Extinction transition in bacterial colonies under forced convection

Neicu, T.; Pradhan, Arpan; Larochelle, D. A.; Kudrolli, Arshad

doi:10.1103/physreve.62.1059

Cited by 30 publications

(30 citation statements)

References 12 publications

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“…They analyzed the dynamics near the extinction and delocalization velocities, where the population is blown off of the oasis. Their predictions have been qualitatively confirmed by recent experiments on Bacillus subtilis growth [5].…”

supporting

confidence: 70%

A quasispecies on a moving oasis

Desai

Nelson

2005

Theoretical Population Biology

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A population evolving in an inhomogeneous environment will adapt differently to different regions. We study the conditions under which such a population can maintain adaptations to a particular region when that region is not stationary, but can move. In particular, we study a quasispecies living near a favorable patch ("oasis") in the middle of a large "desert." The population has two genetic states, one of which which conveys a relative advantage while in the oasis at the cost of a disadvantage in the desert. We consider the population dynamics when the oasis is moving, or equivalently some form of "wind" is blowing the population away from the oasis. We find that the ratio of the two types of individuals exhibits sharp transitions at particular oasis velocities. We calculate an extinction velocity, and a switching velocity above which the dominance switches from the oasis-adapted genotype to the desert-adapted one. This switching velocity is analagous to the quasispecies mutational error threshold. Above this velocity, the population cannot maintain adaptations to the properties of the oasis.

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supporting

confidence: 70%

A quasispecies on a moving oasis

Desai

Nelson

2005

Theoretical Population Biology

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“…As we have discussed, the NLCFE presents patterns only in the presence of a nonlocal interaction term. Then rescaling the Gaussian distribution (17) for z = Lx, we get…”

Section: Pattern Formation and Finite Sizementioning

confidence: 99%

“…Many studies on pattern formation have been carried out experimentally on systems in which convection plays an important role. The convective cells of Rayleigh-Bernard instabilities [15], moving Wigner glasses [16], and pattern formation in bacterial colonies under forced convection [17] illustrate the phenomenon of self-organization in convective motion. In these cases, a flux of particles is expected to undergo a new regime of organization at the threshold of external parameters.…”

Section: Introductionmentioning

confidence: 98%

Self-organization analysis for a nonlocal convective Fisher equation

et al. 2009

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“…These patches are assumed to be of characteristic size 1/λ, where λ is a scale factor central to the model. Alternative ways of inducing spatially non-uniform growth or depletion are to apply, for photosynthetic bacteria, favourable or unfavourable (UV) illumination according to a structured or random spatial pattern [1,2].…”

Section: Introduction Of the Modelmentioning

confidence: 99%

Hierarchical population model with a carrying capacity distribution for bacterial biofilms

Indekeu

Sznajd-Weron

2003

Phys. Rev. E

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A time-and space-discrete model for the growth of a rapidly saturating local biological population N (x, t) is derived from a hierarchical random deposition process previously studied in statistical physics. Two biologically relevant parameters, the probabilities of birth, B, and of death, D, determine the carrying capacity K. Due to the randomness the population depends strongly on position, x, and there is a distribution of carrying capacities, Π(K). This distribution has selfsimilar character owing to the imposed hierarchy. The most probable carrying capacity and its probability are studied as a function of B and D. The effective growth rate decreases with time, roughly as in a Verhulst process. The model is possibly applicable, for example, to bacteria forming a "towering pillar" biofilm. The bacteria divide on randomly distributed nutrient-rich regions and are exposed to random local bactericidal agent (antibiotic spray). A gradual overall temperature change away from optimal growth conditions, for instance, reduces bacterial reproduction, while biofilm development degrades antimicrobial susceptibility, causing stagnation into a stationary state.

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Extinction transition in bacterial colonies under forced convection

Cited by 30 publications

References 12 publications

A quasispecies on a moving oasis

A quasispecies on a moving oasis

Self-organization analysis for a nonlocal convective Fisher equation

Hierarchical population model with a carrying capacity distribution for bacterial biofilms

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