Biomimetic Magnetite Formation: From Biocombinatorial Approaches to Mineralization Effects

Baumgartner, Jens; Carillo, Maria Antonietta; Eckes, Kevin M.; Werner, P.; Faivre, Damien

doi:10.1021/la404290c

Cited by 57 publications

(73 citation statements)

References 48 publications

(112 reference statements)

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“…Further studies with Mms7ct indicate that it and other Mms proteins may play a more significant role in controlling magnetite mineral structure than previously hypothesized. Beyond simple control of size and shape of magnetite (29,30), they may also template the crystal lattice of the mineral itself similar to what has been observed with calcium biomineralization, where unstable crystal forms and phases of the mineral are stabilized by interaction with peptides and other macromolecules (1,2). In the specific case of iron minerals, lattice stabilization could also affect the redox potential of individual Fe atoms within the mineral.…”

Section: Discussionmentioning

confidence: 88%

“…In addition to redox partners that are necessary to generate both Fe(II) and Fe(III), there also exist small magnetosome proteins proposed to template mineralization by direct binding to the material (28) analogous to the more wellunderstood mineralization of calcium. These Mms proteins were identified by their tight association with the magnetite nanoparticles isolated from magnetotactic bacteria and have been shown experimentally to be able to control mineral shape in vitro through their highly acidic C-terminal sequences (29,30). Similar to other magnetotactic bacteria, the MAI of AMB-1 contains multiple mms genes, mms5 (mamG), mms6, and mms7 (mamD), which have been previously shown to possess overlapping genetic function as all genes must be deleted to observe the resulting biomineralization defect (12).…”

Section: Mineralization Of Iron Oxides From Fe(ii) With Magnetosome Pmentioning

confidence: 99%

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Genetic and biochemical investigations of the role of MamP in redox control of iron biomineralization inMagnetospirillum magneticum

Jones

Wilson

Brown

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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Magnetotactic bacteria have evolved complex subcellular machinery to construct linear chains of magnetite nanocrystals that allow the host cell to sense direction. Each mixed-valent iron nanoparticle is mineralized from soluble iron within a membrane-encapsulated vesicle termed the magnetosome, which serves as a specialized compartment that regulates the iron, redox, and pH environment of the growing mineral. To dissect the biological components that control this process, we have carried out a genetic and biochemical study of proteins proposed to function in iron mineralization. In this study, we show that the redox sites of c-type cytochromes of the Magnetospirillum magneticum AMB-1 magnetosome island, MamP and MamT, are essential to their physiological function and that ablation of one or both heme motifs leads to loss of function, suggesting that their ability to carry out redox chemistry in vivo is important. We also develop a method to heterologously express fully heme-loaded MamP from AMB-1 for in vitro biochemical studies, which show that its Fe(III)-Fe(II) redox couple is set at an unusual potential (−89 ± 11 mV) compared with other related cytochromes involved in iron reduction or oxidation. Despite its low reduction potential, it remains competent to oxidize Fe(II) to Fe(III) and mineralize iron to produce mixed-valent iron oxides. Finally, in vitro mineralization experiments suggest that Mms mineral-templating peptides from AMB-1 can modulate the iron redox chemistry of MamP.

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Section: Discussionmentioning

confidence: 88%

Section: Mineralization Of Iron Oxides From Fe(ii) With Magnetosome Pmentioning

confidence: 99%

Genetic and biochemical investigations of the role of MamP in redox control of iron biomineralization inMagnetospirillum magneticum

Jones

Wilson

Brown

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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“…While such processes lead to the formation of SSD particles, imaging by transmission electron microscopy (TEM) has shown the particles to be widely dispersed in size due to aggregation20. The use of additives was reported to control the mechanism of magnetite formation and possibly the resulting nanoparticle dimensions2122232425. Here, we show that the addition of polyarginine mostly leads to the formation of 40 nm monodisperse magnetite particles that are made from 10 nm sub-domains, yet possess true SSD properties.…”

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confidence: 70%

Single crystalline superstructured stable single domain magnetite nanoparticles

Reichel

Kovács

Kumari

et al. 2017

Sci Rep

Self Cite

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Magnetite nanoparticles exhibit magnetic properties that are size and organization dependent and, for applications that rely on their magnetic state, they usually have to be monodisperse. Forming such particles, however, has remained a challenge. Here, we synthesize 40 nm particles of magnetite in the presence of polyarginine and show that they are composed of 10 nm building blocks, yet diffract like single crystals. We use both bulk magnetic measurements and magnetic induction maps recorded from individual particles using off-axis electron holography to show that each 40 nm particle typically contains a single magnetic domain. The magnetic state is therefore determined primarily by the size of the superstructure and not by the sizes of the constituent sub-units. Our results fundamentally demonstrate the structure – property relationship in a magnetic mesoparticle.

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“…21 VSM showed that the saturation magnetization (M s ) was 77 Am 2 /kg and that the coercivity (H c ) was 8 mT (Figure 7c), which reflect the decrease in the average crystal size as compared to the control (Figure 3e). The same Table 1, entry (a) 4, (b) 1, (c) 5, (d) 2, (e) 8, (f) 7 and (g) 3, which demonstrate that all crystal sizes between ∼15 nm and ∼60 nm are accessible through the manipulation of the experimental conditions.…”

Section: Crystal Growth and Designmentioning

confidence: 93%

A Bioinspired Coprecipitation Method for the Controlled Synthesis of Magnetite Nanoparticles

Lenders¹,

Altan

Bomans³

et al. 2014

Crystal Growth & Design

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Nature often uses precursor phases for the controlled development of crystalline materials with welldefined morphologies and unusual properties. Mimicking such a strategy in in vitro model systems would potentially lead to the water-based, room-temperature synthesis of superior materials. In the case of magnetite (Fe 3 O 4 ), which in biology generally is formed through a ferrihydrite precursor, such approaches have remained largely unexplored. Here we report on a simple protocol that involves the slow coprecipitation of Fe III /Fe II salts through ammonia diffusion, during which ferrihydrite precipitates first at low pH values and is converted to magnetite at high pH values. Direct coprecipitation often leads to small crystals with superparamagnetic properties. Conversely, in this approach, the crystallization kineticsand thereby the resulting crystal sizescan be controlled through the NH 3 influx and the Fe concentration, which results in single crystals with sizes well in the ferrimagnetic domain. Moreover, this strategy provides a convenient platform for the screening of organic additives as nucleation and growth controllers, which we demonstrate for the biologically derived M6A peptide. ■ INTRODUCTIONLiving organisms exploit the properties of minerals by building a wide variety of specialized organic−inorganic hybrid materials for a variety of purposes, such as for protection and skeletal support and also for navigation and the detection of light. 1,2 The high level of control over the composition, structure, size, and morphology of such biominerals results in materials with amazing complexity and fascinating functionality that are in strong contrast with those of geological minerals and often surpass those of synthetic analogues. 3 Consequently, the processes involved in biomineralization have intrigued scientists for many decades since they could provide sustainable production routes for advanced materials with highly controllable and specialized properties. 4,5 With inspiration from biological mineralization processes, many studies have addressed the interaction between organic and inorganic components using in vitro experiments and in particular have addressed the biomimetic formation of calcium carbonate, 6 calcium phosphate, 7 and silica-based materials. 8 For these systems, a large variety of synthetic methods were developed, which allow for the controlled deposition of minerals in the presence of organic additives and templates. For the formation of crystalline biominerals, the use of precursor phases is of special interest since they allow the efficient transport of significant amounts of material and provide the organism with a feasible route to minerals with complex, nonequilibrium morphologies. 9 The development of precursor-based strategies for in vitro mineralization has boosted the field of bioinspired crystallization and provided a toolbox with which to mimic the effect of biological templates, additives, and confinement in a laboratory environment. This development has also allowed researc...

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Biomimetic Magnetite Formation: From Biocombinatorial Approaches to Mineralization Effects

Cited by 57 publications

References 48 publications

Genetic and biochemical investigations of the role of MamP in redox control of iron biomineralization inMagnetospirillum magneticum

Genetic and biochemical investigations of the role of MamP in redox control of iron biomineralization inMagnetospirillum magneticum

Single crystalline superstructured stable single domain magnetite nanoparticles

A Bioinspired Coprecipitation Method for the Controlled Synthesis of Magnetite Nanoparticles

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