Combined genomic and structural analyses of a cultured magnetotactic bacterium reveals its niche adaptation to a dynamic environment

Araujo, Ana Carolina Vieira; Morillo, Viviana; Cypriano, Jefferson; Teixeira, Lia Cardoso Rocha Saraiva; Leão, Pedro; Lyra, Sidcley; Almeida, Luiz Gonzaga Paula de; Bazylinski, Dennis A.; Vasconcellos, Ana Tereza Ribeiro de; Abreu, Fernanda; Lins, Ulysses

doi:10.1186/s12864-016-3064-9

Cited by 18 publications

(18 citation statements)

References 72 publications

(102 reference statements)

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“…Third, crystal growth and morphology in strains WYHR‐1 (this study), AV‐1 (Lefèvre, Pósfai, et al, 2011), and MYR‐1 (Li et al, 2015) differ significantly from those in MTB of the Alphaproteobacteria and Gammaproteobacteria classes. Magnetotactic Alphaproteobacteria and Gammaproteobacteria generally biomineralize magnetite with symmetric morphologies, including octahedra ({111} forms) (Araujo et al, 2016; Zhang et al, 2017), cubo‐octahedra ({111} + {100} forms) (Faivre et al, 2008; Li, Ge, et al, 2013; Mann et al, 1984), and elongated hexagonal prisms ({111} + {110} + {100} forms) (Li et al, 2017; Meldrum et al, 1993a, 1993b). Unlike the multiple‐step growth for elongated asymmetric crystals observed in strains WYHR‐1 (this study), AV‐1 (Lefèvre, Pósfai, et al, 2011), and MYR‐1 (Li et al, 2015), symmetric crystals generally have homothetical growth, that is, constant width/length ratio in a given MTB species (Lefèvre, Trubitsyn, Abreu, Kolinko, Jogler, & de Almeida, 2013; Li et al, 2017; Meldrum et al, 1993a, 1993b; Sparks et al, 1990; Zhang et al, 2017).…”

Section: Discussionmentioning

confidence: 99%

“…Consistent with the phylogenetic and physiological diversity of MTB, magnetosomes also have diverse crystal morphologies and compositions (Pósfai, Lefèvre, et al, 2013). For instance, magnetotactic Alphaproteobacteria and Gammaproteobacteria biomineralize octahedral, cubo‐octahedral, or elongated‐prismatic crystals of magnetite, while MTB in the phyla Nitrospirae and Omnitrophica produce bullet‐shaped magnetite crystals (Araujo et al, 2016; Kolinko et al, 2016; Li, Ge, et al, 2013; Li et al, 2017; Meldrum et al, 1993a; Sparks et al, 1990; Zhang et al, 2017). Magnetotactic Deltaproteobacteria synthesize either magnetite‐type or greigite‐type crystals, or both within a single cell (Lefèvre & Bazylinski, 2013).…”

Section: Introductionmentioning

confidence: 99%

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Bullet‐Shaped Magnetite Biomineralization Within a Magnetotactic Deltaproteobacterium: Implications for Magnetofossil Identification

Menguy

Roberts

et al. 2020

JGR Biogeosciences

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Magnetite produced by magnetotactic bacteria (MTB) provides stable paleomagnetic signals because it occurs as natural single‐domain magnetic nanocrystals. MTB can also provide useful paleoenvironmental information because their crystal morphologies are associated with particular bacterial groups and the environments in which they live. However, identification of the fossil remains of MTB (i.e., magnetofossils) from ancient sediments or rocks is challenging because of their generally small sizes and because the growth, morphology, and chain assembly of magnetite within MTB are not well understood. Nanoscale characterization is, therefore, needed to understand magnetite biomineralization and to develop magnetofossils as biogeochemical proxies for paleoenvironmental reconstructions. Using advanced transmission electron microscopy, we investigated magnetite growth and chain arrangements within magnetotactic Deltaproteobacteria strain WYHR‐1, which reveals how the magnetite grows to form elongated, bullet‐shaped nanocrystals. Three crystal growth stages are recognized: (i) initial isotropic growth to produce nearly round ~20 nm particles, (ii) subsequent anisotropic growth along the [001] crystallographic direction to ~75 nm lengths and ~30–40 nm widths, and (iii) unidirectional growth along the [001] direction to ~180 nm lengths, with some growing to ~280 nm. Crystal growth and habit differ from that of magnetite produced by other known MTB strains, which indicates species‐specific biomineralization. These findings suggest that magnetite biomineralization might be much more diverse among MTB than previously thought. When characterized adequately at species level, magnetofossil crystallography, and apomorphic features are, therefore, likely to become useful proxies for ancient MTB taxonomic groups or species and for interpreting the environments in which they lived.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Bullet‐Shaped Magnetite Biomineralization Within a Magnetotactic Deltaproteobacterium: Implications for Magnetofossil Identification

Menguy

Roberts

et al. 2020

JGR Biogeosciences

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“…Magnetotactic Deltaproteobacteria form bullet-shaped magnetite but with straight particles elongated along the [001] direction, with generally one flat {001} face (e.g., Candidatus Magnetcampylobacter weiyangensis strain WYHR-1) (Li, Menguy, et al, 2020) or a double triangle shape at its bottom (e.g., strains RS-1 and AV-1) Pósfai et al, 2006). In contrast, magnetotactic Alphaproteobacteria, Etaproteobacteria, and Gammaproteobacteria generally produce magnetite with symmetric morphologies, including octahedral {111} forms (e.g., Magnetofaba australis strain IT-1 and uncultured magnetotactic coccus strain SHHC-1) (Araujo et al, 2016;Zhang et al, 2017), cubo-octahedral ({111} + {100} forms) (e.g., Magnetotactic spirillum strains MS-1, MMS-1, MSR-1, and AMB-1) Li, Ge, et al, 2013;Mann et al, 1984;Meldrum et al, 1993a), and elongated hexagonal prisms with {111} + {110}…”

Section: Biomineralization and Magnetism Of Magnetosomal Magnetite Frmentioning

confidence: 99%

Biomineralization and Magnetism of Uncultured Magnetotactic Coccus Strain THC‐1 With Non‐chained Magnetosomal Magnetite Nanoparticles

Menguy

Leroy

et al. 2020

JGR Solid Earth

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Magnetotactic bacteria (MTB) have long fascinated geologists and biologists because they biomineralize intracellular single domain (SD) magnetite crystals within magnetosomes that are generally organized into single or multiple chains. MTB remains in the geological record (magnetofossils) are ideal magnetic carriers and are used to reconstruct paleomagnetic and paleoenvironmental information. Here we studied the biomineralization and magnetic properties of magnetosomal magnetite produced by uncultured magnetotactic coccus strain THC-1, isolated from the Tanghe River, China, by combining transmission electron microscope (TEM) and rock magnetic approaches. Our results reveal that THC-1 produces hexagonal prismatic magnetite single crystals that are elongated along the [111] crystallographic direction. Most of the magnetite crystals within THC-1 are dispersed without obvious chain assembly. A whole-cell THC-1 sample yields a normal SD hysteresis loop and a Verwey transition temperature of 112 K. In contrast to MTB cells with magnetosome chain(s), THC-1 cells have a teardrop first-order reversal curve distribution that is indicative of moderate interparticle interactions. Due to the absence of a magnetosome chain, THC-1 has relatively high values of the difference between the saturation isothermal remanent magnetization (SIRM) below and above the Verwey transition temperature for field-cooled and zero field-cooled SIRM curves (δ FC , δ ZFC) and a low δ FC /δ ZFC value. Together with previous studies, our results demonstrate that some MTB species/strains can form magnetosomal magnetite without linear chain configurations. Magnetite produced by MTB has diverse magnetic properties, which are distinctive but not necessarily unique compared to other magnetite types. Therefore, combining bulk magnetic measurements and TEM observations remains necessary for identifying magnetofossils in the geological record. Plain Language Summary Magnetotactic bacteria (MTB) are intriguing because they produce magnetic nanocrystals of magnetite (Fe 3 O 4) or greigite (Fe 3 S 4) within intracellular organelles (magnetosomes) that can leave tiny magnetic fossils (magnetofossils) in the geological record. Magnetofossil identification for paleoenvironmental and paleomagnetic purposes is based heavily on knowledge of modern MTB that often organize magnetic particles into chain(s). We studied here the crystallographic and magnetic properties of uncultured magnetotactic coccus strain THC-1 in which magnetosomal magnetite particles are dispersed without obvious chain assembly. In contrast to whole-cell MTB samples with magnetosome chain(s), THC-1 has distinctive magnetic properties. Together with previous studies, our results demonstrate that MTB magnetite has diverse magnetic properties that are distinctive but not necessarily unique compared to other magnetite types. This indicates that combining magnetic measurements and transmission electron microscope observations remains necessary for identifying magnetofossils.

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“…Although such magnetic enrichment approaches are efficient for isolation of environmental MTB, members of the Alphaproteobacteria and ‘Etaproteobacteria’ classes tend to predominate when these separation methods are used (14, 18–23). Since they are in higher concentration on the environment, are usually faster (24, 25) and more resistant to higher oxygen concentration than other MTB (26). The time used in standard concentration methods (20–30 minutes) make it hard the separation of MTB that have slow swimming ability (e.g., Magnetovibrio blakemorei MV-1) (27).…”

Section: Introductionmentioning

confidence: 99%

Biodiversity of Magnetotactic Bacteria in the Freshwater Lake Beloe Bordukovskoe, Russia

Koziaeva

Alekseeva

Uzun

et al. 2019

Preprint

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20Magnetotactic bacteria (MTB) belong to different taxonomic groups according to 16S 21 rRNA or whole-genome phylogeny. Magnetotactic representatives of the class 22 Alphaproteobacteria and the order Magnetococcales are the most frequently isolated 23 MTB in environmental samples. This bias is due in part to limitations of currently 24 2 available methods to isolate MTB. Here we describe a new approach for isolation of 25 MTB cells that does not depend on cell motility and will allow collecting bacteria 26 both south-and north-seeking movement. We also designed a specific primer system 27 for the gene encoding the MamK protein that effectively detects diverse MTB 28 phylogenetic groups in any sample type. The combination of these two approaches 29 allowed the identification of a novel MTB belonging to the family Syntrophaceae of 30 the class Deltaproteobacteria. Moreover, we found that Nitrospirae bacteria 31 predominated in the MTB fraction of a sample taken from Lake Beloe Bordukovskoe 32 near Moscow, Russia. We describe the novel dominant Nitrospirae bacterium 33 'Candidatus Magnetomonas plexicatena' and propose its taxonomic name. 34 IMPORTANCE 35Among magnetotactic bacteria (MTB), the members of phyla Proteobacteria, 36 Nitrospirae and 'Ca. Omnitrophica' have been studied extensively using the existing 37 approaches. However, in recent years, analyses of the metagenomic databases have 38 revealed the presence of MTB in phylogenetic groups, which had not been previously 39 detected using standard approaches. This finding indicates that the biodiversity of 40 MTB is much broader than is currently known. The difficulty of identifying MTB 41 based on comparative analysis of 16S rRNA genes lies in the existence of closely 42 related species of non-magnetotactic bacteria. Moreover, there is an absence of 16S 43 rRNA MTB sequences from such taxonomic groups as 'Latescibacteria' and 44 Planctomycetes. In addition, the standard methods of separating MTB can benefit 45 bacteria with high motility. Developing novel strategies for investigation offers great 46 3 promise towards identifying MTB groups. We have proposed new approach to 47 separate MTB cells from environmental samples and have also proposed a specific 48 primer system for the MTB identification. 49 INTRODUCTION 50 Prokaryotes having directed active movement that is guided by geomagnetism are 51 collectively called magnetotactic bacteria (MTB) (1). The term MTB has no 52 taxonomic meaning such that it representatives are physiologically, morphologically 53 and phylogenetically different and share only the ability to synthesize special 54 organelles called magnetosomes. Magnetosomes consist of nanosized magnetite 55 (Fe 3 O 4 ) (2) or greigite (Fe 3 S 4 ) (3-5) crystals surrounded by a lipid bilayer membrane 56having proteins specific to the organelle (6, 7). Magnetosomes frequently assemble 57 into chains inside the cell (8). MTB evolved the ability to conduct a special type of 58 movement called magnetotaxis, which is based on orientation relative...

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Combined genomic and structural analyses of a cultured magnetotactic bacterium reveals its niche adaptation to a dynamic environment

Cited by 18 publications

References 72 publications

Bullet‐Shaped Magnetite Biomineralization Within a Magnetotactic Deltaproteobacterium: Implications for Magnetofossil Identification

Bullet‐Shaped Magnetite Biomineralization Within a Magnetotactic Deltaproteobacterium: Implications for Magnetofossil Identification

Biomineralization and Magnetism of Uncultured Magnetotactic Coccus Strain THC‐1 With Non‐chained Magnetosomal Magnetite Nanoparticles

Biodiversity of Magnetotactic Bacteria in the Freshwater Lake Beloe Bordukovskoe, Russia

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