An integrated approach to elucidate the interplay between iron uptake dynamics and magnetosome formation at the single-cell level in Magnetospirillum gryphiswaldense

Abstract

Iron is a crucial element integral to various fundamental biological molecular mechanisms, including magnetosome biogenesis in magnetotactic bacteria (MTB). Magnetosomes are formed through the internalization and biomineralization of iron into magnetite crystals. However, the interconnected mechanisms by which MTB uptake and regulate intracellular iron for magnetosome biomineralization remain poorly understood, particularly at the single-cell level. To gain insights we employed a holistic multiscale approach, i.e., from elemental iron species to bacterial populations, to elucidate the interplay between iron uptake dynamics and magnetosome formation in Magnetospirillum gryphiswaldense MSR-1 under near-native conditions. We combined a correlative microscopy approach integrating light and X-ray tomography with analytical techniques, such as flow cytometry and inductively coupled plasma spectroscopy, to evaluate the effects of iron and oxygen availability on cellular growth, magnetosome biogenesis, and intracellular iron pool in MSR-1. Our results revealed that increased iron availability under microaerobic conditions significantly promoted the formation of longer magnetosome chains and increased intracellular iron uptake, with a saturation point at 300 μM iron citrate. Beyond this threshold, additional iron did not further extend the magnetosome chain length or increase total intracellular iron levels. Moreover, our work reveals (i) a direct correlation between the labile Fe2+ pool size and magnetosome content, with higher intracellular iron concentrations correlating with increased magnetosome production, and (ii) the existence of an intracellular iron pool, distinct from magnetite, persisting during all stages of biomineralization. This study offers insights into iron dynamics in magnetosome biomineralization at a single-cell level, potentially enhancing the industrial biomanufacturing of magnetosomes.

Publication DOI: https://doi.org/10.1021/acsami.4c15975
Divisions: College of Engineering & Physical Sciences > Aston Institute of Materials Research (AIMR)
College of Engineering & Physical Sciences
College of Engineering & Physical Sciences > Energy and Bioproducts Research Institute (EBRI)
Aston University (General)
Funding Information: This work was supported by the Royal Society Research Grant RGS\\R1\\191377, BBSRC New Investigators Award Grant No. BB/V010603/1, and the Energy Research Accelerator (ERA) grant from Innovate UK (project No. 160052). The authors thank UKRI Research Engla
Additional Information: Copyright © 2024 The Authors. Published by American Chemical Society. This publication is licensed under CC-BY 4.0 (https://creativecommons.org/licenses/by/4.0/).
Uncontrolled Keywords: biomineralization,correlative microscopy,cryo-structured illumination microscopy,magnetic nanoparticles,magnetosomes,magnetotactic bacteria,soft X-ray tomography,General Materials Science
Publication ISSN: 1944-8252
Last Modified: 09 Dec 2024 17:42
Date Deposited: 12 Nov 2024 13:32
Full Text Link:
Related URLs: https://pubs.ac ... /acsami.4c15975 (Publisher URL)
http://www.scop ... tnerID=8YFLogxK (Scopus URL)
PURE Output Type: Article
Published Date: 2024-11-13
Published Online Date: 2024-10-31
Accepted Date: 2024-10-24
Authors: Maso-Martinez, Marta
Bond, Josh
Okolo, Chidinma A.
Jadhav, Archana C.
Harkiolaki, Maria
Topham, Paul D. (ORCID Profile 0000-0003-4152-6976)
Fernandez-Castane, Alfred (ORCID Profile 0000-0002-2572-7797)

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