Magnetic properties of uncultivated magnetotactic bacteria and their contribution to a stratified estuary iron cycle

A P Chen; V M Berounsky; M K Chan; M G Blackford; C Cady; B M Moskowitz; P Kraal; E A Lima; R E Kopp; G R Lumpkin; B P Weiss; P Hesse; N G F Vella

doi:10.1038/ncomms5797

Magnetic properties of uncultivated magnetotactic bacteria and their contribution to a stratified estuary iron cycle

A P Chen
, V M Berounsky
, M K Chan
, M G Blackford
, C Cady
, B M Moskowitz
, P Kraal
, E A Lima
, R E Kopp
, G R Lumpkin
, B P Weiss
, P Hesse
, N G F Vella

Macquarie University
University of Rhode Island
University of Minnesota Twin Cities
Australian Nuclear Science and Technology Organisation
Rutgers - The State University of New Jersey, New Brunswick
Massachusetts Institute of Technology

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Of the two nanocrystal (magnetosome) compositions biosynthesized by magnetotactic bacteria (MTB), the magnetic properties of magnetite magnetosomes have been extensively studied using widely available cultures, while those of greigite magnetosomes remain poorly known. Here we have collected uncultivated magnetite- and greigite-producing MTB to determine their magnetic coercivity distribution and ferromagnetic resonance (FMR) spectra and to assess the MTB-associated iron flux. We find that compared with magnetite-producing MTB cultures, FMR spectra of uncultivated MTB are characterized by a wider empirical parameter range, thus complicating the use of FMR for fossilized magnetosome (magnetofossil) detection. Furthermore, in stark contrast to putative Neogene greigite magnetofossil records, the coercivity distributions for greigite-producing MTB are fundamentally left-skewed with a lower median. Lastly, a comparison between the MTB-associated iron flux in the investigated estuary and the pyritic-Fe flux in the Black Sea suggests MTB play an important, but heretofore overlooked role in euxinic marine system iron cycle.

Original language	English
Article number	4797
Number of pages	11
Journal	Nature Communications [E]
Volume	5
DOIs	https://doi.org/10.1038/ncomms5797
Publication status	Published - 2014

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Chen, A. P., Berounsky, V. M., Chan, M. K., Blackford, M. G., Cady, C., Moskowitz, B. M., Kraal, P., Lima, E. A., Kopp, R. E., Lumpkin, G. R., Weiss, B. P., Hesse, P., & Vella, N. G. F. (2014). Magnetic properties of uncultivated magnetotactic bacteria and their contribution to a stratified estuary iron cycle. Nature Communications [E], 5, Article 4797. https://doi.org/10.1038/ncomms5797

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title = "Magnetic properties of uncultivated magnetotactic bacteria and their contribution to a stratified estuary iron cycle",

abstract = "Of the two nanocrystal (magnetosome) compositions biosynthesized by magnetotactic bacteria (MTB), the magnetic properties of magnetite magnetosomes have been extensively studied using widely available cultures, while those of greigite magnetosomes remain poorly known. Here we have collected uncultivated magnetite- and greigite-producing MTB to determine their magnetic coercivity distribution and ferromagnetic resonance (FMR) spectra and to assess the MTB-associated iron flux. We find that compared with magnetite-producing MTB cultures, FMR spectra of uncultivated MTB are characterized by a wider empirical parameter range, thus complicating the use of FMR for fossilized magnetosome (magnetofossil) detection. Furthermore, in stark contrast to putative Neogene greigite magnetofossil records, the coercivity distributions for greigite-producing MTB are fundamentally left-skewed with a lower median. Lastly, a comparison between the MTB-associated iron flux in the investigated estuary and the pyritic-Fe flux in the Black Sea suggests MTB play an important, but heretofore overlooked role in euxinic marine system iron cycle.",

author = "Chen, \{A P\} and Berounsky, \{V M\} and Chan, \{M K\} and Blackford, \{M G\} and C Cady and Moskowitz, \{B M\} and P Kraal and Lima, \{E A\} and Kopp, \{R E\} and Lumpkin, \{G R\} and Weiss, \{B P\} and P Hesse and Vella, \{N G F\}",

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T1 - Magnetic properties of uncultivated magnetotactic bacteria and their contribution to a stratified estuary iron cycle

AU - Chen, A P

AU - Berounsky, V M

AU - Chan, M K

AU - Blackford, M G

AU - Cady, C

AU - Moskowitz, B M

AU - Kraal, P

AU - Lima, E A

AU - Kopp, R E

AU - Lumpkin, G R

AU - Weiss, B P

AU - Hesse, P

AU - Vella, N G F

PY - 2014

Y1 - 2014

N2 - Of the two nanocrystal (magnetosome) compositions biosynthesized by magnetotactic bacteria (MTB), the magnetic properties of magnetite magnetosomes have been extensively studied using widely available cultures, while those of greigite magnetosomes remain poorly known. Here we have collected uncultivated magnetite- and greigite-producing MTB to determine their magnetic coercivity distribution and ferromagnetic resonance (FMR) spectra and to assess the MTB-associated iron flux. We find that compared with magnetite-producing MTB cultures, FMR spectra of uncultivated MTB are characterized by a wider empirical parameter range, thus complicating the use of FMR for fossilized magnetosome (magnetofossil) detection. Furthermore, in stark contrast to putative Neogene greigite magnetofossil records, the coercivity distributions for greigite-producing MTB are fundamentally left-skewed with a lower median. Lastly, a comparison between the MTB-associated iron flux in the investigated estuary and the pyritic-Fe flux in the Black Sea suggests MTB play an important, but heretofore overlooked role in euxinic marine system iron cycle.

AB - Of the two nanocrystal (magnetosome) compositions biosynthesized by magnetotactic bacteria (MTB), the magnetic properties of magnetite magnetosomes have been extensively studied using widely available cultures, while those of greigite magnetosomes remain poorly known. Here we have collected uncultivated magnetite- and greigite-producing MTB to determine their magnetic coercivity distribution and ferromagnetic resonance (FMR) spectra and to assess the MTB-associated iron flux. We find that compared with magnetite-producing MTB cultures, FMR spectra of uncultivated MTB are characterized by a wider empirical parameter range, thus complicating the use of FMR for fossilized magnetosome (magnetofossil) detection. Furthermore, in stark contrast to putative Neogene greigite magnetofossil records, the coercivity distributions for greigite-producing MTB are fundamentally left-skewed with a lower median. Lastly, a comparison between the MTB-associated iron flux in the investigated estuary and the pyritic-Fe flux in the Black Sea suggests MTB play an important, but heretofore overlooked role in euxinic marine system iron cycle.

U2 - 10.1038/ncomms5797

DO - 10.1038/ncomms5797

M3 - Article

C2 - 25175931

SN - 2041-1723

VL - 5

JO - Nature Communications [E]

JF - Nature Communications [E]

M1 - 4797

ER -

Magnetic properties of uncultivated magnetotactic bacteria and their contribution to a stratified estuary iron cycle

Abstract

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