Abstract
The Magnetospirillum magneticum AMB-1 species is one of the most widely used magnetotactic bacterial strains for producing magnetosomes under laboratory conditions. Nevertheless, there exist several challenges in expanding and purifying the AMB-1 culture due to the restricted culture conditions. In an attempt to enrich the production of magnetosomes, this study reports the utilization of fermenter culture, which substantially promotes the cell densities at different concentrations of iron content. The experimental results confirmed magnetosomes’ high yield (production rate of 21.1 mg L−1) at the iron content of 0.2 μmol L−1. Moreover, different characterization techniques systematically confirmed the coated lipid membrane, particle size, dispersity, stability, and elemental composition of magnetosomes. Notably, the fermenter culture-based process resulted in highly discrete, dispersed, and stable magnetosomes with an average particle diameter of 50 nm and presented the integrated lipid membrane around the surface. The chemical composition by EDS of magnetosomes represented the presence of various elements, i.e., C, O, Na, P, and Fe, at appropriate proportions. In conclusion, the culture method in our study effectively provides a promising approach towards the culture of the magnetotactic bacterium for the enriched production of magnetosomes.
Highlights
Since the first report by Blakemore in 1975 [1], magnetotactic bacteria, aquatic prokaryotes that respond to the Earth’s geomagnetic field, have garnered enormous interest due to their ability to synthesize intracellular organelles magnetosomes [2,3]
The microscopic observations elucidated that the Magnetospirillum magneticum bacteria were whirling and certainly self-restrained in the direction of the applied magnetic field
It was observed that most of the AMB-1 bacteria used in this study could synthesize magnetic nanoparticles with excellent magnetotactic properties
Summary
Since the first report by Blakemore in 1975 [1], magnetotactic bacteria, aquatic prokaryotes that respond to the Earth’s geomagnetic field, have garnered enormous interest due to their ability to synthesize intracellular organelles magnetosomes [2,3]. These subcellular membrane-bound constituents are composed of nanometer-sized, iron-based magnetite (Fe3 O4 ) or greigite (Fe3 S4 ) [4,5] crystals, arranged as chains [6].
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