Formation and positioning of the magnetosome chain in Magnetospirillum Magneticum AMB-1

Le Nagard, Lucas

January 2018

Magnetotactic bacteria are a group of prokaryotes that share the ability to align with external magnetic fields, due to the presence within their cytoplasm of one or several chains of nanometer-sized magnetic crystals called the magnetosomes. The orientation of the chain within the cell is critical for magnetotaxis, which allows these bacteria to swim along the geomagnetic field lines. To do so, the magnetic moment and thus the chain need to lie parallel to the swimming direction which, for elongated bacteria such as AMB-1, is roughly parallel to the long axis of the cell. In most studies, the alignment between the magnetic moment and the cell axis is taken for granted, however no precise measurement has been performed to confirm this. In this thesis, experiments performed to test this assumption are presented, and the results show that for most studied bacteria the alignment is not perfect. The effect on the orientation distributions is discussed and accounted for in the analysis performed to measure the magnetic moment of individual bacteria. A second project presented in this thesis is focused on the biomineralization process in AMB-1. Magnetotactic bacteria synthesize crystals characterized by a well-controlled morphology and a high chemical purity, which makes them interesting for biomedical applications. To study how these crystals are produced, we used scanning trans- mission X-ray microscopy, and preliminary results show that this tool is suitable for studying this complex process. The methods developed and improved during this MSc to perform these experiments are presented, and the first results show an evolution in the spectroscopy of the magnetosomes as they grow. / Thesis / Master of Science (MSc)

Biomagnetism

Magnetotaxis

Magnetosomes

Microscopy

Greigite et magnétite : les déterminants environnementaux et génétiques contrôlant la biominéralisation chez les bactéries magnétotactiques / Greigite and magnetite : environmental and genetic determinants controlling biomineralization in magnetotactic bacteria

Descamps, Elodie

12 February 2018

Les bactéries magnétotactiques représentent un groupe d’une grande diversité écologique et phylogénétique. Elles sont capables de biominéraliser des nanocristaux de magnétite [un oxyde de fer (Fe(II)Fe(III)2O4)] ou de greigite [un sulfure de fer (Fe(II)Fe(III)2S4)] dans leurs magnétosomes, organites alignés en chaînes permettant la navigation le long des lignes de champ magnétique terrestre. Jusqu'à récemment, seules des souches produisant de la magnétite étaient disponibles en culture pure, conduisant à des études sur les mécanismes de biominéralisation de cet oxyde de fer. En 2011, une nouvelle bactérie capable de former de la magnétite et de la greigite, Desulfamplus magnetovallimortis souche BW-1, a été cultivée avec succès en laboratoire. Dans cette thèse, nous proposons d'utiliser une approche intégrée et multidisciplinaire pour comprendre les mécanismes de biominéralisation de la greigite en utilisant comme modèle d’étude la souche BW-1. Nous avons donc cherché à déterminer les conditions environnementales et biologiques favorisant la formation de la magnétite et de la greigite. Ces travaux ont également conduit à la caractérisation physiologique et phylogénétique de BW-1. Puis, l’utilisation d’approches globales et ciblées de transcriptomique ont permis d'évaluer le taux d'expression des gènes impliqués dans la formation des magnétosomes (magnétite vs. greigite) dans diverses conditions de croissance. Une approche de protéomique a permis d’apporter des informations supplémentaires à cette étude. Ces résultats ont permis de progresser dans la compréhension fondamentale de la biominéralisation in vivo, en particulier pour des bactéries formant de la greigite. / Magnetotactic bacteria represent a phylogenetically and ecologically diverse group of prokaryotes able to biomineralize magnetic nanocrystals composed of magnetite [an iron oxide (Fe(II)Fe(III)2O4)] or greigite [an iron sulfide (Fe(II)Fe(III)2S4)] in their magnetosomes, a prokaryotic organelle whose cytoplasmic alignement in chain allows the cell to navigate along the Earth’s magnetic field lines. Until recently, only magnetite-producing strains were available in pure culture. Thus, only the magnetite biomineralization has been studied. In 2011, a new bacterium able to form both magnetite and greigite, Desulfamplus magnetovallimortis strain BW-1, was isolated from Death Valley, California and cultivated in pure culture. In this work, we propose to use an integrated and multidisciplinary approach to understand the mechanisms involved in greigite biomineralization in BW-1 strain. First, we determined the environmental and biological conditions in which magnetite and greigite are formed. This first part of my thesis also contributed to the physiologic and phylogenetic characterization of this bacterium. Secondly, we used global and targeted transcriptomic approaches to evaluate the transcription levels of genes putatively involved in magnetosomes formation (magnetite vs. greigite) under various growth conditions. A proteomic approach provided additional informations to this study.Results obtained during my thesis contribute to the understanding of in vivo biomineralization, particularly for greigite production in magnetotactic bacteria.

Bactéries magnétotactiques

Biominéralisation

Greigite

Magnétite

Organite procaryote

Magnétosome

Magnétotaxie

Magnetotactic bacteria

Biomineralization

Greigite

Magnetite

Prokaryotic organelle

Magnetosome

Magnetotaxis

579

Mixotrophic Magnetosome-Dependent Magnetoautotrophic Metabolism of Model Magnetototactic Bacterium Magnetospirillum magneticum AMB-1

Mumper, Eric Keith

20 June 2019

No description available.

Biogeochemistry

Geobiology

Geology

Microbiology

Mineralogy

Collective Behavior of Magneto-Aerotactic Bacteria: Experiments and Computational Modeling

Wijesinghe, Wijesinghe Mudiyanselage Hiran Shanaka

January 2021

No description available.

Physics

Biomechanics

Ecology

Materials Science

Microbiology

complex systems

collective behaviors

MTB

magnetotaxis

aerotaxis

magnetotactic bacteria

Magnetospirillum magneticum

hydrodynamics

lattice Boltzmann

LBM

LB

agent based

agent-based