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| + | <h1>Part Improvement</h1> |
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| + | <h2>Background</h2> |
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| + | <p style="margin-bottom: 1.5em">Magnetosomes, an organelle encapsulating magnetic iron crystal, can be applied in many aspects. One of these applications is to construct a more efficient microbial fuel cell (MFC). MFC is a device which uses electrons produced by microorganism to generate electricity. If we genetically modify the bacteria <i>Azotobacter vinelandii</i> to have magnetosomes, magnetosomes inside them would be attracted towards the electrodes by magnetic force and in the process, bringing the whole bacteria along with it. As a result, the physical distance between the bacteria and electrodes will be decreased, thus an increase in the efficiency of the MFC as the diffusion rate for the electron to the electrode can be greatly increased.</p> |
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− | </style> | + | <p style="margin-bottom: 1.5em">Additionally, in the review of the previous iGEM teams, the idea of constructing an MFC has been popular. For example, the iGEM 2013 Bielefeld-Germany team also constructed an MFC. After a brief study of their project, we understood that one of their components is the oprF gene (<a href="parts.igem.org/Part:BBa_K1172501">K1172501</a>). The team has claimed that oprF, an outer membrane porin, could increase the efficiency of MFC by allowing electron shuttle-mediated extracellular electron transfer from bacteria to electrodes. </p> |
− | <center><div style="text-align:justify; text-justify:inter-ideograph; width:1000px"> | + | <br> |
| + | <h2>Investigation on K1172501</h2> |
| + | <p style="margin-bottom: 1.5em">However, after studying carefully, we found that the translated sequence of <a href="parts.igem.org/Part:BBa_K1172501">K1172501</a> contains premature stop codons. After translation, the sequence of <a href="parts.igem.org/Part:BBa_K1172501">K1172501</a> provided by the Bielefeld-Germany team will not be able to translate into an oprF porin protein. As the DNA sequence of <a href="parts.igem.org/Part:BBa_K1172501">K1172501</a> is greatly different from oprF DNA sequence from <i>Pseudomonas fluorescens</i>, the bacteria Germany team claimed to obtain oprF gene sequence from.</p></font> |
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| + | <h2>OprF in <i>Azotobacter vinelandii</i></h2> |
| + | <p style="margin-bottom: 1.5em">We found that OprF exists on the outer membrane of <i>A. vinelandii</i>, the bacteria we have been working on. Therefore we chose it to provide an alternative OprF. The sequence provided by <i>A. vinelandii</i> can be completely translated to form OprF with no stop codon appearing in the gene except in the last residue. Here we provide the biobrick, <a href="parts.igem.org/Part:BBa_K1648045">K1648045</a> and we are planning to provide <a href="parts.igem.org/Part:BBa_K1648047">K1648047</a> for insertion with different promoters.</p> |
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| + | <center><img src="https://static.igem.org/mediawiki/2015/3/31/Cuhk_partimprovementgenephoto3.jpg"></center> |
| + | <p style="margin-bottom: 1.2em; font-size:12px"><b>Figure 1:</b> The photo of 1% agarose gel electrophoresis. L: DNA ladder. Lane 1: PCR product of oprF encoding from <i>Azotobacter vinelandii</i> strain DJ genome.</p> |
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| + | <center><img src="https://static.igem.org/mediawiki/2015/5/5b/Cuhk_partimprovementgenephoto4.jpg"></center> |
| + | <p style="margin-bottom: 1.2em; font-size:12px"><b>Figure 2:</b> Checking of recombinant plasmid using double digestion. L: DNA ladder. Lane 1-3: Recombination Template for pSB1C3-oprF (<a href="parts.igem.org/Part:BBa_K1648045">K1648045</a>) with double digestion cut at EcoRI and PstI sites; with single digestion at PstI site; without digestion.</p> |
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− | <h1>Magnetosome - Nanostructure with Great Application Potentials</h1> | + | <br> |
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− | <div class="photoRight"> | + | <h2>Mutated oprF with Higher Efficiency</h2> |
− | <img src = "https://static.igem.org/mediawiki/2015/2/25/CUHK_Project_The_Magnetosome.jpg" height ="200px" style="margin:-30px 0px 0px 20px" align="right">
| + | <p style="margin-bottom: 1.5em">Furthermore, to construct a more efficient MFC, a mutated OprF with 5-point mutations is utilized. According to a paper concerning the factors affecting the conformation of OprF, we found that mutations on all 4 Cys to Ser residues, and Lys to Gly residues at 189<sup>th</sup> position (K189G; C201S; C210S; C216S; C230S) of <i>A. vinelandii</i> oprF would have higher probability in open-channel conformation 5 times more than WT oprF [2]. With the introduction of this mutated OprF into the bacteria, it is expected that the electron carrier diffusion into or out of the bacteria, as well as the efficiency of MFC, would be increased by 5 fold. Knowing that <i>E. coli</i> is capable to form porin using plasmid DNA [1], we used it to carry out the investigation on the oprF efficiency compare to <a href="parts.igem.org/Part:BBa_K1172501">K1172501</a>, oprF from <i>A. vinelandii</i> and mutated OprF (<a href="parts.igem.org/Part:BBa_K1648046">K1648046</a>).</p> |
− | <p align="right"> Figure 1: Magnetosome </p>
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− | </div> | + | |
− | <p style="margin-bottom: 1.5em">Magnetosome is a kind of rare intracellular membrane-bound structure in a specific type of prokaryotes, of nano-size ranging about 35 - 120 nm. They comprise of a magnetic mineral crystal encapsulated by a lipid bilayer about 3 – 4 nm thick (Figure 1) [1], which might be utilized in various applications involving magnetic field. </p> | + | |
− | <p style="margin-bottom: 1.5em">
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− | The magnetosome membrane is highly significant for its biogenesis as it creates an isolated environment within the cell crucial for mineral crystal nucleation and growth [2]. These inorganic crystals are magnetic in nature (hence its name), which compose of either magnetite (Fe<sub>3</sub>O<sub>4</sub>) or greigite (Fe<sub>3</sub>S<sub>4</sub>). The magnetosomes usually arrange in one or multiple chains along the cell axis. Different varieties of crystal morphologies such as cubo-octahedral, elongated hexagonal prismatic, and bullet-shaped morphologies were discovered in different magnetotactic bacteria [1].</p>
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| + | <h2>Characterization of Different oprF</h2> |
| + | <p style="margin-bottom: 1.5em">For comparison, identical promoter, J13002 (a constitutive promoter), was added before the gene in pSB1C3 for constitutive expression of different oprF in bacteria. There are <a href="parts.igem.org/Part:BBa_K1648048">K1648048</a> for oprF from <i>A. vinelandii</i>, <a href="parts.igem.org/Part:BBa_K1648049">K1648049</a> for mutated oprF from <i>A. vinelandii</i> and <a href="parts.igem.org/Part:BBa_K1648050">K1648050</a> for <a href="parts.igem.org/Part:BBa_K1172501">K1172501</a> from Germany iGEM team.</p> |
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− | <h1>Magnetotactic Bacteria - The Magnetosome Producer </h1>
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− | <img src = "https://static.igem.org/mediawiki/2015/a/a8/Magnetospirillum.jpg" height ="200px" style="margin:0px 20px 0px 0px" align="left">
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− | <p align="left" padding="10">Figure 2: Micrograph of a Magnetotactic Bacteria, <i>Magnetospirillum gryphiswaldense</i> (image from Departamento de Inmunología, Microbiología y Parasitología, University of the Basque Country) </p>
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− | <p style="margin-bottom: 1.5em">Magnetosomes are organelles synthesized by magnetotactic bacteria for its movement along magnetic field. These magnetotactic bacteria are mobile, aquatic, gram-negative prokaryotes [3] with an array of cellular morphologies, including coccoid, rod-shaped, vibrioid, helical or even multi-cellular. Some of them are more extensively studied, including <i>Magnetospirillum magnetotacticum</i> and <i>Magnetospirillum gryphiswaldense</i>. They are found optimally grown at the oxic-anoxic interface in aquatic habitats, and in fact grow less happily under atmospheric oxygen concentration.</p>
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− | <p style="margin-bottom: 1.5em">Magnetosomes form a chain and are aligned along the axis within the bacteria. With these magnetosomes inside them, they are able to align passively to the earth’s magnetic field so as to swim along geomagnetic field lines. This behaviour is called magnetotaxis and is beneficial to their survival by aiding them to reach regions of optimal oxygen concentrations at minimal energy cost [4]. </p> | + | <center><img src="https://static.igem.org/mediawiki/2015/c/c6/Cuhk_partimprovementgenephoto2.jpg"></center> |
| + | <p style="margin-bottom: 1.2em; font-size:12px"><b>Figure 3:</b> Checking of recombinant plasmid using double digestion. L: DNA ladder. Lane 1-3: Recombination Template for J13002-oprF (<a href="parts.igem.org/Part:BBa_K1648048">K1648048</a>) with double digestion cut at EcoRI and PstI sites; with single digestion at PstI site; without digestion.</p> |
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− | <a name="azotobacter"></a> | + | <center><img src="https://static.igem.org/mediawiki/2015/1/11/Cuhk_partimprovementgenephoto1.jpg"></center> |
− | <h1> <i>Azotobacter vinelandii</i> - What and Why? </h1> | + | <p style="margin-bottom: 1.2em; font-size:12px"><b>Figure 4:</b> Checking of recombinant plasmid using double digestion. L: DNA ladder. Lane 1-2: Recombination Template for R0040-oprF* (<a href="parts.igem.org/Part:BBa_K1648049">K1648049</a>) with double digestion cut at EcoRI and PstI sites; with single digestion at PstI site. |
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| + | <h2>Experiment Set-up and Ongoing Test</h2> |
| + | <p style="margin-bottom: 1.5em">In the experiment, we will use the colour change of methylene blue as an indicator to compare the efficiency between the transformed bacteria with different oprF plasmids and wild type bacteria. The desired function of the oprF porin protein for this experiment is to allow the diffusion of (reduced) electron carriers in and out of the periplasmic membrane from the outside of the cell. As the electron carrier (e.g. NAD<sup>+</sup>) picks up an electron in the periplasmic space (i.e. being reduced to NADH) and diffuse out of the cell through the porin protein, the electron on the NADH will transfer to methylene blue (the mediator solution outside the cell). When the methylene blue is reduced to form leucomethylene blue, it turns from blue to colourless. Hence, the rate of transmission of electron carrier is calculated by the rate of reduction of methylene blue. The experiment is planned to carry out soon. The plasmids will also be transformed into <i>A. vinelandii</i> for the construction of our MFC.</p></font> |
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− | <p style="margin-bottom: 1.5em">Although magnetotactic bacteria produces magnetosomes, these bacteria are notorious for the difficulty to cultivate owing to their micro-aerophilic nature. Elaborate growth techniques are required, and they are difficult to grow on the surface of agar plates, introducing problems in mutant screening [5]. </p> | + | <center><img src="https://static.igem.org/mediawiki/2015/a/a6/Cuhk_solutionphoto.jpg" width="400px"></center> |
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− | <p style="margin-bottom: 1.5em">The lack of effective methods of DNA transfer in these microorganisms is a challenge too. Luckily, the situation is improving due to better technologies recently and some of the genes from <i>M. magnetotacticum</i> were confirmed functionally expressed in <i>Escherichia coli</i>, a common lab bacteria strain. This shows that the transcriptional and translational elements of the two microorganisms are compatible. With such good news, a number of previous iGEM teams including Kyoto-2014, OCU-China-2013, Washington-2011 and UNIK_Copenhagen-2013 have been working with transferring the magnetosome-related genes to <i>E. coli</i>. Some exciting results about the formation of magnetosome membrane in <i>E. coli</i> (by the Kyoto-2014 team) has been reported, however, never the whole magnetosome.</p>
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− | <div class="photoRight"> | + | <h3>References</h3> |
− | <img src = "https://static.igem.org/mediawiki/2015/a/ac/CUHK_Project_Azotobacter_vinelandii.jpg" height ="250px" style="margin:0px 0px 0px 20px" align="right">
| + | <p style="margin-bottom: 1.5em">1. Sugawara, Etsuko, Keiji Nagano, and Hiroshi Nikaido. "Factors affecting the folding of Pseudomonas aeruginosa OprFporin into the one-domain open conformer." MBio 1.4 (2010): e00228-10.</p></font> |
− | <p align="right"> Figure 3: Azotobacter vinelandii </p>
| + | <p style="margin-bottom: 1.5em">2. Yong, Yang‐Chun, et al. "Enhancement of extracellular electron transfer and bioelectricity output by synthetic porin." Biotechnology and bioengineering110.2 (2013): 408-416.</p></font> |
− | </div> | + | |
− | <p style="margin-bottom: 1.5em">We wonder why magnetosomes seem so hard to be formed in <i>E. coli</i>. And then, we come up with a hypothesis - the formation of magnetosome requires <b>a micro-aerobic or anaerobic environment</b> as the magnetotatic bacteria are all living micro-aerobically. </p> | + | |
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− | <p style="margin-bottom: 1.5em">Therefore, we chose a new bacteria to work on our magnetosome project - <b><i>Azotobacter vinelandii</i></b>. </p>
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− | <p style="margin-bottom: 1.5em"><i>A. vinelandii</i> is gram-negative diazotroph (nitrogen-fixing microorganism). It is a soil bacterium related to the <i>Pseudomonas</i> genus that fixes nitrogen under aerobic conditions while having enzymatic mechanisms protecting <b>its oxygen-sensitive nitrogenase</b> from oxidative damage. This finding shows that <i>A. vinelandii</i> could be an excellent host for the production and characterization of oxygen-sensitive proteins or organelles in our case [6]. </p>
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− | <p style="margin-bottom: 1.5em">With the biggest advantage of using <i>Azotobacter</i> that it being <b>an aerobe providing an intracellular anaerobic environment</b>, we can grow it easily in normal lab conditions without expensive equipments, while fulfilling the formation criteria for magnetosome. Besides, <b>most parts in registry are compatible in <i>Azotobacter</i></b> and it is of <b>safety level group 1</b>. One more important thing is that it can conduct <b>homologous recombination for stable genome integration</b>, which is a critical process we need in our project. </p><br> | + | |
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− | <h1>Magnetosome Island Genes - Everything Required for Magnetosome Formation</h1>
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− | <p>For the synthesis of magnetosome, it is strictly controlled by a group of genes clustered in the magnetosome island (MAI). MAI comprise of four operons, namely mms6, mamGFDC, mamAB and mamXY operons [5]. The actual size and organisation of the MAI might differ between species, but the operons seems to be highly conserved within the MAI [2]. </p>
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− | <p>Through genetic mutants, researches has shown with the deletion of mamAB operon would lead to non-magnetic phenotype, showing the importance of <b>mamAB operon as minimal requirement for magnetosome formation</b> and other important functions such as membrane invagination, iron transport, and magnetite biomineralization [7]. </p>
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− | <p>In the bacteria <i>Magnetospirillum gryphiswaldense</i>, the mamAB operon consists of 17 genes, namely mamH, -I, -E, -J, -K, -L, -M, -N, -O, -P, -A, -Q, -R, -B, -S, -T, and -U. </p>
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− | <h1>Biogenesis of Magnetosome</h1>
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− | <p>Now let's look at the biosynthesis of magnetosomes as a multistep complex process. </p>
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− | <div class="photoRight">
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− | <img src = "https://static.igem.org/mediawiki/2015/c/c1/CUHK_Magnetosome_formation.jpg" width="500px" style="margin:-30px 0px 0px 20px" align="right">
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− | <p align="right"> Figure 4: Overview of Magnetosome Formation</p>
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− | </div>
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− | <p>First, the inner membrane of the bacteria swells outwards for <b>vesicle invaginations</b>. The following step is to <b>sort magnetosome proteins to the mangetosome membrane (MM)</b> to perform specific functions in the transport and accumulation of iron.</p>
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− | <p>After protein sorting to the MM, the next step is iron uptake.
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− | The need to import iron for magnetite production makes MTB differs from other bio-mineralizers. Iron transporters in the MM
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− | would pump Fe<sup>2+</sup>/Fe<sup>3+</sup> into the vesicle. </p>
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− | | + | |
− | <p>Additionally, MamM, MamB, and MamH were suggested as additional iron transporters for magnetite biomineralization. As the concentration of iron ions increases inside the vesicle, biomineralization occurs [8]. </p>
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− | <p>The process of magnetite biomineralization is tightly regulated through specific conditions such as: pH and the concentration of iron within the vesicle. It was also shown that such formation only occurs below a threshold value of 10 mbar of atmospheric pressure, and is inhibited at higher oxygen concentrations. <b>In other words, the size of particles is limited by atmospheric pressure and oxygen concentration.</b> It is found that at 0.25 mbar, magnetite biomineralization can produce particles up to 42 nm. As the condition rise to 10 mbar, the particle size dropped to about 20 nm. [9] As the biomineralization of the magnetosome is reported to be highly affected by oxygen, we propose an educated guess that <b>magnetosome will have a higher probability to be successfully formed in our bacteria <i>Azotobacter</i></b> rather than <i>E. coli</i> due to its <b>intracellular microaerobic</b> characteristic. </p>
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− | <h2>References</h2>
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− | <p>
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− | 1. BAZYLINSKI, Dennis A.; FRANKEL, Richard B. Magnetosome formation in prokaryotes. <i>Nature Reviews Microbiology</i>, 2004, 2.3: 217-230.
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− | </p> | + | |
− | <p>
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− | 2. NUDELMAN, Hila; ZARIVACH, Raz. Structure prediction of magnetosome-associated proteins. <i>Frontiers in microbiology</i>, 2014, 5.
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− | </p>
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− | <p>
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− | 3. BLAKEMORE, Richard. Magnetotactic bacteria. <i>Science</i>, 1975, 190.4212: 377-379.
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− | </p>
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− | <p>
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− | 4. FRANKEL, Richard B.; BAZYLINSKI, Dennis A. Magnetosomes and magneto-aerotaxis. 2009.
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− | </p>
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− | <p>
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− | 5. YAN, Lei, et al. Magnetotactic bacteria, magnetosomes and their application. <i>Microbiological research</i>, 2012, 167.9: 507-519.
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− | </p>
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− | <p>
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− | 6. MAIER, R. J.; MOSHIRI, F. Role of the Azotobacter vinelandiinitrogenase-protective shethna protein in preventing oxygen-mediated cell death. <i>Journal of bacteriology</i>, 2000, 182.13: 3854-3857.
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− | </p>
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− | <p>
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− | 7. LOHßE, Anna, et al. Functional analysis of the magnetosome island in Magnetospirillum gryphiswaldense: the mamAB operon is sufficient for magnetite biomineralization. <i>PLoS One</i>, 2011, 6.10: e25561.
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− | </p>
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− | <p>
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− | 8. LOHßE, Anna, et al. Genetic dissection of the mamAB and mms6 operons reveals a gene set essential for magnetosome biogenesis in Magnetospirillum gryphiswaldense. <i>Journal of bacteriology</i>, 2014, 196.14: 2658-2669.
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− | </p>
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− | <p>
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− | 9. ODENBACH, Stefan (ed.). Colloidal Magnetic Fluids: Basics, Development and Application of Ferrofluids. <i>Springer</i>, 2009.
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− | </p>
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