Magnetotactic bacteria align along the Earth's magnetic field using an organelle called the magnetosome, a biomineralized magnetite (Fe(II)Fe(III)2O4) or greigite (Fe(II)Fe(III)2S4) crystal embedded in a lipid vesicle. Although the need for both iron(II) and iron(III) is clear, little is known about the biological mechanisms controlling their ratio. Here we present the structure of the magnetosome-associated protein MamP and find that it is built on a unique arrangement of a self-plugged PDZ domain fused to two magnetochrome domains, defining a new class of c-type cytochrome exclusively found in magnetotactic bacteria. Mutational analysis, enzyme kinetics, co-crystallization with iron(II) and an in vitro MamP-assisted magnetite production assay establish MamP as an iron oxidase that contributes to the formation of iron(III) ferrihydrite eventually required for magnetite crystal growth in vivo. These results demonstrate the molecular mechanisms of iron management taking place inside the magnetosome and highlight the role of magnetochrome in iron biomineralization.
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Article Synopsis
- Earth's abundance of iron has been essential for the development of life, influencing biochemical processes and leading to the emergence of early life forms near hydrothermal vents.
- Iron also plays a role in the evolution of organisms like magnetotactic bacteria, which can detect the Earth's geomagnetic field, showing adaptations beyond humans' conventional senses.
- Research on species such as zebrafish and pigeons indicates that various life forms have specialized mechanisms for geomagnetic sensing, hinting at complex interactions in the brain related to magnetic fields and their implications for human magnetoreception.
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