Abstract
Although mutualisms are often studied as simple pairwise interactions, they typically involve complex networks of interacting species. How multiple mutualistic partners that provide the same service and compete for resources are maintained in mutualistic networks is an open question. We use a model bacterial community in which multiple ‘partner strains’ of Escherichia coli compete for a carbon source and exchange resources with a ‘shared mutualist’ strain of Salmonella enterica. In laboratory experiments, competing E. coli strains readily coexist in the presence of S. enterica, despite differences in their competitive abilities. We use ecological modeling to demonstrate that a shared mutualist can create temporary resource niche partitioning by limiting growth rates, even if yield is set by a resource external to a mutualism. This mechanism can extend to maintain multiple competing partner species. Our results improve our understanding of complex mutualistic communities and aid efforts to design stable microbial communities.
Similar content being viewed by others
Introduction
Mutualisms—bidirectional positive interspecies interactions—are abundant and important1,2. Traditionally, studies of mutualism have focused on interactions between two species. However, communities often contain many species of mutualists that interact in complex networks3,4. For example, many flowering plants are pollinated by multiple insect species5, and corals interact with a phylogenetically diverse set of endosymbionts6. In fact, two-partner mutualisms are now thought to be the exception rather than the norm3,7. Understanding the ecology of multiple mutualist communities is an important goal3,8. To do so, we need theoretical predictions and experimentally tractable multiple mutualist communities.
In many multiple mutualist systems, several functionally similar species within a “partner guild” supply resources or services to a “shared mutualist,” which supplies resources in return (Fig. 1)3,8. For example, a guild consisting of two plant species may provide carbon compounds to a shared arbuscular mycorrhizal fungi mutualist that provides both phosphorus, from which one plant species benefits, and pathogen protection, from which the other plant benefits8,9. Recent studies have suggested that interactions between species within the partner guild can affect the coexistence and stability of the whole community10,11,12. Within-guild interactions may be especially important if the partner mutualists within the guild are ecologically similar. If partner species’ resource niches overlap, they may compete for resources that are external to the mutualism. When multiple species compete for the same limiting resource, one species may competitively exclude the others, leading to a loss of diversity within the community12,13. However, because species-rich communities of multiple mutualists exist in nature, certain mechanisms that maintain coexistence must exist14. Here, we seek to understand the conditions in which multiple partner mutualists are able to coexist despite competition for a common resource.
Using a community of mutualistic bacteria, we explore the potential for the coexistence of multiple partner species. Our system consists of a partner guild of Escherichia coli strains that compete with one another for a carbon source and engage in mutualism with a strain of Salmonella enterica, the shared mutualist. The strains engage in mutualism via cross-feeding, with the E. coli strains providing acetate and receiving amino acids from S. enterica. We show that the competing E. coli strains are unable to coexist when they are provided amino acids in the growth media rather than obtaining them from the shared mutualist because one strain has a faster growth rate. However, when the two E. coli strains obtain their amino acids from the shared mutualist, the two E. coli strains coexist, maintaining the diversity of the multiple mutualist communities. Next, we use a resource-explicit ecological model to identify factors that promote coexistence. We show that limitation by the shared mutualist is key—if the shared mutualist sets the growth rate of the community, the two-partner mutualists coexist because they are temporarily limited by different resources. Finally, we demonstrate computationally that this phenomenon can promote the coexistence of more than two-partner mutualists. This work helps us understand how diversity is maintained in multiple mutualist communities and can inform efforts to design stable microbial communities.
Results
Laboratory experiments
We studied competition between two-partner mutualists using a laboratory system of cross-feeding bacteria (Fig. 2a). The partner guild consists of one E. coli strain that is a methionine auxotroph (“Em”) and another E. coli strain that is an arginine auxotroph (“Er”)—each strain lacks a gene in the biosynthetic pathway for its respective amino acid, so in order for a strain to grow, its required amino acid must be available in the environment. The two E. coli strains compete for lactose, which we provide in the growth media, and excrete acetate as a byproduct of lactose metabolism. We experimentally evolved a “shared mutualist” strain of Salmonella enterica (“Smr”) that secretes methionine and arginine. Smr was derived from a strain that we had previously evolved to secrete methionine15, and acquired a mutation in argG causing arginine secretion. Smr consumes acetate and is unable to metabolize lactose.
Growth rates are a classic measure of competitive ability in microbial systems16. Therefore, we started by measuring the growth rates of the three strains in monoculture and in pairwise coculture. For all experiments, we used a batch culture setup in which populations grow until resources are depleted. When grown in monoculture in media containing each strain’s required nutrients (with both amino acids in excess in Em and Er monocultures), the three strains have different maximum growth rates (one-way ANOVA: F(2, 9) = 9897, P = 9.1e-16; Fig. 2b). Er has a slightly higher growth rate than Em (Em: n = 3, mean = 0.666 h−1, SD = 0.003; Er: n = 3, mean = 0.680 h−1, SD = 0.007; Tukey HSD: P = 0.037), and both E. coli strains grow faster than Smr (Smr: n = 6, mean = 0.172 h−1, SD = 0.007; Tukey HSD: P < 1e-7 for both comparisons). When each E. coli strain is grown separately in coculture with Smr in lactose media with no amino acids, the coculture containing Em grows faster (Em + Smr: n = 3, mean = 0.350 h−1, SD = 0.0006; Er+Smr: n = 3, mean = 0.295 h−1, SD = 0.006; Welch’s two-sided two-sample t test: t(2) = 15, P = 0.004; Fig. 2c). This may be because Smr secretes methionine at a faster rate than arginine, or because Em requires less methionine than Er requires arginine (Supplementary Fig. 1). Yields in monoculture and coculture are shown in Supplementary Figs. 2 and 3.
Next, we tested whether the two E. coli strains coexist in a lactose environment with excess amino acids and no Smr present. We predicted that the strain with the faster monoculture growth rate, Er, would outcompete Em (Fig. 2b). We assessed the coexistence of the two E. coli strains through a mutual invasibility test, measuring whether each E. coli strain could increase in frequency when initially rare. Mutual invasibility would indicate negative-frequency dependence and coexistence17,18. Em decreased in frequency from all five initial frequencies, indicating that Er outcompetes Em and coexistence is not possible (Fig. 2d; Welch’s two-sided two-sample t test for the lowest initial Em frequency, 0.006: n = 3, mean change = −0.004, SD = 0.0001, t(2) = 48, P = 0.0004). Competitive exclusion of Em by Er also occurs in this environment in the presence of Smr (Supplementary Fig. 4) and over multiple transfers (Supplementary Fig. 5a).
These findings led to two alternative hypotheses about coexistence in the three-strain multiple mutualist community: Hypothesis (1): One E. coli strain will outcompete the other. Er may outcompete Em due to its faster monoculture growth rate and greater competitive ability, or Em may outcompete Er due to its faster coculture growth rate when paired with Smr. Hypothesis (2): The two E. coli strains coexist.
To assess the coexistence of the two E. coli strains in the three-strain community, we again conducted a mutual invasibility test. We inoculated cultures with six different initial frequencies of the E. coli strains, with a constant initial density of Smr. In line with Hypothesis 2, both E. coli strains increased in frequency when initially rare, indicating coexistence (Fig. 2e). Em increased in frequency when initially rare (Welch’s two-sided two-sample t test for the lowest initial Em frequency, 0.006: n = 3, mean change = +0.495, SD = 0.015, t(2) = −58, P = 0.0003), and decreased in frequency when initially common (Welch’s two-sided two-sample t test for the highest initial Em frequency, 0.985: n = 3, mean change = −0.210, SD = 0.056, t(2) = 6, P = 0.02). Smr also increased in frequency from rare and decreased when initially common (Supplementary Fig. 6), consistent with previous results showing that S. enterica stably coexists with cross-feeding E. coli19. Coexistence was maintained over multiple transfers, although the evolution of prototrophy prevented long-term assessment of frequencies (Supplementary Fig. 5b). Yields are shown in Supplementary Fig. 7.
Ecological modeling
To understand why the two E. coli strains coexist, we constructed a computational ecological model with ordinary differential equations for the three strains (Em, Er, and Smr) and the four resources (lactose, acetate, methionine, and arginine):
Em, Er, and Smr are the population densities of each strain (cells/ml). Resources (lcts = lactose, ac = acetate, met = methionine, arg = arginine) are in units of cell-equivalents/ml (the density of cells that a unit of resource can produce). Growth is governed by Monod saturation rates using Monod constants (e.g., kEm lcts), which are in units of cells/ml. Production terms (e.g., pEm ac) are in units of cells/cell. Default values and parameter descriptions can be found in Supplementary Table 1. Briefly, we kept the model simple by using equal values for the same parameters for each of the three strains, except for their growth rates, which we approximated based on monoculture growth rates in the laboratory system (Fig. 2b). Default growth rates are µEm = 1.0, µEr = 1.1, and µSmr = 0.5 with units of 1/timestep.
Consistent with our laboratory system, the model shows that Er outcompetes Em when the two strains are grown in a lactose environment without Smr and with excess amino acids (Fig. 3a). This is because Er has a faster growth rate than Em. Also consistent with our findings in the laboratory system, in the three-strain community in a lactose environment, the two E. coli strains coexist. Both E. coli strains increase in frequency when started rare (Fig. 3b). Stable equilibrium frequencies are quickly reached when communities are serially transferred with 100-fold dilutions, and coexistence is robust to changes in initial Smr densities (Supplementary Fig. 8).
To understand why Em and Er coexist despite lactose competition, we focused on nutrient dynamics in the model. At the end of growth, lactose is fully depleted while amino acids are in excess, highlighting that competition for lactose sets the yield of each E. coli strain (Supplementary Figs. 10 and 11). However, the dynamics of amino acid concentrations early in growth provide an explanation for coexistence. When Em starts rare (the left boxed point in Fig. 3b), it initially depletes little methionine and methionine is therefore plentiful, which allows Em to grow at its maximum growth rate. In contrast, Er initially depletes arginine at a faster rate, and Er’s growth rate is limited by low arginine concentrations at early timepoints (Fig. 3c and Supplementary Fig. 9). Conversely, when Er starts rare (the right boxed point in Fig. 3b), arginine is never limiting, while methionine is limiting at early timepoints (Fig. 3d and Supplementary Fig. 10). This means that the initially common E. coli strain’s growth rate is limited by its amino acid, while the initially rare E. coli strain is able to grow at its maximum growth rate because its amino acid is abundant. Initial rates of amino acid consumption create negative-frequency dependence, allowing the initially rare E. coli strain to increase in frequency.
To explore the importance of amino acid limitation for coexistence, we used the model to investigate the influence of Smr’s growth rate and amino acid production rates. We hypothesized that these parameters are key for coexistence because they affect amino acid limitation. In our laboratory system, Smr grows more slowly than both E. coli strains (Fig. 2b), but using our model, we can explore the effect of increasing Smr’s growth rate. We increased Smr’s growth rate from 0.5 to 1.5. To test for coexistence, we started Em rare (10%) and tracked its change in frequency—an increase in frequency would indicate coexistence, while a decrease would indicate competitive exclusion by the faster-growing Er. When Smr’s growth rate is lower than 0.96, Em increases in frequency, and the two E. coli strains coexist (Fig. 4a). However, when Smr’s growth rate is greater than 0.96, Em decreases in frequency and Er takes over. Under these conditions, methionine and arginine are never limiting (compare Fig. 4a inset plots). This means that both E. coli strains grow at their maximum growth rates (µEm and µEr) until lactose is depleted, and the strain with the faster growth rate, Er, takes over (µEr > µEm, see Fig. 2b). Smr’s amino acid production rates also affect coexistence. We measured whether Em is able to increase in frequency from rare across a range of arginine production rates, keeping the methionine production rate fixed at 1 and Smr’s growth rate at 0.5. When Smr grows more slowly but produces arginine at a rate four times faster than methionine, Em is not able to invade from rare (Fig. 4b). This is because Er is no longer arginine-limited, and it has a faster maximum growth rate than Em (amino acid dynamics are similar to inset plots in Fig. 4a). In sum, these results suggest that coexistence via amino acid limitation can be created either by a low Smr growth rate or low amino acid production rates.
Another model parameter that we hypothesized could affect amino acid limitation is the rate at which the E. coli strains deplete their amino acids (Supplementary Fig. 11). To test for coexistence, we started Em rare (10%) and tracked its change in frequency under different amino acid depletion rates. We found that Er competitively excludes Em when Em consumes methionine rapidly, at nine times the rate at which Er consumes arginine (Supplementary Fig. 11a). Coexistence is lost because methionine becomes limiting for Em, and Er is able to grow faster. Coexistence is also lost when Er’s arginine depletion rate is low (around 25% of the default rate; Supplementary Fig. 11b, c). At low arginine depletion rates, both amino acids are abundant throughout growth, and Er is able to grow more quickly and outcompete Em (µEr > µEm, see Fig. 2b). These results support the conclusion that amino acid limitation for the initially common E. coli strain is necessary for coexistence. When amino acids are either limiting for both strains or abundant for both strains, coexistence is lost and Er takes over due to its faster growth rate.
Next, we used the model to explore coexistence in a scenario in which the E. coli strains deplete both amino acids. In our laboratory system, it is possible that Em depletes arginine and that Er depletes methionine at low rates. We again started Em rare and tracked its change in frequency under different depletion rates of the other E. coli strain’s required amino acid. We found that depletion of arginine by Em has no effect on coexistence (Supplementary Fig. 12a), presumably because arginine only becomes more limiting for Er at early timepoints. However, if Er depletes methionine at high rates (e.g., at 90% of the rate at which Em depletes methionine), Em is unable to invade and Er takes over due to its faster maximum growth rate (Supplementary Fig. 12b). If both strains are able to deplete the other strain’s amino acid, the two effects cancel out and coexistence is always possible, except when both strains deplete the other amino acid at the same per capita rate at which the auxotroph depletes that amino acid (Supplementary Fig. 12c). In that scenario, Er takes over due to its faster maximum growth rate.
We explored complete overlap in amino acid consumption by creating a model in which both E. coli strains require and consume the same amino acid and S. enterica only produces this single amino acid (Supplementary Fig. 13a). In this situation, the two E. coli strains compete both for lactose and for the amino acid, and the slower-growing E. coli strain is outcompeted by the faster-growing strain, even if S. enterica’s growth rate is low (Supplementary Fig. 13b–d). Consistent with previous simulations, we kept the Monod constants for lactose (e.g., kEm lcts) and amino acid equal for both E. coli strains. As shown elsewhere, unequal Monod constants can allow two competitors to coexist when competing for two essential nutrients20. However, in a system like ours where competitors are limited by equivalent resource concentrations, coexistence is not possible with the complete overlap in benefits provided by the shared mutualist.
Finally, we wondered whether frequency-dependent amino acid limitation could promote coexistence in more complex communities. We added a third E. coli amino acid auxotroph (“Ex,” auxotrophic for a hypothetical amino acid “x”) into our model and added production of this amino acid by S. enterica (“Smrx”) (Fig. 5a and Supplementary Table 2). We set Ex’s growth rate slightly lower than Em’s, and again assessed coexistence by starting each E. coli strain rare and tracking whether it could increase in frequency. When Smrx grows more slowly than the E. coli strains, all three E. coli strains coexist (Fig. 5b). However, when Smrx grows faster, the E. coli strain with the highest growth rate, Er, outcompetes the other E. coli strains (Fig. 5c). The mechanism of coexistence is the same as above, where the amino acid consumed by the initially rare E. coli strain(s) is abundant, allowing it to grow at its maximum growth rate, while the initially common strain(s) is limited by its amino acid (Supplementary Fig. 14).
Discussion
In communities of multiple mutualists, competition between species within a partner guild can affect the coexistence and maintenance of diversity11,12. We explored the impact of resource competition between partner species that interact with a shared mutualist on coexistence and stability. Laboratory results showed that two E. coli partner mutualist strains that receive different amino acids from a S. enterica shared mutualist can coexist, despite the fact that one E. coli strain is a better competitor for lactose, the resource that ultimately limits growth. Modeling indicated that stability is possible when the E. coli strains are temporarily limited by different resources. While lactose sets the total E. coli carrying capacity—growth ceases when lactose is exhausted—the availability of amino acids during growth determines the instantaneous growth rate of each E. coli strain. When one E. coli strain begins rare, its amino acid is always abundant, so its instantaneous growth rate is faster and it consumes lactose quickly. In contrast, the initially common E. coli strain is amino acid-limited at early timepoints and grows more slowly than the rare strain, which allows the initially rare E. coli strain to increase in frequency. The community is therefore stable through negative-frequency dependence. We found that three key parameters affect the potential for coexistence via temporary amino acid limitation. Coexistence is not possible if S. enterica’s growth rate is high, if S. enterica’s production rate of the initially common E. coli’s amino acid is high, or if the initially common E. coli strain depletes its amino acid at a low rate. In these situations, the initially common E. coli strain is never limited by its amino acid, and the stronger competitor excludes the weaker. In summary, coexistence requires temporary amino acid limitation for one partner strain.
This mechanism of stability is related to classical ideas in ecology about niche partitioning21,22. Theoretical work predicts that multiple species typically do not coexist if they are limited by the same resource13,20 (though see Lobry et al.14). However, if the species are limited by different resources, they can more easily coexist23,24. In our system, the carrying capacity of the E. coli strains is ultimately limited by lactose. However, during growth, the limiting resources are temporarily “partitioned.” One strain’s instantaneous growth rate is limited by its amino acid, while the other achieves its maximum growth rate due to an abundance of lactose and its amino acid. An interesting element of our system is that a biotic factor creates the potential for temporary niche partitioning, rather than an aspect of the environment. The shared mutualist, S. enterica, causes the two-partner species’ instantaneous growth rates to be determined by different resources early on in growth. In addition, the shared mutualist creates the potential for niche partitioning by providing two different resources for the partner strains. Coexistence is not possible if both partner strains receive the same resource from the shared mutualist (Supplementary Fig. 13).
Recent work has explored the importance of competition between partner species in multiple mutualist communities. Several empirical studies have documented competition between species within a partner guild for access to the shared mutualist. For example, flowering plants compete for pollinator services25, and multiple species of plant-defending ants compete for nesting sites on host acacia plants26. In these cases, partner species may also compete for resources that are external to the mutualism. For example, in the ant–plant systems, plants may compete with one another for water and nutrients, and ants for prey12. Johnson and Bronstein12 took a mathematical approach to examine the coexistence of two-partner mutualists that compete for both a host-provided resource and an external resource. They determined that coexistence requires that one partner is limited by the host-provided resource and the other by the external resource (i.e., niche partitioning). Together with this study, our results suggest that understanding the stability of multiple mutualist systems requires consideration of competition for external resources in addition to competition for access to the shared mutualist. We show that even when both competing partners are ultimately limited by a resource external to the mutualism, coexistence can be maintained through temporary niche partitioning. Our work also identifies the importance of the shared mutualist providing different resources to members of the partner mutualist guild.
Microbial communities are often observed to include many cross-feeding species that exchange metabolites27,28,29. An open question in microbial ecology is why natural communities appear to contain several ecologically similar species that consume the same resources and carry out the same functions29,30. Our work suggests that these communities may be stable despite the potential for competition between strains that provide redundant functions (in our case, the conversion of lactose to acetate). We also showed that temporary limitation by different resources allows for the coexistence of three partner strains (Fig. 5b), and this mechanism may extend to the coexistence of many partner strains. However, there is likely a limit to the number of metabolites that a single shared mutualist can secrete and therefore an upper limit to the system complexity. Other factors that are likely to influence the stability of cross-feeding systems include spatial structure and evolution. In general, the spatial structure promotes diversity31, though structure can also lead to a loss of strains32. Evolution can lead to rapid changes in cross-feeding33,34. The evolution of specialists that only interact with a subset of competing partners may decrease the diversity of the system. This will be explored in future work. Finally, our mechanism of coexistence relies on the dynamics created by a batch or seasonal culture regime. However, analytical analysis of a chemostat model of our system indicates that coexistence is also possible in continuous culture, through co-limitation by both amino acids and lactose (Supplementary Note 1).
The results presented here improve our understanding of the ecology of multiple mutualist communities, expanding our knowledge of mutualisms beyond pairwise interactions. Ecological stability is critical for the maintenance of biodiversity. Within mutualistic communities, the coexistence of many species within a partner mutualist guild creates functional redundancy, which is important in the face of disturbances because redundancy can protect mutualistic communities from collapse5,35. Knowledge of ways to preserve functional redundancy can aid efforts to design stable microbial communities for applications in health and industry36.
Methods
Strains and media
We used two Escherichia coli K12 strains, both derived from the Keio collection37. The methionine auxotroph (“Em”) has a ΔmetB mutation, and the arginine auxotroph (“Er”) has a ΔargA mutation. LacZ was added to both strains using conjugation for Em, and phage transduction for Er38. Em has a cyan fluorescent protein inserted in the lambda attachment site. We also used a Salmonella enterica serovar Typhimurium LT2 strain that secretes methionine and arginine (“Smr”). This strain was derived from a strain containing mutations in metA and metJ that cause overproduction of methionine15,39,40. We selected for arginine production by coculturing this strain with the E. coli arginine auxotroph as a lawn on lactose minimal media plates containing x-gal (0.05% v/v) for four 7-day growth cycles with 1:6.67 dilutions at each transfer41. The appearance of a blue colony suggested the evolution of arginine production in S. enterica, which we confirmed by isolating S. enterica from the colony on citrate minimal media plates and cross-streaking with Er. We sequenced this strain using Illumina NextSeq and identified mutations using breseq42. We found a T → A point mutation in argG at position 3459818 (reference strain NC_003197).
In coculture or three-strain cultures, strains were grown in a modified Hypho minimal medium with lactose as the carbon source, containing 2.78 mM lactose, 14.5 mM K2HPO4, 16.3 mM NaH2PO4, 0.814 mM MgSO4, 3.78 mM Na2SO4, 3.78 mM [NH4]2SO4, and trace metals (1.2 µM ZnSO4, 1 µM MnCl2, 18 µM FeSO4, 2 µM (NH4)6Mo7O24, 1 uM CuSO4, 2 mM CoCl2, 0.33 µm Na2WO4, 20 µM CaCl2). Monocultures and cocultures of Em and Er were grown in this medium with 250 µM of methionine and 250 µM of arginine added, concentrations that we found to be unlimiting (i.e., growth ceased when lactose was depleted, rather than the amino acids; Supplementary Fig. 1). Smr’s growth rate in monoculture was assessed in Hypho minimal medium with 12 mM acetate rather than lactose, a concentration that approximates the total amount of acetate produced by the E. coli strains.
To measure final yields as colony-forming units (CFU/ml), cultures were diluted in saline (0.85% NaCl) and plated on selective Hypho minimal media plates with 1% agar. Plates for the E. coli strains contained 2.78 mM lactose and 100 µM of methionine for Em, or 100 µM of arginine for Er. Smr was plated on Hypho plates containing 3.4 mM sodium citrate instead of lactose. All plates contained 0.05% v/v x-gal, which makes E. coli colonies blue. We counted the dilution plates that had between 30 and 300 colonies.
Growth assays
All experiments were performed in 96-well plates with 200 µl of media per well, inoculated with a 1:200 dilution of log-phase monocultures (1 µl of each strain). We measured OD600 in a Tecan InfinitePro 200 plate reader at 30 °C, shaking at 432 rpm between readings, which were taken every 20 min. Growth rate estimates were calculated by fitting growth curves to a Baranyi function43 by obtaining nonlinear least-square estimates and using the growth rate parameter estimate. For all experiments (monocultures, cocultures, and mutual invasibility experiments), we performed three biological replicates, except for Smr monocultures, where we performed six biological replicates. All measurements were taken from distinct samples.
Mutual invasibility experiments
The ability of each E. coli strain to increase in frequency from rare was our criterion for coexistence17,18. To measure whether invasion from rare occurred, we set up cultures with different starting frequencies and tracked their changes over one growth cycle. We performed several batches of these experiments on different weeks, with three biological replicates per batch. The initial Smr density was kept constant (9.8e5 CFU/ml for batch A, 3.7e5 CFU/ml for batch B), and the E. coli total density was kept constant (1.6e6 CFU/ml ± 5.4e5 (SD) for batch A,_1.7e6 CFU/ml ± 5.3e5 (SD) for batch B, 3.6e6 ± 6.7e5 (SD) for batch C) but the frequency of each strain differed across a range of frequencies—0.024, 0.320, and 0.899 Em/(Em + Er) for batch A, 0.006, 0.393, and 0.985 Em/(Em + Er) for batch B, and 0.08 for batch C. (Note that batch C was only performed in lactose + methionine + arginine media with no Smr present.) After growth, the cultures were diluted and plated on strain-specific plates to measure yields as CFU/ml (media described above). The change in Em frequency was calculated as [Em/(Em + Er)]final – [Em/(Er + Er)]initial.
Ecological modeling
The ecological model is shown in “Results” and Supplementary Table 1. The ODE system was solved using the deSolve package in R, which used the lsoda solver to numerically integrate. All simulations were solved for sufficient duration to ensure dynamics had ceased. During integration, relative tolerance (rtol) was set to 1e-13 and maxsteps to 1e5.
Analysis and statistics
Modeling, data visualization, and statistical analyses were done in R version 3.6.0. Monoculture growth rates were compared using a one‐way analysis of variance (ANOVA) and post hoc Tukey HSD tests, with α = 0.05. The coculture growth rates and mutual invasibility experiments were analyzed using Welch’s two-sided two-sample t test, which is designed for unequal sample distribution variance and assumes normality, with α = 0.05. We used the R package ggtern to make the ternary plots in Fig. 5.
Reporting summary
Further information on research design is available in the Nature Research Reporting Summary linked to this article.
Data availability
All data generated and/or analyzed in this study are provided in the Source Data file and are also available in the Zenodo repository at https://doi.org/10.5281/zenodo.432179744. Source data are provided with this paper.
Code availability
Code for the ecological model is available in the Zenodo repository at https://doi.org/10.5281/zenodo.432179744. Code for data analysis is available upon reasonable request.
References
Bruno, J. F., Stachowicz, J. J. & Bertness, M. D. Inclusion of facilitation into ecological theory. Trends Ecol. Evol. 18, 119–125 (2003).
Bronstein, J. L. Mutualism (Oxford University Press, 2015).
Stanton, M. L. Interacting guilds: moving beyond the pairwise perspective on mutualisms. Am. Nat. 162, S10–S23 (2003).
Bascompte, J., Jordano, P., Melian, C. J. & Olesen, J. M. The nested assembly of plant-animal mutualistic networks. Proc. Natl Acad. Sci. USA 100, 9383–9387 (2003).
Waser, N. M., Chittka, L., Price, M. V., Williams, N. M. & Ollerton, J. Generalization in pollination systems, and why it matters. Ecology 77, 1043–1060 (1996).
Knowlton, N. & Rohwer, F. Multispecies microbial mutualisms on coral reefs: the host as a habitat. Am. Nat. 162, S51–S62 (2003).
Hoeksema, J. D. & Bruna, E. M. Pursuing the big questions about interspecific mutualism: a review of theoretical approaches. Oecologia 125, 321–330 (2000).
Afkhami, M. E., Rudgers, J. A. & Stachowicz, J. J. Multiple mutualist effects: conflict and synergy in multispecies mutualisms. Ecology 95, 833–844 (2014).
Denison, R. F. & Kiers, E. T. Life histories of symbiotic rhizobia and mycorrhizal fungi. Curr. Biol. 21, 775–785 (2011).
Jones, E. I., Bronstein, J. L. & Ferrière, R. The fundamental role of competition in the ecology and evolution of mutualisms: competition and mutualism. Ann. N. Y. Acad. Sci. 1256, 66–88 (2012).
Palmer, T. M., Stanton, M. L. & Young, T. P. Competition and coexistence: exploring mechanisms that restrict and maintain diversity within mutualist guilds. Am. Nat. 162, S63–S79 (2003).
Johnson, C. A. & Bronstein, J. L. Coexistence and competitive exclusion in mutualism. Ecology 100, e02708 (2019).
Hardin, G. The competitive exclusion principle. Science 131, 1292–1297 (1960).
Lobry, C., Mazenc, F. & Rapaport, A. Persistence in ecological models of competition for a single resource. Comptes Rendus Math. 340, 199–204 (2005).
Harcombe, W. Novel cooperation experimentally evolved between species. Evolution 64, 2166–2172 (2010).
Vasi, F., Travisano, M. & Lenski, R. E. Long-term experimental evolution in Escherichia coli. II. Changes in life-history traits during adaptation to a seasonal environment. Am. Nat. 144, 432–456 (1994).
Chesson, P. Mechanisms of maintenance of species diversity. Annu. Rev. Ecol. Syst. 31, 343–366 (2000).
Wright, E. S. & Vetsigian, K. H. Inhibitory interactions promote frequent bistability among competing bacteria. Nat. Commun. 7, 1–7 (2016).
Hammarlund, S. P., Chacón, J. M. & Harcombe, W. R. A shared limiting resource leads to competitive exclusion in a cross-feeding system: role of environment for cross-feeder coexistence. Environ. Microbiol. 21, 759–771 (2019).
Tilman, D. Resource competition between plankton algae: an experimental and theoretical approach. Ecology 58, 338–348 (1977).
MacArthur, R. & Levins, R. The limiting similarity, convergence, and divergence of coexisting species. Am. Nat. 101, 377–385 (1967).
Schoener, T. W. Resource partitioning in ecological communities. Science 185, 27–39 (1974).
Tilman, D. Resources: a graphical-mechanistic approach to competition and predation. Am. Nat. 116, 362–393 (1980).
Tilman, D. Resource Competition and Community Structure (Princeton University Press, 1982).
Mitchell, R. J., Flanagan, R. J., Brown, B. J., Waser, N. M. & Karron, J. D. New frontiers in competition for pollination. Ann. Bot. 103, 1403–1413 (2009).
Palmer, T. M. et al. A role for indirect facilitation in maintaining diversity in a guild of African acacia ants. Ecology 94, 1531–1539 (2013).
Morris, J. J., Lenski, R. E. & Zinser, E. R. The black queen hypothesis: evolution of dependencies through adaptive gene loss. mBio 3, e00036–12 (2012).
Mee, M. T., Collins, J. J., Church, G. M. & Wang, H. H. Syntrophic exchange in synthetic microbial communities. Proc. Natl Acad. Sci. USA 111, E2149–E2156 (2014).
Goldford, J. E. et al. Emergent simplicity in microbial community assembly. Science 361, 469–474 (2018).
Estrela, S. et al. Metabolic rules of microbial community assembly. Preprint at bioRxiv https://doi.org/10.1101/2020.03.09.984278 (2020).
Amarasekare, P. Competitive coexistence in spatially structured environments: a synthesis: Spatial coexistence mechanisms. Ecol. Lett. 6, 1109–1122 (2003).
Saxer, G., Doebeli, M. & Travisano, M. Spatial structure leads to ecological breakdown and loss of diversity. Proc. R. Soc. B Biol. Sci. 276, 2065–2070 (2009).
Harcombe, W. R., Chacón, J. M., Adamowicz, E. M., Chubiz, L. M. & Marx, C. J. Evolution of bidirectional costly mutualism from byproduct consumption. Proc. Natl Acad. Sci. USA 115, 12000–12004 (2018).
Waite, A. J. & Shou, W. Adaptation to a new environment allows cooperators to purge cheaters stochastically. Proc. Natl Acad. Sci. USA 109, 19079–19086 (2012).
Memmott, J., Waser, N. M. & Price, M. V. Tolerance of pollination networks to species extinctions. Proc. R. Soc. Lond. B Biol. Sci. 271, 2605–2611 (2004).
Lawson, C. E. et al. Common principles and best practices for engineering microbiomes. Nat. Rev. Microbiol. 17, 725–741 (2019).
Baba, T. et al. Construction of Escherichia coli K‐12 in‐frame, single‐gene knockout mutants: the Keio collection. Mol. Syst. Biol. 2, 2006.0008 (2006).
Bernstein, H. C. & Carlson, R. P. Design, construction, and characterization methodologies for synthetic microbial consortia. in Engineering and Analyzing Multicellular Systems (eds Sun, L. & Shou, W.) Vol. 1151, 49–68 (Springer New York, 2014).
Douglas, S. M., Chubiz, L. M., Harcombe, W. R., Ytreberg, F. M. & Marx, C. J. Parallel mutations result in a wide range of cooperation and community consequences in a two-species bacterial consortium. PLoS ONE 11, e0161837 (2016).
Douglas, S. M., Chubiz, L. M., Harcombe, W. R. & Marx, C. J. Identification of the potentiating mutations and synergistic epistasis that enabled the evolution of inter-species cooperation. PLoS ONE 12, e0174345 (2017).
Chubiz, L., Douglas, S. & Harcombe, W. Combining Engineering and Evolution to Create Novel Metabolic Mutualisms Between Species. in Engineering and Analyzing Multicellular Systems: Methods and Protocols (eds Sun, L. & Shou, W.) 39–47 (Springer, 2014).
Deatherage, D. E. & Barrick, J. E. Identification of Mutations in Laboratory-Evolved Microbes from Next-Generation Sequencing Data Using breseq. in Engineering and Analyzing Multicellular Systems (eds Sun, L. & Shou, W.) Vol. 1151, 165–188 (Springer New York, 2014).
Baranyi, J. & Roberts, T. A. A dynamic approach to predicting bacterial growth in food. Int. J. Food Microbiol. 23, 277–294 (1994).
Hammarlund, S. P., Gedeon, T., Carlson, R. P. & Harcombe, W. R. Data and Code for ‘Limitation by a shared mutualist promotes coexistence of multiple competing partners’ (Version v1) [Data set]. Zenodo https://doi.org/10.5281/zenodo.4321797 (2020).
Acknowledgements
We thank Lisa Fazzino, Ben Holte, and Alejandro Behling for assistance with preliminary experiments, Jeremy Chacón for help with modeling, and Brian Smith, Leno Smith, and Jonathan Martinson for providing comments on the manuscript. This work was supported by the National Institutes of Health (1R01-GM121498 to W.R.H. and U01EB019416 to R.P.C.), and by a National Science Foundation Graduate Research Fellowship for S.P.H.
Author information
Authors and Affiliations
Contributions
S.P.H. conceived the study, collected and analyzed the data, and prepared the paper. W.H. helped design the experiments, oversaw data analysis, supplied materials, and assisted with the paper preparation. T.G. analyzed the chemostat model and provided comments on the paper. R.C. constructed the Er strain, provided ideas for additional modeling experiments, and provided comments on the paper.
Corresponding author
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Peer review information Nature Communications thanks Jeff Gore, Maria Rebolleda-Gomez and the other, anonymous, reviewer(s) for their contribution to the peer review of this work. Peer reviewer reports are available.
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary information
Source data
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Hammarlund, S.P., Gedeon, T., Carlson, R.P. et al. Limitation by a shared mutualist promotes coexistence of multiple competing partners. Nat Commun 12, 619 (2021). https://doi.org/10.1038/s41467-021-20922-0
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41467-021-20922-0
- Springer Nature Limited
This article is cited by
-
Resource competition predicts assembly of gut bacterial communities in vitro
Nature Microbiology (2024)
-
Bacteriophage-mediated lysis supports robust growth of amino acid auxotrophs
The ISME Journal (2023)
-
Seasonal niche differentiation among closely related marine bacteria
The ISME Journal (2022)