. Fujiwara. Taketomo. Yoshimatsu. Katsuhiko. Fukumori. Yoshihiro. 1999. Iron reductase for magnetite synthesis in the magnetotactic bacterium Magnetospirillum magnetotacticum. Journal of Bacteriology. 181. 7. 2142–2147. 10.1128/JB.181.7.2142-2147.1999. 10094692. 93627.
  8. Bazylinski . Dennis A. . Frankel . Richard B. . March 2004 . Magnetosome formation in prokaryotes . Nature Reviews Microbiology . en . 2 . 3 . 217–230 . 10.1038/nrmicro842 . 1740-1526.
  9. Jacob . Jobin John . Suthindhiran . K. . November 2016 . Magnetotactic bacteria and magnetosomes – Scope and challenges . Materials Science and Engineering: C . en . 68 . 919–928 . 10.1016/j.msec.2016.07.049.
  10. Web site: Methods in Microbiology Book series ScienceDirect.com by Elsevier . 2023-11-08 . www.sciencedirect.com . en-us.