Spatial self-organization resolves conflicts between individuality and collective migration

Fu, Xiaofeng; Kato, Setsu; Long, Jessica B.; Mattingly, Henry H.; He, Caiyun; Vural, Dervis Can; Zucker, Steven W.; Emonet, Thierry

doi:10.1038/s41467-018-04539-4

Cited by 86 publications

(148 citation statements)

References 56 publications

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“…Organelles (Kutschera & Niklas, 2005;Siegel, 1960), single (Lewis, 2007) and multi-phenotype (Fu et al, 2018;Koufopanou, 1994) bacterial populations, tissues and organs in multicellular organisms (Carroll, 2001;Hedges, Blair, Venturi, & Shoe, 2004), casts and social classes in colonial animals (Beshers & Fewell, 2001;Smith, Toth, Suarez, & Robinson, 2008), and guilds in ecological communities (Futuyma & Moreno, 1988;May & Seger, 1986;Terborgh, 1986), all fulfil specialized roles that are vital for the functioning of a larger whole. Specialization also gives rise to metabolic interdependencies in microbial populations and can serve as a strong mechanism for community assembly (Zelezniak et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

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Evolution of specialized microbial cooperation in dynamic fluids

Uppal

Vural

2020

J of Evolutionary Biology

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Here, we study the evolution of specialization using realistic computer simulations of bacteria that secrete two public goods in a dynamic fluid. Through this first‐principles approach, we find physical factors such as diffusion, flow patterns and decay rates are as influential as fitness economics in governing the evolution of community structure, to the extent that when mechanical factors are taken into account, (a) generalist communities can resist becoming specialists despite the invasion fitness of specialization; (b) generalist and specialists can both resist cheaters despite the invasion fitness of free‐riding; and (c) multiple community structures can coexist despite the opposing force of competitive exclusion. Our results emphasize the role of spatial assortment and physical forces on niche partitioning and the evolution of diverse community structures.

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Section: Introductionmentioning

confidence: 99%

“…E. coli can differentiate into transient nongrowing cells and normally growing cells to hedge their bets across different environments (Lewis, 2007). A travelling band of E. coli will exhibit a continuum of navigation styles, each specializing in processing different local conditions while still moving in unison (Fu et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Evolution of specialized microbial cooperation in dynamic fluids

Uppal

Vural

2020

J of Evolutionary Biology

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“…Although the principles of chemotactic sensing are fairly well understood for a single cell [28,30], little is known of the effects of physical interactions between cells on chemotaxis, despite their frequent occurrence during self-concentration processes [37][38][39][40][41][42] or high-density collective motility [21,22,26]. Here we used a model system, a suspension of E. coli in a controlled environment, to investigate the effect of collective motion, emerging when cell density increases, on chemotactic sensing.…”

Section: Discussionmentioning

confidence: 99%

“…Although typically seen as a single-cell behavior, chemotaxis also drives collective behaviors based on chemical interactions, such as autoaggregation [37,38], self-concentration in patches [39,40] and travelling band formation [41,42], where chemotactic response to self-generated gradients of chemoattractants lead to local cell density increases. However, very little is known about how the high-density physical interactions and the resulting collective motion influence the chemotactic navigation of bacteria [43,44]: e.g., would chemotaxis be improved by alignments of convective flows with the gradient [12,44] or compromised by random collisions between cells?…”

Section: Introductionmentioning

confidence: 99%

Chemotactic behaviour ofEscherichia coliat high cell density

Colin¹,

Drescher²,

Sourjik³

2018

Preprint

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4At high cell density, swimming bacteria exhibit collective motility patterns, self-organized through physical 5 interactions of a however still debated nature. Although high-density behaviours are frequent in natural 6 situations, it remained unknown how collective motion affects chemotaxis, the main physiological function 7 of motility, which enables bacteria to follow environmental gradients in their habitats. Here, we systemati-8 cally investigate this question in the model organism Escherichia coli, varying cell density, cell length, and 9 suspension confinement. The characteristics of the collective motion indicate that hydrodynamic interac-10 tions between swimmers made the primary contribution to its emergence. We observe that the chemotactic 11 drift is moderately enhanced at intermediate cell densities, peaks, and is then strongly suppressed at higher 12 densities. Numerical simulations reveal that this suppression occurs because the collective motion disturbs 13 the choreography necessary for chemotactic sensing. We suggest that this physical hindrance imposes a fun-14 damental constraint on high-density behaviours of motile bacteria, including swarming and the formation 15 of multicellular aggregates and biofilms.Indroduction 17 When the cell density of a suspension of swimming bacteria increases, collective motion emerges, char-18 acterized by intermittent jets and swirls of groups of cells [1][2][3]. This behaviour is observed for many 19 microorganisms not only in artificial but also in natural situations, often at an interface, e.g. when bac-20 teria swarm on a moist surface in the lab [4][5][6][7][8] or during infection [9], or at an air-water interface during 21 formation of pellicle biofilms [1, 10]. Bacterial collective motion has been extensively studied experimentally 22 [11][12][13][14] and theoretically [15][16][17][18][19][20], and it is known to emerge from the alignment between the self-propelled 23 cells [21]. Two alignment mechanisms have been proposed, based either on steric interactions between the 24 rod-like bacteria [22][23][24] or on the hydrodynamics of the flow they create as they swim [15, 17], which 25 displays a pusher force dipole flow symmetry [3, 25, 26]. However, the relative importance of these two 26 mechanisms has not been clearly established so far [27]. 27Bacterial collective motion contrasts to the behaviour of individual motile cells in dilute suspension, 28 when bacteria swim in relatively straight second-long runs interrupted by short reorientations (tumbles), 29 resulting at long times in a random walk by which they explore their environment [28]. Bacteria can 30 furthermore navigate in environmental gradients by biasing this motion pattern: they lengthen (resp. 31 shorten) their runs when swimming toward attractive (resp. repulsive) environment [28]. The biochemical 32 signaling pathway controlling this chemotactic behaviour is well understood in E. coli [29, 30] and it is 33 one of the best modeled biological signaling systems [31]. Bacteria monitor -via...

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“…Analyses of 25 phenotypic diversity in motile cells suggest that it also may lead to a selective advantage 26 at a population level [23][24][25]. Although several studies have tackled the problem of how 27 individual variability affects population expansion [6,9,10,26,27,27,28,[28][29][30], 28 systematic and predictive theory is still lacking [22].…”

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confidence: 99%

Bet-hedging strategies in expanding populations

Martín

Muñoz

Pigolotti

2018

Preprint

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In ecology, species can mitigate their extinction risks in uncertain environments by diversifying individual phenotypes. This observation is quantified by the theory of bet-hedging, which provides a reason for the degree of phenotypic diversity observed even in clonal populations. The theory of bet-hedging in well-mixed populations is rather well developed. However, many species underwent range expansions during their evolutionary history, and the importance of phenotypic diversity in such scenarios still needs to be understood. In this paper, we develop a theory of bet-hedging for populations colonizing new, unknown environments that fluctuate either in space or time. In this case, we find that bet-hedging is a more favorable strategy than in well-mixed populations. For slow rates of variation, temporal and spatial fluctuations lead to different outcomes. In spatially fluctuating environments, bet-hedging is favored compared to temporally fluctuating environments. In the limit of frequent environmental variation, no opportunity for bet-hedging exists, regardless of the nature of the environmental fluctuations. For the same model, bet-hedging is never an advantageous strategy in the well-mixed case, supporting the view that range expansions strongly promote diversification. These conclusions are robust against stochasticity induced by finite population sizes. Our findings shed light on the importance of phenotypic heterogeneity in range expansions, paving the way to novel approaches to understand how biodiversity emerges and is maintained. Author summaryEcological populations are often exposed to unpredictable and variable environmental 1 conditions. A number of strategies have evolved to cope with such uncertainty. One of 2 them is stochastic phenotypic switching, by which some individuals in the community 3 are enabled to tackle adverse conditions, even at the price of reducing overall growth in 4 the short term. In this paper, we study the effectiveness of these "bet-hedging" 5 strategies for a population in the process of colonizing new territory. We show that 6 bet-hedging is more advantageous when the environment varies spatially rather than 7 temporally, and infrequently rather than frequently. 8 Introduction 9The dynamics and evolutionary history of many biological species, from bacteria to 10 humans, are characterized by invasions and expansions into new territory. The 11 September 19, 2018 1/15 effectiveness of such expansions is crucial in determining the ecological range and 12 therefore the success of a species. A large body of observational [1, 2] and 13 experimental [3-6] literature indicates that evolution and selection of species undergoing 14 range expansions can be dramatically different from that of other species resident in a 15 fixed habitat. Theoretical studies of range expansions based on the Fisher-Kolmogorov 16 equation [7, 8] or variants [9, 10] also support this idea. Adaptive dispersal strategies [2] 17and small population sizes at the edges of expanding fronts [11,12] are among the m...

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Spatial self-organization resolves conflicts between individuality and collective migration

Cited by 86 publications

References 56 publications

Evolution of specialized microbial cooperation in dynamic fluids

Evolution of specialized microbial cooperation in dynamic fluids

Chemotactic behaviour ofEscherichia coliat high cell density

Bet-hedging strategies in expanding populations

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