Magnetospirillum gryphiswaldense
Classification
Domain: Bacteria
Phylum: Proteobacteria
Class: Alphaproteobacteria
Order: Rhodospirillales
Family: Rhodospirillaceae
Species
NCBI: [1] |
Magnetospirillum gryphiswaldense
Description and Significance
Describe the appearance, habitat, etc. of the organism, and why you think it is important.
Genome Structure
Describe the size and content of the genome. How many chromosomes? Circular or linear? Other interesting features? What is known about its sequence?
Cell Structure and Nanomagnet Synthesis
Cell Structure
As previously mentioned, M. gryphiswaldense are spirilla, or helically shaped single-celled microbes with rotating flagella at either end of their bodies [1,6]. Their cell walls are gram-negative, meaning that they lack a thick peptidoglycan layer [5]. M. gryphiswaldense are usually several micrometers long and have a diameter of about half a micrometer [13]. The magnetic moment of M. gryphiswaldense as measured by light scattering was found to be 2.53± 1.6×10^16〖Am〗^2 [1].
While there is not much literature on the reproduction of M. gryphiswaldense research has shown that the turn-around time from initial reproduction to a fully-functioning organism (producing nanomagnets) is about 24 hours under ideal conditions (iron and oxygen conditions) [2].
Nanomagnet Synthesis
M. gryphiswaldense synthesizes nanomagnets made of an iron oxide know as magnetite (Fe3O4), which is the most magnetic naturally occurring mineral on earth [1]. The magnetite nanomagnets are formed through the process of biologically controlled mineralization (BCM), where M. gryphiswaldense creates an organic mold, pulls in iron ions from the environment, and then oxidizes those ions so that they crystalize as magnetite [1]. The nanomagnets themselves are cuboctahedral in shape, and about 40-45 nm in size [11].
In M. gryphiswaldense, BCM occurs within the magnetosomes: organelles that each consist of a phospholipid and fatty acid membrane surrounding a growing nanomagnet [8]. These magnetosome vesicles the result of cytoplasmic membrane invagination, which occurs before magnetic crystal growth begins [1,11]. Once the magnetosome membrane has separated from the cytoplasmic membrane, its fatty acid and phospholipid proportions are slightly adjusted [8]. At least 18 specific proteins can be found within the magnetosome membrane as well, having attached to the magnetosome membrane either before or after membrane invagination [8]. M. gryphiswaldense arranges these magnetosomes in a linear configuration, held in place by cytoskeletal filaments [1].
Ecology
M. gryphiswaldense can be found in freshwater, aquatic environments where there is vertical chemical stratification (i.e., varying concentrations of oxygen and iron ions within the water) [1]. Specifically, M. gryphiswaldense is highly sensitive to oxygen concentrations; being microaerophilic, they prefer only very low levels of dissolved oxygen (around 0.5-1.0%) [1,6]. M. gryphiswaldense remains at an ideally oxygenated level within its environment through magnetotaxis [1]. The chain of magnetosomes within M. gryphiswaldense allows the microbe to be continually aligned with the geomagnetic field, providing a sense of direction [1]. If oxygen levels are too low, M. gryphiswaldense simply propels itself upwards in line with the geomagnetic field until it reaches an ideal oxygen concentration [1]. Likewise, if oxygen levels become too high, the microbe simple reverses its direction of flagella rotation, and swims down along the geomagnetic field lines until it reaches lower oxygen levels [1]. By limiting movement to a fixed axis that aligns with the oxygen gradient, M. gryphiswaldense is able to efficiently explore an maneuver within its environment.
Applications
M. gryphiswaldense is potentially a highly lucrative microbe in terms of biotechnology applications because it synthesizes strong nanomagnets with high precision; synthetic nanomagnet production is not nearly as precise or dependable [3]. Magnetosomes can serve a wide range of different purposes because they are very small but can also be easily separated from mixtures because they are magnetic [3]. Additionally, the surface properties of the magnetosome membrane make it relatively simple to attach amounts of specific molecules to the magnetosome surface [10]. Some specific applications for both entire MTBs (including M. gryphiswaldense) and magnetosomes alone are listed below [10].
Magnetoactive Bacteria Applications
- Drug Delivery
- Bioremediation
- Energy Generation
Magnetosome Applications
- Drug Delivery
- Cell Separation
- Food Safety
- DNA and Antigen Recovery or Detection
- MRA Contrast Agent
- Hyperthermia
- Enzyme immobilization
References
[4] Magnetospirillum gryphiswaldense (ID 1508). (2014).
[6] [https://doi.org/10.1007/s007060200047 Šafařík, I., & Šafaříkov&#, M. (2002). Magnetic Nanoparticles and Biosciences. Monatshefte f�r Chemie / Chemical Monthly, 133(6), 737–759.]
Author
Page authored by MacKenzie Emch, student of Prof. Jay Lennon at IndianaUniversity.