Abstract
Bacterial conglomerates such as biofilms and microcolonies are ubiquitous in nature and play an important role in industry and medicine. In contrast to well-mixed, diluted cultures routinely used in microbial research, bacteria in a microcolonv interact mechanically with one another and with the substrate to which they are attached. Despite their ubiquity, little is known about the role of such mechanical interactions on growth and biological evolution of microbial populations. Here we use a computer model of a microbial colony of rod-shaped cells to investigate how physical interactions between cells determine their motion in the colony, this affects biological evolution. We show that the probability that a faster-growing mutant “surfs” at the colony’s frontier and creates a macroscopic sector depends on physical properties of cells (shape, elasticity, friction). Although all these factors contribute to the surfing probability in seemingly different ways, they all ultimately exhibit their effects by altering the roughness of the expanding frontier of the colony and the orientation of cells. Our predictions are confirmed by experiments in which we measure the surfing probability for colonies of different front roughness. Our results show that physical interactions between bacterial cells play an important role in biological evolution of new traits, and suggest that these interaction may be relevant to processes such as de novo evolution of antibiotic resistance.
1 Introduction
Bacteria are the most numerous organisms on Earth capable of autonomous reproduction. They have colonised virtually all ecological niches and are able to survive harsh conditions intolerable for other organisms such as high salinity, low pH, extreme temperatures, or the presence of toxic elements and compounds [1]. Many bacteria are important animal or human pathogens, but some bacteria find applications in the industry as waste degraders [2] or to produce fuels and chemicals [3]. In all these roles, biological evolution of microbes is an undesired side effect because it can disrupt industrial processes or lead to the emergence of new pathogenic [4] or antibiotic-resistant strains [5].
Experimental research on bacterial evolution has been traditionally carried out in well-stirred cultures [6, 7]. However, in their natural environment bacteria often form aggregates such as microcolonies and biofilms. Such aggregates can be found on food [8], teeth (plague), on catheters or surgical implants [9], inside water distribution pipes [10], or in the lungs of people affected by cystic fibrosis [11]. Bacteria in these aggregates adhere to one another and the surface on which they live, form layers of reduced permeability to detergents and drugs, and sometimes switch to a different phenotype that is more resistant to treatment [12, 13, 14]; this causes biofilms to be notoriously difficult to remove.
An important aspect of bacteria living in dense conglomerates is that they do not only interact via chemical signaling such as quorum sensing [15] but also through mechanical forces such as when they push away or drag other bacteria when sliding past them. Computer simulations [16, 17, 18, 19] and experiments [20, 21, 22, 23, 24] have indicated that such mechanical interactions play an important role in determining how microbial colonies grow and what shape they assume. However, the impact of these interactions on biological evolution has not been explored.
A particularly interesting scenario relevant to microbial evolution in microcolonies and biofilms is that of a range expansion [25] in which a population of microbes invades a new territory. If a new genetic variant arises near the invasion front, it either “surfs” on the front and spreads into the new territory, or (if unlucky) it lags behind the front and forms only a small “bubble” in the bulk of the population [26]. This stochastic process, called “gene surfing”, has been extensively studied [27, 28, 29, 30, 31, 32, 33, 34] but these works have not addressed the role of mechanical interactions between cells. Many of the existing models do not consider individual cells [27], assume Eden-like growth [31], or are only appropriate for diluted populations of motile cells described by reaction-diffusion equations similar to the Fisher-Kolmogorov equation [35]. On the other hand, agent-based models of biofilm growth, which have been applied to study biological evolution in growing biofilms [36, 37, 38], use very simple rules to mimic cell-cell repulsion which neglect important physical aspects of cell-cell and cell-substrate interactions such as adhesion and friction.
In this work, we use a computer model of a growing microbial colony to study how gene surfing is affected by the mechanical properties of cells and their environment. In our model, non-motile bacteria grow attached to a two-dimensional permeable surface which delivers nutrients to the colony. This corresponds to a common experimental scenario in which bacteria grow on the surface of agarose gel infused with nutrients. We have previously demonstrated [17] that this model predicts a non-equilibrium phase transition between a regular (circular) and irregular (branched) shape of a radially expanding colony of microbes, and that it can be used to study biological evolution in microbial colonies [34]. Here, we use this model to show that the surfing probability of a beneficial mutation depends primarily on the roughness of the expanding front of the colony, and to a lesser extend on the thickness of the front and cellular ordering at the front. We also investigate how mechanical properties of cells such as elasticity, friction, and adhesion affect these three quantities. We corroborate some of our results by experiments in which we vary the roughness of the growing front and show that it influences the surfing probability as expected.
2 Computer model
We use a computer model similar to that from Refs.[17, 23, 34], with some modifications. Here we discuss only the generic algorithm; more details will be given in subsequent sections where we shall talk about the role of each of the mechanical factors.
We assume that bacteria form a monolayer as if the colony was two-dimensional and bacteria always remained attached to the substrate. This is a good approximation to what occurs at the edge of the colony and, as we shall see, is entirely justifiable because the edge is the part of the colony most relevant for biological evolution of new traits. We model cells as spherocylinders of variable length and constant diameter d = 2r0 = 1μm (Fig. la). Cells repel each other with normal force determined by the Hertzian contact theory: where h is the overlap distancebetween the walls of the interacting cells, and E plays the role of the elastic modulus of the cell. Thedynamics is overdamped, i.e. the linear/angular velocityis proportional to the total force/total torque actingon the cell:
In the above equations is the position of the centre of mass of cell i,ϕi is the angle it makes with the x axis, and τ are the total force and torque acting on the cell, m and J are its mass and the momentum of inertia (perpendicular to the plane of growth), and ζ is the damping (friction) coefficient. We initially assume that friction is isotropic, and explore anisotropic friction later in Sec. 4.3.
Bacteria grow by consuming nutrients that diffuse in the substrate. The limiting nutrient concentration dynamics is modelled by the diffusion equation with sinks corresponding to the bacteria consuming the nutrient:
Here , is the nutrient concentration at position and time t, D is the diffusion coefficient of the nutrient, and k is the nutrient uptake rate. The initial concentration .
A cell elongates at a constant rate vl as long as the local nutrient concentration is larger than a certain fraction (>1%) of the initial concentration. When a growing cell reaches a pre-determined length, it divides into two daughter cells whose lengths are half the length of the mother cell. The critical inter-cap distance lcap–cap at which this occurs is a random variable from a Gaussian distribution with mean c and standard deviation ±0.15 c. Varying c allows us to extrapolate between quasi-spherical cells (e.g. yeasts S. cerevisae or the bacterium S. aureus) and rod-shaped cells (e.g. E. colt or P. aeruginosa), whereas the randomness of lcap-cap accounts for the loss of synchrony in replication that occurs after a few generations (the coefficient of variation of the time to division ~ 0.1 — 0.2 [39, 40, 41]). The two daughter cells have the same orientation as the parent cell, plus a small random perturbation to prevent the cells from growing in a straight line.
We use two gemetries in our simulations: a radially expanding colony that starts from a single bacterium (Fig. 2a), and a colony growing in a narrow (width L) but infinitely long vertical tube with periodic boundary conditions in the direction lateral to the expanding front (Fig. 2d). While the radial expansion case represents a typical experimental scenario, only relatively small colonies (106 cells as opposed to > 108 cells in a real colony [34]) can be simulated in this way due to the high computational cost. The second method (growth in a tube) enables us to simulate growth for longer periods of time at the expense of confining the colony to a narrow strip and removing the curvature of the growing front. This has however little effect on the surfing probability of faster-growing mutants if the L of the tube is sufficiently large.
Figure lb, shows a snapshot of a small colony; the concentration of the limiting nutrient is also shown. Table 1 shows default values of all parameters used in the simulation. Many of these parameters have been taken from literature data for the bacterium E. colt [34], but some parameters such as the damping coefficient must be estimated indirectly [17]. We note that the assumed value of the diffusion constant D is unrealisticallv small; the actual value for small nutrient molecules such as sugars and aminoacids would be ~ 106μm2/h, i.e., four orders of magnitude larger. Ourchoice of D is a compromise between realism and computational cost; we have also showed in Ref. [17] that the precise value of the diffusion coefficient is irrelevant in the parameter regime we are interested here. We also note that in reality cessation of growth in the center of the colony and the emergence of the growing layer may be due to the accumulation of waste chemicals, pH change etc., rather than nutrient exhaustion. Here we focus on the mechanical aspects of growing colonies and do not aim at reproducing the exact biochemistry of microbial cells, as long as the simulation leads to the formation of a well-defined growth layer (as observed experimentally).
3 Experiments
Experiments were performed as described in our previous work [34]. Here we provide a brief description of these methods.
Strains and growth conditions
For the mixture experiments measuring surfing probability, we used pairs of microbial strains that differed in fluorescence color and a selectable marker. The selective difference between the strains was adjusted as in [34] using low doses of antibiotics. The background strains and antibiotics used were E. coli DH5a with tetracycline, E. coli MG 1655 with chloramphenicol, and S. cerevisiae W303 with cycloheximide. Selective differences were measured using the colliding colony assay [32]. E. coli strains were grown on LB agar (2%) medium (l0g/L tryptone, 5g/L yeast extract, l0g/L NaCl) at either 37°C or 21°C. S. cerevisiae experiments were performed on either YPD (20g/L peptone, l0g/L yeast extract, 20g/L glucose) or CSM (0.79g/L CSM (Sunrise media Inc.), 20 g/L glucose) at 30_C. 20g/L ° agar was added to media before autoclaving. Antibiotics were added after autoclaving and cooling of the media to below 60°C.
Measuring surfing probability
For each pair of mutant and wild type, a mixed starting population was prepared that contained a low initial frequency Pi of mutants having a selective advantage s. Colony growth was initiated by placing 2μl of the mixtures onto plates and incubated until the desired final population size was reached. The initial droplet radius was measured to compute the number of cells at the droplet perimeter. The resulting colonies were imaged with a Zeiss AxioZoom vl6. The number of sectors was determined by eye. The surfing probability was calculated using Eq. (10).
Timelapse movies
For single cell-scale timelapse movies, we used a Zeiss LSM700 confocal microscope with a stage-top incubator to image the first few layers of most advanced cells in growing S. cerevisiae and E. coli colonies between a coverslip and an agar pad for about four hours, taking an image every minute.
Measuring roughness
Images of at least 10 equalsized colonies per condition were segmented and the boundary detected. The squared radial distance δr2 between boundary curve and the best-fit circle to the colony was measured as a function of the angle and averaged over all possible windows of length l. The resulting mean δr2 was averaged over different colonies.
Images of moving fronts at the single-cell level from the timelapse movies were first segmented using a local adaptative threshold algorithm to identify cells. The front was found by the outlines of cells directly at the front. For all possible windows of length l, a line was fitted to the front line and the mean squared distance from the best-fit line was measured, as in Ref. [27]. The resulting mean squared distance was averaged over all windows of length l and all frames.
4 Simulation results
4.1 Growth and statistical properties of the simulated colony
We now discuss the properties of our simulated colonies. When the colony is small, all bacteria grow and replicate. As the colony expands, the nutrient becomes depleted in the centre of the colony because diffusion of the nutrient cannot compensate its uptake by growing cells. This causes cessation of growth in the centre. When this happens, growth becomes restricted to a narrow layer at the edge of the colony, see Fig. 2a, and Supplementary Video 1. The radius of the colony increases approximately linearly in time (Fig. 2b,c). The presence of a “growing layer” of cells and the linear growth of the colony’s radius agree with what has been observed experimentally [42, 34].
Statistical properties of the growing layer can be conveniently studied using the “tube-like” geometry. Figure 2d shows a typical configuration of cells at the colony’s frontier (see also Supplementary Video 2). The growing layer can be characterized by its thickness h and roughness ρ which we calculate as follows. We first rasterize the growing front of the colony using pixels of size 1 × 1μm, and find the two edges of the front: the upper one (the colony edge) and the lower one (the boundary between the growing and quiescent cells) . We then calculate the average thickness as
This method takes into account that the growing layer can be curved and does not have to run parallel to the x axis1. Similarly, we calculate the average roughness where . Note that all quantities are in pixels and not μm.
After a short transient the expansion velocity, the nutrient profile, and other properties of the growing layer stabilize and vary little with time (Fig. 2e,f). It is therefore convenient to choose a new reference frame co-moving with the leading edge of the colony. Since cells that lag behind the front do not replicate, we do not have to simulate these cells explicitly. This dramatically speeds up simulations and enables us to study stripes of the colony of width L > 1mm and length > 10mm.
We have shown previously [17] that the thickness of the growing layer of cells is controlled by the nutrient concentration c0, nutrient uptake rate k, growth rate b, and elasticity E of cells. This in turn affects the roughness of the leading edge of the colony, see Fig. 3, where we vary the uptake rate k while keeping the remaining parameters constant. Figure 4 shows that front thickness decreases and its roughness increases with increasing k; eventually, when a critical value kc ≈ 2.5 is crossed, the growing front splits into separate branches. This transition has been investigated in details in Ref. [17]. Although this scenario can be realized experimentally [43, 44], here we focus on the “smooth” regime in which colonies do not branch out and the frontier remains continuous.
4.2 Surfing probability of a beneficial mutation
When a mutation arises at the colony’s frontier, its fate can be twofold [27, 34]. If cells carrying the new mutation remain in the active layer, the mutation “surfs” on the moving edge of the colony and the progeny of the mutant cell eventually forms a macroscopic “sector” (Fig. 5). On the other hand, if cells carrying the mutation leave the active layer, the mutation becomes trapped as a bubble in the bulk of the colony [26]. Due to the random nature of replication and mixing at the front, surfing is a stochastic process; a mutation remains in the active layer in the limit t →∞ with some probability Psurf which we shall call here the surfing probability.
Surfing is a softer version of fixation - a notion from population genetics in which a mutant takes over the population. The soft-sweep surfing probability has therefore a hard-selection-sweep counterpart, the fixation probability, which is the probability that the new mutation spreads in the population so that eventually all cells have it. Both surfing and fixation probabilities depend on the balance between selection (how well the mutant grows compared to the parent strain) and genetic drift (fluctuations in the number of organisms due to randomness in reproduction events) [45]. In the previous work [34] we showed that Psurf increased approximately linearly with selective advantage s - the difference between the growth rate of the mutant and the parent strain. Here, we study how the properties of the active layer affect Psurf for a fixed s.
We first run simulations in the planar-front geometry in which a random cell picked up from the growing layer of cells with probability proportional to its growth rate is replaced by a mutant cell with selective advantage s > 0. This can be thought of as mutations occurring with some small probability per division. The simulation finishes when either fixation (all cells in the growing layers becoming mutants) or extinction (no mutant cells in the growing layer) is achieved. Before inserting the mutant cell, the colony is simulated until the properties of the growing layer stabilize and both thickness and roughness reach steady-state values. The simulation is then repeated many times and the probability of surfing is estimated from the proportion of runs leading to fixation of the mutant in the growing layer. Snapshots showing different fates (extinction, surfing) of mutant sectors are shown in Fig 5.
Surfing probability depends on the position of the cell in the growing layer
In Ref. [34] we showed that the surfing probability strongly depends on how deeply in the growing layer a mutant was born. Here we would like to emphasize this result as it will become important later. Let Δ be the distance from the edge of the colony to the place the mutant first occurred. Figure 6 shows the probability density P Δ|surf) that a cell was born a distance Δ behind the colony front, given that it went on to surf on the edge of the expanding colony. It is evident that only cells born extremely close to the frontier have a chance to surf. Cells born deeper must get past the cells in front of them. This is unlikely to happen, even if the cell has a significant growth advantage, as the cell’s growth will also tend to push forward the cells in front of it. This also justifies why we focus on 2d colonies; even though real colonies are three-dimensional, all interesting dynamics occurs at the edge of the colony, made of a single layer of cells.
Given that surfing is restricted to the first layer of cells, and the distribution PΔ|surf) is approximately the same for all explored parameter sets (different k and s), it may seem to be a waste of computer time to study the fate of mutants that occurred deeply in the growing layer. To save the time, and to remove the effect the front thickness has on Psurf (thicker layer = lower overall probability), we changed the way of introducing mutants. Instead of inserting mutants anywhere in the growing layer, we henceforth inserted them only at the frontier.
Roughness of the front is more predictive of Psurf than its thickness
Using the new method of introducing mutants (only the first layer of cells), we run simulations for s = 0.02 and for different widths L and nutrient uptake rates k as in Fig. 4. Figure 7 shows how the surfing probability Psurf varies as a function of the thickness and the roughness of the front. Psurf increases with increasing thickness h and decreases with increasing roughness ρ. We know from Fig. 4 that thickness and roughness are inversely correlated so this reciprocal behaviour is not surprising. An interesting question is which of the two quantities, roughness or thickness, directly affects the probability of surfing? From a statistics point of view, thickness h seems to be a better predictor of Psurf because data points for hL ever, it could be that it is actually front roughness that directly (in the causal sense) affects the surfing probability and that Psurf and h are anti-correlated because of the relationship between h and ρ.
We performed two computer experiments to address the above question. First, we simulated a colony that had a very low and constant roughness ρ ≈ 1, independently of front’s thickness. This was achieved by introducing an external force Fy = -gy acting on the centre of mass of each cell, where g > 0 was a “flattening factor” whose magnitude determined the strength of suppression of deviations from a flat front. Psurf plotted in Figure 8, left, as a function of h for two cases: “normal”, rough front, and “flattened” front, demonstrates that the surfing probability does not depend on h in the case of flat front.
Second, we varied roughness while keeping thickness constant. This was done by measuring front roughness in each simulation step, and switching on the external “flattening” force Fy = −gy if the roughness was larger than a desired value ρmax. Figure 8, right, shows that although thickness remains the same for all data points, PSurf decreases with increasing roughness.
We can conclude from this that it is the increase in the roughness, and not decreasing thickness, that lowers the surfing probability for thinner fronts (larger nutrient intake rate k). However, the data points in Fig. 7, right, from different simulations do not collapse onto a single curve as it would be expected if average, large-scale front roughness was the only factor.
Local roughness predicts Psurf
According to the theory of Ref. [29], the dynamics of a mutant sector can be described by a random process similar to Brownian motion in which the sector boundaries drift away from each other with constant velocity. The velocity depends on the growth advantage s whereas the amplitude of random fluctuations in the positions of boundary walls is set by the microscopic dynamics at the front. We reasoned that these fluctuations must depend on the roughness ρ of the frontier, and that a mutant sector should be affected by front roughness when the sector is small compared to the magnitude of fluctuations. This means that local roughness ρ(l), determined over the length l of the front, should be more important than the global roughness ρ(L). We calculated the local roughness as
Here Y+ is the average height of the interface and are the vertical coordinates (interface height) of the points at the leading edge, obtained as in Section 4.1. Figure 9 shows that Psurf for different L now collapse onto a single curve, for all lengths l ≈ 10…100μm over which roughness has been calculated.
Orientation of cells affects Psurf. So far we havefocused only on the macroscopic properties of the leadingedge of the colony, completely neglecting its granularnature due to the presence of individual cells. Re-call that in our model each cell is rod-shaped, and the direction in which it grows is determined by the orientation of the rod. Figure 10a shows that cells at the leading edge assume orientations slightly more parallel to the direction of growth (vertical) in the flattened front than in the normal simulation. A natural question is how does cellular alignment affects Psurf,independently of the roughness? To answer this question, we simulated a modified model, in which external torque τ = —τmax sin[(ϕ -ϕpreferred) mod π] was applied to the cells, forcing them to align preferentially in the direction ϕ preferred. We investigated two forced alignments: ϕ preferred = 0 corresponding to cells parallel to the x axis and hence to the growing edge of the colony, and ϕ preferred = π/2 which corresponds to the vertical orientation of cells (perpendicular to the growing edge).
Figure 10b compares these two different modes with previous simulations with no external torque, for approximately the same thickness and roughness of the growing layer. It is evident that the orientation of cells strongly affects the surfing probability: horizontally-forced cells have ~ 3x smaller Psurf compared to the normal case, which in turn has Psurf ~ 5x smaller than vertically-forced cells.
Shorter cells have higher Psurf than long cells
To check how the aspect ratio of cells affect Psurf, we simulated cells whose maximal length was only 2μm and the minimal separation before the spherical caps was zero, i.e., the cells became circles immediately after division. As before we selected a set of k’s such that the thickness and roughness were approximately the same for all simulations. In order to make a fair comparison between “short rods” and “long rods” from previous simulations, thickness and roughness were expressed in cell lengths rather than in μm. This was hp done by dividing both h and ρ by the average length of a cell measured for cells from the growing layer. Figure 10c show that short rods have a much higher surfing probability than long rods.
In all previous simulations, even for short rods, cells remembered their orientation from before division and growth always initially occurred in that direction. To see whether this has any impact on Psurf, we consid ered a scenario in which the new direction of growth is selected randomly and does not correlate with the direction prior to division. Figure 10c shows that Psurf Psurf almost does not change regardless whether a short cell randomly changes its orientation after division or not.
4.3 Surfing probability and the mechanical properties of bacteria
Our results from the previous section demonstrate that surfing is affected by (i) the roughness of the growing layer, (ii) the orientation of cells, (iii) the thickness of the growing layer if mutations occur inside the growing layer and not only at its edge. To show this, we varied thickness, roughness, and orientation of cells by using ad hoc external forces flattening out the front or forcing the cells to order in a particular way. In this section we will investigate what parameters of the model affect surfing in the absence of such artificial force fields.
Thickness of the growing layer
If cells are prohibited to form multiple layers, as in our 2d simulations, thickness h can be determined from the parameters of the model by a simple dimensional analysis. Assuming h that h is proportional to the characteristic scale over which the nutrient concentration and cell density reaches bulk values [17], we can approximate h by where E is the elastic modulus of the bacterium (Pa), a is the average area per cell (μm2), ζ is the friction coefficient (Pa.h), ϕ is the replication rate (h−1), and β < 1 is a dimensionless ratio of the nutrient consumption rate to biomass production rate (i.e. new bacteria): β = (kρ0)/(ϕc0). Equation (7) shows that thickness h increases with increasing cell stiffness (larger E) and replication rate ϕ, and decreases with increasing nutrient uptake k and increasing friction ζ. The aspect ratio of the cells does not affect h in our model. Equation (7) suggests that the thickness of the growing layer can be conveniently controlled in an experiment by varying temperature or growth medium (which both affect the growth rate), or by varying the nutrient concentration c0. We shall use the first two methods when discussing the experimental verification of our theory.
Orientation of cells
A useful measure of the global alignment of cells in the colony is the order parameter S = 〈cos2(ϕ — Φ)〉. Here ϕ is the angle a cell makes with the x-axis and Φ is the angular coordinate of the vector normal to the front; this is to remove a front caused by roughness. According to this definition, S = 1 if all cells are perfectly vertically aligned (in the direction of growth), S = 0 if they are horizontal (parallel to the front), and S = 1/2 if their ori-entations are random. It turns out that changing the uptake rate (and hence thickness h) tom k = 1.6 to k = 2.8 changes S by a small amount from S = 0.77 to S = 0.70. Here we are more interested in other factors h.
Friction
One such factor is the nature of friction between cells and the substrate. So far, in all simulations the friction force was proportional to the eell’s velocity irrespective of the direction of motion. To test whether this assumption affected front roughness and the surfing probability we ran simulations in which friction coefficients were different in the directions parallel and perpendicular to the cell’s axis. We replaced Eq. (1) for the dynamics of the centre of mass with the following equation: where the matrix K accounts for the anisotropy of friction
We now have two friction coefficients: ζ⊥ is the coefficient in the direction perpendicular to cell’s major axis , whereas ζ║ is the coefficient in the parallel direction. For convenience, we shall assume that ζ║ = Aζ, ζ⊥ = ζ/A where A is the “asymmetry coeficient and ζ is the isotropic friction coeffcient, same as in previous simulations (Table 1). For isotropic friction, A = 1, hence ζ⊥ = ζ║ ζ and K = 1ζ, and we recover Eq. (1). If A > 1, it is easier for the rod to “roll” than to slide along the major axis. If A < 1 it is easier for the rod to slide.
Figure 11 shows images of the front for different levels of friction anisotropy. In the anisotropic “rolling A>1 edge-on to the colony, and the roughness is noticeably larger. In the “sliding rods” case (A < 1) the roughness is even larger but the orientation of cells falls between the isotropic and the “rolling rods” case. This is quanti fied in Fig. 12, left where we plotted _ as a function of k. The same figure, right, shows that, as expected, the surffng probability goes down with increasing roughness.
5 Comparison with experiments
We next checked whether the predicted dependence of the surfing probability on the roughness of the growing layer agree with experiments. We measured surfing probabilities of beneficial mutants with different selective advantages s = -5…25% in colonies of E. coli and S. cerevisiae (Methods) grown at different conditions affecting the roughness of the growing layer. A small number of fluorescently labeled mutant cells was mixed with a much larger number of wild-type cells, and a small droplet of the mixture was used to inoculate a colony on a Petri dish. After a few days, colonies with a characteristic sectoring pattern emerged (Fig. 13). By zooming into the colony edge we confirmed that some mutants “surfed” at the front and expanded into large sectors whereas some mutants did not make it and became trapped as bubbles in the bulk of the colony (Fig. 13, compare with Fig. 5).
We counted the number of sectors and estimated the surfing probability Psurf from the formula [34]: where P1 is the initial fraction of mutant cells in the population and r0 the initial radius of the colony (in units of cell diameters). Note this equation makes sense only if surfing is restricted to the first layer of cells; we have shown that this is true in computer simulations and we shall experimentally validate it later in this section. Fig. 14a shows Psurf for E. coli and S. cerevisiae, and for different conditions. In the limit of low selective advantage s < 10% we are interested here, the surfing probability is highest in colonies of roughly-spherical S. cerevisiae, which have rather smooth boundaries, and smallest for the rod-shaped bacterium E. coli, which are characterized by rough front. This agrees with our predictions (Fig. 10), however it does not yet show whether this is due to difference in the cell shape or different thickness/roughness of the growing layer.
To study the connection between surfing and surface roughness, we computed the local roughness p(l) as a function of window length l (Fig. 14b, cf. Eq. (6) and Methods) for the same colonies for which we previously calculated Psurf (Fig. 14a). In all cases, p2(l) showed a linear dependence on window length l after a transient at small window lengths, i.e., the colony boundary behaved like a standard random walk (Fig. 14c).
We then tested the correlation of colony roughness with surfing probability in a similar way to what we did in computer simulations. In Fig. 14d, we plot the surfing probability Psurf as a function of colony roughness measured at one specific window length l = 17mm (dotted line in Fig. 14c), for different selective advantages s. We observe that the surfing probability of E. coli decreases with increasing roughness (Fig. 14d) for all s Similar results are obtained for different choices of the window length l for which roughness is calculated. The situation is less clear for S. cerevisiae; we hypothesize that this is due to roughness being too small (c.f. Fig. 9) to markedly affect the surfing probability.
We next examined how microscopic properties of the front (cellular orientation) correlated with macroscopic roughness. We analysed microscopic images of the fronts of E. coli and S. cerevisiae fronts (Methods, data from Ref. [34]), and measured local roughness ρ(l) over sub-mm length scales l Example snapshots in Fig. 15a,b show that roughness of the fronts indeed differ very much for these two microorganisms. Figure 15c confirms that E. coli has a much higher roughness compared to S. cerevisiae, suggesting that macroscopic roughness on the colony scale is a consequence of microscopic front roughness on the single-cell level.
To study the dynamics of surfing, we tracked E. coli cells over 200 minutes and measured their distance from, and orientation relative to the edge of the colony, as well as the number of offspring for all cells in the initial image. Figure 15d shows that cells only have an appreciable number of offspring if they are within about one cell diameter of the front. This agrees with our conclusion from simulations and justifies inserting mutants only directly at the front.
Figure 15e shows the order parameter S = (cos2(0 — Φ)), which measures the orientation of cells and has been defined in Sec. 4.3, as a function of the distance from the front. Cells near the front tend to align parallel to the front. This changes quickly behind the front, with most cells being perpendicular to the to the growth direction starting about 5_m behind the front. Figure 15f shows the distribution of S obtained from simulations; the agreement with the experimental data from Fig. 15e is excellent, suggesting that our model indeed captures the dynamics of the growing bacterial front reasonably well.
6 Conclusions
In this work we have focused on the role of mechanical interactions in microbial colonies. We first used computer simulations to show that the speed of biological evolution, measured by the probability that a new mutation “surfs” at the growing edge of a microbial colony, depends mostly on the thickness and roughness of the growing layer of cells at colony’s front. Thicker fronts decrease the per-cell surfing probability because only cells from the very first layer of cells create successful progenies, and the fraction of such cells decreases with increasing front thickness. Rougher fronts also decrease the surfing probability for a similar reason; only cells at the tips of the “bumps” are successful and these tips become smaller for rougher fronts. Moreover, roughness and thickness are related; thicker front have lower roughness and vice versa. While the dependence between genetic segregation and the front thickness [46], and between thickness and roughness [47] has been known previously, in this work we have shown that it is actually the roughness of the growing layer that should be thought of as affecting the surfing probability in the causal sense. We have also linked thickness and roughness to the mechanical properties of cells for the first time. Moreover, we have discovered that the orientation of cells has also a significant effect, irrespective of front roughness, on the surfing probability.
All these quantities (roughness, thickness, cellular alignment) are controlled in a very non-trivial way by the properties of cells and their environment: cell-surface friction (and anisotropy of thereof), elasticity of cells, their growth/nutrient uptake rate, and their shape. While some of these parameters are very difficult to vary experimentally, we managed to show in simple experiments that the growth rate and the shape of cells affect the surfing probability in the way predicted by our simulations.
Microbial evolution is a research area that is important both from fundamental and practical viewpoints. In particular, our research shows that mechanical forces such as adhesion, friction, etc., can play a significant role in biological evolution of microorganisms. To our knowledge, this article is the first that not only puts forward this idea but also provides concrete arguments in its support.
From a more practical point of view, our results are relevant to the evolution of antimicrobial resistance. It has been demonstrated that even a small bacterial population can develop de novo resistance to some antimicrobial drugs in less than a day [48]. This rapid evolution makes the most popular drugs - antibiotics - increasingly ineffective [49]. Since the rate of discovery of new antibiotics has steadily declined over years [50], the evolution of drug-resistant bacteria has been highlighted as one of the major challenges we will face in the coming decades. By demonstrating the role of mechanical interactions on biological evolution in microbial aggregates, our research opens up a new antimicrobial paradigm in which the physical properties of microbes could be targeted alongside standard antimicrobial therapy to reduce the probability of evolving resistance to drugs.
Acknowledgments
Research reported in this publication was supported by the Royal Society of Edinburgh (B.W.), National Institute of General Medical Sciences of the National Institutes of Health under Award Number R01GM115851 (O.H.), by a National Science Foundation Career Award (O.H.) and by a Simons Investigator award from the Simons Foundation (O.H.). The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health.