Coarse-grained simulations of bacterial cell wall growth reveal that local coordination alone can be sufficient to maintain rod shape

Nguyen, Lam T.; Gumbart, James C.; Beeby, Morgan; Jensen, Grant J.

doi:10.1073/pnas.1504281112

Cited by 50 publications

(89 citation statements)

References 91 publications

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“…Here the angle between neighboring stem peptides that belong to a single glycan is assumed to be 90°. Therefore, every other stem peptide is in plane with glycan sheet (Nguyen et al, 2015, Huang et al, 2008). The role of effective glycan persistence length on engulfment is negligible (see Figure 4—figure supplement 3).…”

Section: Resultsmentioning

confidence: 99%

“…( B ) Simulations for different values of effective peptide

k_{pep}

and glycan

k_{gly}

spring constants are compared with experimentally measured forespore surface area, volume and engulfment using mutual

χ^{2}

statistics (Equation 2). Arrows point to effective literature

k_{pep}

and

k_{gly}

(Nguyen et al, 2015). Dark blue region corresponds to simulation parameters that best fit experimental data (Figure 4—figure supplement 4, Video 3).…”

Section: Resultsmentioning

confidence: 99%

See 1 more Smart Citation

Cell-wall remodeling drives engulfment during Bacillus subtilis sporulation

Ojkic

López‐Garrido

Pogliano

et al. 2016

eLife

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When starved, the Gram-positive bacterium Bacillus subtilis forms durable spores for survival. Sporulation initiates with an asymmetric cell division, creating a large mother cell and a small forespore. Subsequently, the mother cell membrane engulfs the forespore in a phagocytosis-like process. However, the force generation mechanism for forward membrane movement remains unknown. Here, we show that membrane migration is driven by cell wall remodeling at the leading edge of the engulfing membrane, with peptidoglycan synthesis and degradation mediated by penicillin binding proteins in the forespore and a cell wall degradation protein complex in the mother cell. We propose a simple model for engulfment in which the junction between the septum and the lateral cell wall moves around the forespore by a mechanism resembling the ‘template model’. Hence, we establish a biophysical mechanism for the creation of a force for engulfment based on the coordination between cell wall synthesis and degradation.DOI: http://dx.doi.org/10.7554/eLife.18657.001

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Section: Resultsmentioning

confidence: 99%

“…( B ) Simulations for different values of effective peptide

k_{pep}

and glycan

k_{gly}

spring constants are compared with experimentally measured forespore surface area, volume and engulfment using mutual

χ^{2}

statistics (Equation 2). Arrows point to effective literature

k_{pep}

and

k_{gly}

(Nguyen et al, 2015). Dark blue region corresponds to simulation parameters that best fit experimental data (Figure 4—figure supplement 4, Video 3).…”

Section: Resultsmentioning

confidence: 99%

Cell-wall remodeling drives engulfment during Bacillus subtilis sporulation

Ojkic

López‐Garrido

Pogliano

et al. 2016

eLife

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“…Although this model is able to predict conditions for rod-shaped growth, it fails to predict the MreB-dependent chiral organization of the glycan strands. Other recent attempts to model cell growth do not use chiral polymers, but instead hypothesize that MreB's role is to colocalize cell wall growth factors randomly on the cell surface (14). This work also fails to predict the cell wall chirality and invokes a global geometric sensing of the cell's long-axis direction, either by the MreB or the cell wall synthesizing enzymes, without an explanation of how a nonpolymeric molecule might achieve this.…”

Section: Introductionmentioning

confidence: 83%

MreB Orientation Correlates with Cell Diameter in Escherichia coli

Ouzounov

Nguyen

Bratton

et al. 2016

Biophysical Journal

117

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Bacteria have remarkably robust cell shape control mechanisms. For example, cell diameter only varies by a few percent across a given population. The bacterial actin homolog, MreB, is necessary for establishment and maintenance of rod shape although the detailed properties of MreB that are important for shape control remained unknown. In this study, we perturb MreB in two ways: by treating cells with the polymerization-inhibiting drug A22 and by creating point mutants in mreB. These perturbations modify the steady-state diameter of cells over a wide range, from 790 5 30 nm to 1700 5 20 nm. To determine which properties of MreB are important for diameter control, we correlated structural characteristics of fluorescently tagged MreB polymers with cell diameter by simultaneously analyzing three-dimensional images of MreB and cell shape. Our results indicate that the helical pitch angle of MreB inversely correlates with the cell diameter of Escherichia coli. Other correlations between MreB and cell diameter are not found to be significant. These results demonstrate that the physical properties of MreB filaments are important for shape control and support a model in which MreB organizes the cell wall growth machinery to produce a chiral cell wall structure and dictate cell diameter.

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“…Generally, the murein sacculus (peptidoglycan layer) is the essential determinant of the shape of E. coli which has to be preserved during cell divisions. Cell growth requires that the sacculus be elongated by a complex remodeling process which requires the coordinated action of transglycosylases, transpeptidases and endopepidases [13]. Obviously, the growth occurred at multiple domains of the cylindrical part of E. coli [20].…”

Section: Discussionmentioning

confidence: 99%

“…Thus, besides the initial attachment of the E. coli to a cicada wing-like surface an ongoing cell division process will induce additional strain for cell wall rupture. For every division of the E. coli the elongation of the rod structure is necessary [13]. This elongation process will obviously induce additional strain on the bacterial cell wall when the living cell is somehow fixed by the tips of the nano-pillars.…”

Section: Introductionmentioning

confidence: 99%

Bacterial cell division is involved in the damage of gram-negative bacteria on a nano-pillar titanium surface

Köller

Ziegler

Sengstock

et al. 2018

Biomed. Phys. Eng. Express

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Bacterial cell division is involved in the damage of gram-negative bacteria on a nano-pillar titanium surface AbstractThe role of bacterial cell division on the damage of adherent bacteria to titanium (Ti) nano-pillar cicada wing like surface was analyzed. Therefore nano-pillar Ti thin films were fabricated by glancing angle sputter deposition (GLAD) on silicon substrates. Gram-negative E. coli bacteria were allowed to adhere and to proliferate on these nanostructured samples for 3 h at 37°C either under optimal cell growth conditions (brain heart infusion medium, BHI) or limited growth conditions (RPMI1640 medium). The bacteria adhered to the samples in both media. Compared to BHI medium the growth of E. coli in RPMI1640 medium was significantly inhibited. Concomitantly, the ratio of dead/living adherent bacteria on the nano-pillar surface was significantly decreased after the incubation period in RPMI1640. In addition, when the bacterial proliferation was biochemically halted using DL-serinehydroxamate a comparable decrease in the ratio of dead/living adherent bacteria was also obtained in BHI medium. These results indicate that cell growth of adherent E. coli which is accompanied by cell elongations of the rod structure is involved in the damage induced by the titanium nano-pillar surface.

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Coarse-grained simulations of bacterial cell wall growth reveal that local coordination alone can be sufficient to maintain rod shape

Cited by 50 publications

References 91 publications

Cell-wall remodeling drives engulfment during Bacillus subtilis sporulation

Cell-wall remodeling drives engulfment during Bacillus subtilis sporulation

MreB Orientation Correlates with Cell Diameter in Escherichia coli

Bacterial cell division is involved in the damage of gram-negative bacteria on a nano-pillar titanium surface

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