Myxococcus xanthus Swarms Are Driven by Growth and Regulated by a Pacemaker

Twitching motility-mediated biofilm expansion is a complex, multicellular behavior that enables the active colonization of surfaces by many species of bacteria. In this study we have explored the emergence of intricate network patterns of interconnected trails that form in actively expanding biofilms of Pseudomonas aeruginosa. We have used high-resolution, phase-contrast time-lapse microscopy and developed sophisticated computer vision algorithms to track and analyze individual cell movements during expansion of P. aeruginosa biofilms. We have also used atomic force microscopy to examine the topography of the substrate underneath the expanding biofilm. Our analyses reveal that at the leading edge of the biofilm, highly coherent groups of bacteria migrate across the surface of the semisolid media and in doing so create furrows along which following cells preferentially migrate. This leads to the emergence of a network of trails that guide mass transit toward the leading edges of the biofilm. We have also determined that extracellular DNA (eDNA) facilitates efficient traffic flow throughout the furrow network by maintaining coherent cell alignments, thereby avoiding traffic jams and ensuring an efficient supply of cells to the migrating front. Our analyses reveal that eDNA also coordinates the movements of cells in the leading edge vanguard rafts and is required for the assembly of cells into the "bulldozer" aggregates that forge the interconnecting furrows. Our observations have revealed that large-scale self-organization of cells in actively expanding biofilms of P. aeruginosa occurs through construction of an intricate network of furrows that is facilitated by eDNA.collective behavior | t4p | type IV pili | tfp | swarming

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“…3A, Fig. S4C) bear a striking resemblance to M. xanthus swarms cultured on the surface of solidified growth media (25).…”

Section: Quantitative Analysis Of Cell Movements During Interstitial mentioning

confidence: 91%

Self-organization of bacterial biofilms is facilitated by extracellular DNA

Gloag¹,

Turnbull²,

Huang

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

258

269

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“…(i) Swarms have flat tops; they are not heaped up like a colony. (ii) The rate at which a steady state swarm expands is directly proportional to the rate of individual cell movement, not to its rate of growth, and the increase in cell numbers contribute only 10% of the swarm expansion rate (5). All stages of growth can be found in a swarm.…”

mentioning

confidence: 99%

“…Due to the way Myxococcus xanthus cells move and to the way cells interact with each other, their swarms spread outward (5). The capacity to spread arises from their ability to build different types of organized, dynamic, multicellular structures: planar, rectangular rafts of cells with their long axes aligned; and round multilayered mounds.…”

mentioning

confidence: 99%

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Transmission of a signal that synchronizes cell movements in swarms of Myxococcus xanthus

Kaiser

Warrick

2014

Proc. Natl. Acad. Sci. U.S.A.

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We offer evidence for a signal that synchronizes the behavior of hundreds of Myxococcus xanthus cells in a growing swarm. Swarms are driven to expand by the periodic reversing of direction by members. By using time-lapse photomicroscopy, two organized multicellular elements of the swarm were analyzed: single-layered, rectangular rafts and round, multilayered mounds. Rafts of hundreds of cells with their long axes aligned in parallel enlarge as individual cells from the neighborhood join them from either side. Rafts can also add a second layer piece by piece. By repeating layer additions to a raft and rounding each layer, a regular multilayered mound can be formed. About an hour after a five-layered mound had formed, all of the cells from its top layer descended to the periphery of the fourth layer, both rapidly and synchronously. Following the first synchronized descent and spaced at constant time intervals, a new fifth layer was (re)constructed from fourthlayer cells, in very close proximity to its old position and with a number of cells similar to that before the "explosive" descent. This unexpected series of changes in mound structure can be explained by the spread of a signal that synchronizes the reversals of large groups of individual cells.timer | pattern formation | cell polarity | synchrony | polysaccharide

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“…This suggests a layer of complexity in the associations of M. xanthus and other organisms that has not been considered previously-promotion of intercellular activity by neighboring cells can be both blocked and undone by predivision cells. Several studies have shown the importance of different biochemical and physical components that promote cell-cell interaction (11,18,21,22,44,(54)(55)(56), group alignment (21,44,56), and group motility (19,20,44,57,58) of M. xanthus. However, our results show that pausing for cell division dominates over any tested intercellular interactions, with no distinction between the pausing behavior of dividing cells that were in contact with other cells and that of dividing cells that were isolated.…”

Section: Discussionmentioning

confidence: 99%

Cell Division Resets Polarity and Motility for the Bacterium Myxococcus xanthus

et al. 2014

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e Links between cell division and other cellular processes are poorly understood. It is difficult to simultaneously examine division and function in most cell types. Most of the research probing aspects of cell division has experimented with stationary or immobilized cells or distinctly asymmetrical cells. Here we took an alternative approach by examining cell division events within motile groups of cells growing on solid medium by time-lapse microscopy. A total of 558 cell divisions were identified among approximately 12,000 cells. We found an interconnection of division, motility, and polarity in the bacterium Myxococcus xanthus. For every division event, motile cells stop moving to divide. Progeny cells of binary fission subsequently move in opposing directions. This behavior involves M. xanthus Frz proteins that regulate M. xanthus motility reversals but is independent of type IV pilus "S motility." The inheritance of opposing polarity is correlated with the distribution of the G protein RomR within these dividing cells. The constriction at the point of division limits the intracellular distribution of RomR. Thus, the asymmetric distribution of RomR at the parent cell poles becomes mirrored at new poles initiated at the site of division. Many approaches to study cell division utilize traits that readily allow the distinction of two progeny cells. For example, cells displaying "asymmetrical" division traits allow the clear distinction of numerous characteristics that can then be monitored while deciphering other unknowns. Caulobacter bacteria are among the best studied with this distinction (1), but other biological examples include: preneuron neuroblast brain cells, budding Saccharomyces cerevisiae, germ line cells of male Drosophila, endospore development by Bacillus species, and Mycobacterium species subjected to environmental nutrient stress (2, 3). While such explicitly distinct examples may be rare, nearly all types of cells display some asymmetrical properties when functioning properly. There are numerous examples of distinctive asymmetrical and polarized attributes of cells (4). However, one difficulty that remains in characterizing asymmetrical properties in biology is distinguishing the timing and order of those intra-and intercellular attributes that are transient in nature. Alternative to studying asymmetric cell types that can be readily differentiated, other research strategies to probe stages of division often examine stationary or immobilized cells.Myxococcus xanthus is one of many myxobacteria, common soil microbes that grow readily in environments rich in complex organics, such as those containing decaying plants (5) or other bacteria (6). M. xanthus cells exhibit a symmetric morphology. The specific mechanism and dynamics of M. xanthus cell division, like those of most nonmodel organisms, are not entirely known. M. xanthus is among many bacteria lacking a clear MinCD system that drives the recruitment of FtsZ for division. It is known that the middle of M. xanthus cells is marked by PomZ, w...

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Myxococcus xanthus Swarms Are Driven by Growth and Regulated by a Pacemaker

Cited by 27 publications

References 31 publications

Self-organization of bacterial biofilms is facilitated by extracellular DNA

Self-organization of bacterial biofilms is facilitated by extracellular DNA

Transmission of a signal that synchronizes cell movements in swarms of Myxococcus xanthus

Cell Division Resets Polarity and Motility for the Bacterium Myxococcus xanthus

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