Abstract

The biomineralization pathway of magnetite in magnetotactic bacteria is still poorly understood and a matter of intense debates. In particular, the existence, nature, and location of possible mineral precursors of magnetite are not clear. One possible precursor has been suggested to be ferritin-bound ferrihydrite. To clarify its role for magnetite biomineralization, we analyzed and characterized ferritin-like proteins from the magnetotactic alphaproteobacterium Magnetospirillum gryphiswaldense MSR-1, employing genetic, biochemical, and spectroscopic techniques. Transmission Mössbauer spectroscopy of the wild type (WT) and a bacterioferritin (bfr) deletion strain uncovered that the presence of ferrihydrite in cells is coupled to the presence of Bfr. However, bfr and dps deletion mutants, encoding another ferritin-like protein, or even mutants with their codeletion had no impact on magnetite formation in MSR-1. Thus, ferritin-like proteins are not involved in magnetite biomineralization and Bfr-bound ferrihydrite is not a precursor of magnetite biosynthesis. Using transmission electron microscopy and bacterial two-hybrid and electrophoretic methods, we also show that MSR-1 Bfr is an atypical representative of the Bfr subfamily, as it forms tetraeicosameric complexes from two distinct subunits. Furthermore, our analyses revealed that these subunits are functionally divergent, with Bfr1 harboring a ferroxidase activity while only Bfr2 contributes to heme binding. Because of this functional differentiation and the poor formation of homooligomeric Bfr1 complexes, only heterooligomeric Bfr protects cells from oxidative stress in vivo. In summary, our results not only provide novel insights into the biomineralization of magnetite but also reveal the unique properties of so-far-uncharacterized heterooligomeric bacterioferritins.IMPORTANCE Magnetotactic bacteria like Magnetospirillum gryphiswaldense are able to orient along magnetic field lines due to the intracellular formation of magnetite nanoparticles. Biomineralization of magnetite has been suggested to require a yet-unknown ferritin-like ferrihydrite component. Here, we report the identification of a bacterioferritin as the source of ferrihydrite in M. gryphiswaldense and show that, contrary to previous reports, bacterioferritin is not involved in magnetite biomineralization but required for oxidative stress resistance. Additionally, we show that bacterioferritin of M. gryphiswaldense is an unusual member of the bacterioferritin subfamily as it is composed of two functionally distinct subunits. Thus, our findings extend our understanding of the bacterioferritin subfamily and also solve a longstanding question about the magnetite biomineralization pathway.

Highlights

  • IMPORTANCE Magnetotactic bacteria like Magnetospirillum gryphiswaldense are able to orient along magnetic field lines due to the intracellular formation of magnetite nanoparticles

  • This analysis revealed the presence of two distinct bands of ϳ500 kDa and ϳ740 kDa, respectively (Fig. 1D). While these results suggested the presence of two different Bfr complexes, 2D-blue native (BN)/SDS-PAGE analyses revealed that Bfr1 and Bfr2 were present in both high-molecular weight (MW) bands (Fig. 1E)

  • In contrast to previous reports, which proposed a central role for a ferritin-like component in the magnetite biomineralization pathway [12,13,14,15], we were unable to detect any defects or alterations during magnetite biomineralization in the Δdps, Δbfr12, and Δdps/bfr12 ferritin-like mutants

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Summary

Introduction

IMPORTANCE Magnetotactic bacteria like Magnetospirillum gryphiswaldense are able to orient along magnetic field lines due to the intracellular formation of magnetite nanoparticles. Ferritin-like proteins with iron storage capability are found in the ferritin (Ftn), heme-containing bacterioferritin (Bfr), archaeoferritin (Afr), and DNA-binding proteins from starved cells (Dps) or Dps-like subfamilies [4,5,6]. All of these proteins share a four-helical bundle structural motif and are able to self-assemble into sphere-shaped hollow tetraeicosameric (Ftn, Bfr, and Afr) or dodecameric (Dps and Dps-like) nanocages that engulf an iron mineral core [4]. Biochemical, and spectroscopic techniques, we show that, contrary to previous assumptions, ferritin-like proteins are not required for magnetite biomineralization but involved in the resistance to oxidative stress. We show that the Bfr subunit requires interaction with Bfr to form stable nanocages

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