Diversity and ecology of and biomineralization by magnetotactic bacteria

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Summary The most well‐recognized magnetoreception behaviour is that of the magnetotactic bacteria (MTB), which synthesize membrane‐bounded magnetic nanocrystals called magnetosomes via a biologically controlled process. The magnetic minerals identified in prokaryotic magnetosomes are magnetite (Fe3O4) and greigite (Fe3S4). Magnetosome crystals, regardless of composition, have consistent, species‐specific morphologies and single‐domain size range. Because of these features, magnetosome magnetite crystals possess specific properties in comparison to abiotic, chemically synthesized magnetite. Despite numerous discoveries regarding MTB phylogeny over the last decades, this diversity is still considered underestimated. Characterization of magnetotactic microorganisms is important as it might provide insights into the origin and establishment of magnetoreception in general, including eukaryotes. Here, we describe the magnetotactic behaviour and characterize the magnetosomes from a flagellated protist using culture‐independent methods. Results strongly suggest that, unlike previously described magnetotactic protists, this flagellate is capable of biomineralizing its own anisotropic magnetite magnetosomes, which are aligned in complex aggregations of multiple chains within the cell. This organism has a similar response to magnetic field inversions as MTB. Therefore, this eukaryotic species might represent an early origin of magnetoreception based on magnetite biomineralization. It should add to the definition of parameters and criteria to classify biogenic magnetite in the fossil record.

Section: Introductionmentioning

confidence: 97%

Magnetosome magnetite biomineralization in a flagellated protist: evidence for an early evolutionary origin for magnetoreception in eukaryotes

Leão

Nagard

Yuan

et al. 2019

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“…Previous biodiversity studies revealed the intriguing polyphyletism of magnetic biomineralization within the bacteria domain (Lin et al, 2018). Most of the MTB described so far belong to three classes of Proteobacteria, and some are affiliated to the Nitrospirae and Omnitrophica phyla Lin et al, 2017a). Recent metagenomic data suggested that some bacteria within the Latescibacteria and Planctomycetes phyla could also biomineralize (Lin et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

“…QH-2 whose region harbouring the magnetosome genes contains few or no mobile elements and present a high stability within the genome (Lefèvre et al, 2011;Ji et al, 2014). Because different strains may support different evolutionary scenarios, it is difficult to arbitrate between vertical and horizontal inheritance, which feeds a permanent debate (Lefèvre et al, 2013a;Lin et al, 2017a).…”

Section: Introductionmentioning

confidence: 99%

Genomic study of a novel magnetotacticAlphaproteobacteriauncovers the multiple ancestry of magnetotaxis

Monteil

Perrière

Menguy

et al. 2018

Ecological and evolutionary processes involved in magnetotactic bacteria (MTB) adaptation to their environment have been a matter of debate for many years. Ongoing efforts for their characterization are progressively contributing to understand these processes, including the genetic and molecular mechanisms responsible for biomineralization. Despite numerous culture-independent MTB characterizations, essentially within the Proteobacteria phylum, only few species have been isolated in culture because of their complex growth conditions. Here, we report a newly cultivated magnetotactic, microaerophilic and chemoorganoheterotrophic bacterium isolated from the Mediterranean Sea in Marseille, France: Candidatus Terasakiella magnetica strain PR-1 that belongs to an Alphaproteobacteria genus with no magnetotactic relative. By comparing the morphology and the whole genome shotgun sequence of this MTB with those of closer relatives, we brought further evidence that the apparent vertical ancestry of magnetosome genes suggested by previous studies within Alphaproteobacteria hides a more complex evolutionary history involving horizontal gene transfers and/or duplication events before and after the emergence of Magnetospirillum, Magnetovibrio and Magnetospira genera. A genome-scale comparative genomics analysis identified several additional candidate functions and genes that could be specifically associated to MTB lifestyle in this class of bacteria.

“…MTB signature genes in metagenomic sequences obtained from Sakinaw Lake (Canada), a lake where the pH varies from 5.7 to 6.5 and the temperature ranges from 8 to 19 C (Perry, 1990), strongly indicate the possibility of a novel greigite-producing MTB belonging to the candidate phylum 'Latescibacteria' (formerly WS3) (Lin and Pan, 2015) although an MTB of this type was not physically observed from the lake. Recently, a partial greigite-type magnetosome gene cluster has been identified in a draft genome from a bacterium affiliated to Planctomycetes phylum obtained from the sediment of the White Oak River, North Carolina (Lin et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

“…These strains grow optimally at pH 9.0-9.5, but not at pH 8.0 (Lefèvre et al, 2011). Different morphotypes of MTB have also been found in saline-alkaline lakes in Inner Mongolia, China (Lin et al, 2017). An uncultured moderately thermophilic MTB from the Nitrospirae phylum was discovered in hot spring sediments collected from Great Boiling Springs, Nevada (Lefèvre et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

Culture‐independent characterization of a novel magnetotactic member affiliated to the Beta class of the Proteobacteria phylum from an acidic lagoon

Abreu

Leão

Vargas

et al. 2018

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Magnetotactic bacteria (MTB) comprise a group of motile microorganisms common in most mesothermal aquatic habitats with pH values around neutrality. However, during the last two decades, a number of MTB from extreme environments have been characterized including: cultured alkaliphilic strains belonging to the Deltaproteobacteria class of the Proteobacteria phylum; uncultured moderately thermophilic strains belonging to the Nitrospirae phylum; cultured and uncultured moderately halophilic or strongly halotolerant bacteria affiliated with the Deltaproteobacteria and Gammaproteobacteria classes and an uncultured psychrophilic species belonging to the Alphaproteobacteria class. Here, we used culture-independent techniques to characterize MTB from an acidic freshwater lagoon in Brazil (pH ∼ 4.4). MTB morphotypes found in this acidic lagoon included cocci, rods, spirilla and vibrioid cells. Magnetite (Fe O ) was the only mineral identified in magnetosomes of these MTB while magnetite magnetosome crystal morphologies within the different MTB cells included cuboctahedral (present in spirilla), elongated prismatic (present in cocci and vibrios) and bullet-shaped (present in rod-shaped cells). Intracellular pH measurements using fluorescent dyes showed that the cytoplasmic pH was close to neutral in most MTB cells and acidic in some intracellular granules. Based on 16S rRNA gene phylogenetic analyses, some of the retrieved gene sequences belonged to the genus Herbaspirillum within the Betaproteobacteria class of the Proteobacteria phylum. Fluorescent in situ hybridization using a Herbaspirillum-specific probe hybridized with vibrioid MTB in magnetically-enriched samples. Transmission electron microscopy of the Herbaspirillum-like MTB revealed the presence of many intracellular granules and a single chain of elongated prismatic magnetite magnetosomes. Diverse populations of MTB have not seemed to have been described in detail in an acid environment. In addition, this is the first report of an MTB phylogenetically affiliated with Betaproteobacteria class.