Localization of Protein Aggregation in Escherichia coli Is Governed by Diffusion and Nucleoid Macromolecular Crowding Effect

Coquel, Anne-Sophie; Jacob, Jean-Pascal; Primet, Maël; Démarez, Alice; Dimiccoli, Mariella; Julou, Thomas; Moisan, Lionel; Lindner, Ariel B.; Berry, Hugues

doi:10.1371/journal.pcbi.1003038

Cited by 122 publications

(165 citation statements)

References 66 publications

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“…Restriction of aggregates to the pole was also observed during treatment with substances disrupting the protein motive force, suggesting an energy independent process of aggregation [20]. Energy-independent polar localization was also confirmed by others [30] but also convincing opposite results were obtained [15]. Thus, it is not absolutely clear if active ATP-dependent transport of smaller particles is required or if the fluidizing properties of active metabolism are responsible for the polar preference of protein aggregates [16].…”

Section: Cellular Formation Of Ibsmentioning

confidence: 80%

“…There are claims that transport of aggregates to the poles is energy-driven as studies on reassembly of pressure dissociated IBs revealed that confinement to the pole is caused by the presence of the nucleoid but reassembly of smaller aggregates into large IBs does not occur in energy and nutrient depleted cells [16]. However, there are also reports stating that exclusion of aggregates from mid-cell to the pole is energy-free, and simply results from nucleoid exclusion [17,20,[28][29][30]. Restriction of aggregates to the pole was also observed during treatment with substances disrupting the protein motive force, suggesting an energy independent process of aggregation [20].…”

Section: Cellular Formation Of Ibsmentioning

confidence: 99%

“…Thus, it is not absolutely clear if active ATP-dependent transport of smaller particles is required or if the fluidizing properties of active metabolism are responsible for the polar preference of protein aggregates [16]. IBs and aggregation foci are not only found at the polar sites but also in mid-cells presumably at the place of future septation sites [20,30,31]. The major disaggregating chaperones (DnaK, ClpB) also co-localize at the poles [20] and are required for disaggregation of polar aggregates [15].…”

Section: Cellular Formation Of Ibsmentioning

confidence: 99%

See 2 more Smart Citations

Bacterial Inclusion Bodies: Discovering Their Better Half

Rinas

García‐Fruitós

Corchero

et al. 2017

Trends in Biochemical Sciences

141

123

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Bacterial inclusion bodies are functional, non-toxic amyloids occurring in recombinant bacteria that show analogies with secretory granules of the mammalian endocrine system. The scientific interest in these mesoscale protein aggregates has been historically masked by their status as a hurdle in recombinant protein production.However, insights into their molecular organization and the progressive understanding on how the cell handles the quality of recombinant polypeptides have stimulated the interest on inclusion bodies and opened ways for their usability in diverse technological fields. The engineering and tailoring of inclusion bodies as functional protein particles for materials science and biomedicine is a good example of how formerly undesired bacterial by-products can be re-discovered as promising functional materials for a broad spectrum of applications.-2 - BACKGROUND

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Section: Cellular Formation Of Ibsmentioning

confidence: 80%

Section: Cellular Formation Of Ibsmentioning

confidence: 99%

Section: Cellular Formation Of Ibsmentioning

confidence: 99%

See 1 more Smart Citation

Bacterial Inclusion Bodies: Discovering Their Better Half

Rinas

García‐Fruitós

Corchero

et al. 2017

Trends in Biochemical Sciences

141

123

View full text Add to dashboard Cite

show abstract

“…Computer simulations are often integrated with experiments performed in vivo to provide a microscopic interpretation of cellular phenomena (Hihara et al 2012;Coquel et al 2013;Di Rienzo et al 2014;Earnest et al 2017). Although powerful to predict macromolecule behavior, this technique, defined as the Bcomputational microscope^by Schulten (Lee et al 2009), has some limitations (Takada 2012;Piana et al 2014;Ivani et al 2016;Song et al 2017;Wang et al 2017a).…”

Section: Introductionmentioning

confidence: 99%

Molecular simulations of cellular processes

Trovato

Fumagalli

2017

Biophys Rev

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It is, nowadays, possible to simulate biological processes in conditions that mimic the different cellular compartments. Several groups have performed these calculations using molecular models that vary in performance and accuracy. In many cases, the atomistic degrees of freedom have been eliminated, sacrificing both structural complexity and chemical specificity to be able to explore slow processes. In this review, we will discuss the insights gained from computer simulations on macromolecule diffusion, nuclear body formation, and processes involving the genetic material inside cell-mimicking spaces. We will also discuss the challenges to generate new models suitable for the simulations of biological processes on a cell scale and for cellcycle-long times, including non-equilibrium events such as the co-translational folding, misfolding, and aggregation of proteins. A prominent role will be played by the wise choice of the structural simplifications and, simultaneously, of a relatively complex energetic description. These challenging tasks will rely on the integration of experimental and computational methods, achieved through the application of efficient algorithms.

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“…Experimental studies of subcellular localization of RNAs and proteins have induced the development of spatiotemporal models of gene expression. A few available models are focused on protein aggregation and nucleoid occlusion [19][20][21]. Protein localization near the transcription region was described as a consequence of diffusion within and exchange between the condensed chromosomal DNA and an extrachromosomal area [9,22].…”

Section: Introductionmentioning

confidence: 99%

Localized mRNA translation and protein association

Zhdanov¹

2014

Open Physics

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Abstract:Recent direct observations of localization of mRNAs and proteins both in prokaryotic and eukaryotic cells can be related to slowdown of diffusion of these species due to macromolecular crowding and their ability to aggregate and form immobile or slowly mobile complexes. Here, a generic kinetic model describing both these factors is presented and comprehensively analyzed. Although the model is non-linear, an accurate self-consistent analytical solution of the corresponding reaction-diffusion equation has been constructed, the types of localized protein distributions have been explicitly shown, and the predicted kinetic regimes of gene expression have been classified.

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Localization of Protein Aggregation in Escherichia coli Is Governed by Diffusion and Nucleoid Macromolecular Crowding Effect

Cited by 122 publications

References 66 publications

Bacterial Inclusion Bodies: Discovering Their Better Half

Bacterial Inclusion Bodies: Discovering Their Better Half

Molecular simulations of cellular processes

Localized mRNA translation and protein association

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