Your search keyword '"Wolgemuth, Charles W."' showing total 6 results

1. Processivity of peptidoglycan synthesis provides a built-in mechanism for the robustness of straight-rod cell morphology

Author

Sliusarenko, Oleksii, Cabeen, Matthew T., Wolgemuth, Charles W., Jacobs-Wagner, Christine, and Emonet, Thierry

Subjects

Peptidoglycans -- Properties, Morphology -- Research, Plant cell walls -- Properties, Science and technology

Abstract

The propagation of cell shape across generations is remarkably robust in most bacteria. Even when deformations are acquired, growing cells progressively recover their original shape once the deforming factors are eliminated. For instance, straight-rod-shaped bacteria grow curved when confined to circular microchambers, but straighten in a growth-dependent fashion when released. Bacterial cell shape is maintained by the peptidoglycan (PG) cell wall, a giant macromolecule of glycan strands that are synthesized by processive enzymes and cross-linked by peptide chains. Changes in cell geometry require modifying the PG and therefore depend directly on the molecular-scale properties of PG structure and synthesis. Using a mathematical model we quantify the straightening of curved Caulobacter crescentus cells after disruption of the cell-curving crescentin structure. We observe that cells straighten at a rate that is about half (57%) the cell growth rate. Next we show that in the absence of other effects there exists a mathematical relationship between the rate of cell straightening and the processivity of PG synthesis--the number of subunits incorporated before termination of synthesis. From the measured rate of cell straightening this relationship predicts processivity values that are in good agreement with our estimates from published data. Finally, we consider the possible role of three other mechanisms in cell straightening. We conclude that regardless of the involvement of other factors, intrinsic properties of PG processivity provide a robust mechanism for cell straightening that is hardwired to the cell wall synthesis machinery. cell shape | cell wall | cell curvature | modeling doi/ 10.1073/pnas.1000737107

Published

2010

2. Z-ring force and cell shape during division in rod-like bacteria

Author

Lan, Ganhui, Wolgemuth, Charles W., and Sun, Sean X.

Subjects

Cell division -- Research, Bacteria -- Physiological aspects, Peptidoglycans -- Properties, Biosynthesis -- Research, Science and technology

Abstract

The life cycle of bacterial cells consists of repeated elongation, septum formation, and division. Before septum formation, a division ring called the Z-ring, which is made of a filamentous tubulin analog, FtsZ, is seen at the mid cell. Together with several other proteins, FtsZ is essential for cell division. Visualization of strains with GFP-labeled FtsZ shows that the Z-ring contracts before septum formation and pinches the cell into two equal halves. Thus, the Z-ring has been postulated to act as a force generator, although the magnitude of the contraction force is unknown. In this article, we develop a mathematical model to describe the process of growth and Z-ring contraction in rod-like bacteria. The elasticity and growth of the cell wall is incorporated in the model to predict the contraction speed, the cell shape, and the contraction force. With reasonable parameters, the model shows that a small force from the Z-ring (8 pN in Escherichia coli) is sufficient to accomplish division. bacterial cell division | FtsZ-ring | mathematical model | peptidoglycan synthesis

Published

2007

3. Bacterial swimming and oxygen transport near contact lines

Author

Tuval, Idan, Cisneros, Luis, Dombrowski, Christopher, Wolgemuth, Charles W., Charles W., Kessler, John O., and Goldstein, Raymond E.

Subjects

Bacteria, Aerobic -- Research, Science and technology

Abstract

Aerobic bacteria often live in thin fluid layers near solid-air-water contact lines, in which the biology of chemotaxis, metabolism, and cell-cell signaling is intimately connected to the physics of buoyancy, diffusion, and mixing. Using the geometry of a sessile drop, we demonstrate in suspensions of Bacillus subtilis the self-organized generation of a persistent hydrodynamic vortex that traps cells near the contact line. Arising from upward oxygentaxis and downward gravitational forcing, these dynamics are related to the Boycott effect in sedimentation and are explained quantitatively by a mathematical model consisting of oxygen diffusion and consumption, chemotaxis, and viscous fluid dynamics. The vortex is shown to advectively enhance uptake of oxygen into the suspension, and the wedge geometry leads to a singularity in the chemotactic dynamics near the contact line. bioconvection | chemotaxis | singularity | Bacillus subtilis

Published

2005

4. The heterogeneous motility of the Lyme disease spirochete in gelatin mimics dissemination through tissue.

Author

Harman, Michael W., Dunham-Ems, Star M., Caimano, Melissa J., Belperron, Alexia A., Bockenstedt, Linda K., Fu, Henry C., Radolf, Justin D., and Wolgemuth, Charles W.

Subjects

LYME disease, SPIROCHETES, GELATIN, BORRELIA burgdorferi, ARTHROPOD vectors, IXODES scapularis, MOTILITY of bacteria

Abstract

The Lyme disease spirochete Borrelia burgdorferi exists in nature in an enzootic cycle that involves the arthropod vector Ixodes scapularis and mammalian reservoirs. To disseminate within and between these hosts, spirochetes must migrate through complex, polymeric environments such as the basement membrane of the tick midgut and the dermis of the mammal. To date, most research on the motility of B. burgdorferi has been done in media that do not resemble the tissue milieus that B. burgdorferi encounter in vivo. Here we show that the motility of Borrelia in gelatin matrices in vitro resembles the pathogen's movements in the chronically infected mouse dermis imaged by intravital microscopy. More specifically, B. burgdorferi motility in mouse dermis and gelatin is heterogeneous, with the bacteria transitioning between at least three different motility states that depend on transient adhesions to the matrix. We also show that B. burgdorferi is able to penetrate matrices with pore sizes much smaller than the diameter of the bacterium. We find a complex relationship between the swimming behavior of B. burgdorferi and the rheological properties of the gelatin, which cannot be accounted for by recent theoretical predictions for microorganism swimming in gels. Our results also emphasize the importance of considering borrelial adhesion as a dynamic rather than a static process. [ABSTRACT FROM AUTHOR]

Published

2012

5. Processivity of peptidoglycan synthesis provides a built-in mechanism for the robustness of straight-rod cell morphology.

Author

SIiusarenko, Oleksii, Matthew T. Cabeen, Wolgemuth, Charles W., Jacobs-Wagner, Christine, and Emonet, Thierry

Subjects

PEPTIDOGLYCANS, CELL morphology, BACTERIA, PROTEIN synthesis, CYTOSKELETAL proteins, ESTIMATION theory, MATHEMATICAL models

Abstract

The propagation of cell shape across generations is remarkably robust in most bacteria. Even when deformations are acquired. growing cells progressively recover their original shape once the deforming factors are eliminated. For instance, straight-rod-shaped bacteria grow curved when confined to circular microchambers, but straighten in a growth-dependent fashion when released. Bacterial cell shape is maintained by the peptidoglycan (PG) cell wall, a giant macromolecule of glycan strands that are synthesized by processive enzymes and cross-linked by peptide chains. Changes in cell geometry require modifying the PG and therefore depend directly on the molecular-scale properties of PG structure and synthesis. Using a mathematical model we quantify the straightening of curved Cau!obacter crescentus cells after disruption of the cell-curving crescentin structure. We observe that cells straighten at a rate that is about half (57%) the cell growth rate. Next we show that in the absence of other effects there exists a mathematical relationship between the rate of cell straightening and the processivity of PG synthesis-the number of subunits incorporated before termination of synthesis. From the measured rate of cell straightening this relationship predicts processivity values that are in good agreement with our estimates from published data. Finally, we consider the possible role of three other mechanisms in cell straightening. We conclude that regardless of the involvement of other factors, intrinsic properties of PG processivity provide a robust mechanism for cell straightening that is hardwired to the cell wall synthesis machinery. [ABSTRACT FROM AUTHOR]

Published

2010

6. Z-ring force and cell shape during division in rod-like bacteria.

Author

Ganhui Lan, Wolgemuth, Charles W., and Sun, Sean X.

Subjects

*BACTERIA morphology, *CELL division, *CELL cycle, *CELL populations, *CELL growth

Abstract

The life cycle of bacterial cells consists of repeated elongation, septum formation, and division. Before septum formation, a division ring called the Z-ring, which is made of a filamentous tubulin analog, FtsZ, is seen at the mid cell. Together with several other proteins, FtsZ is essential for cell division. Visualization of strains with GFP-labeled FtsZ shows that the Z-ring contracts before septum formation and pinches the cell into two equal halves. Thus, the Z-ring has been postulated to act as a force generator, although the magnitude of the contraction force is unknown. In this article, we develop a mathematical model to describe the process of growth and Z-ring contraction in rod-like bacteria. The elasticity and growth of the cell wall is incorporated in the model to predict the contraction speed, the cell shape, and the contraction force. With reasonable parameters, the model shows that a small force from the Z-ring (8 pN in Escherichia coli) is sufficient to accomplish division. [ABSTRACT FROM AUTHOR]

Published

2007