3.1. Environmental source and host fitness advantage can compensate for imperfect vertical transmission

To understand the forces that sustain the host–mutualist association, we investigate the conditions under which the mutualist can persist in the population despite imperfect vertical transmission. By doing this we investigate how steps in the transmission process can compensate for deficiencies in other steps. We have derived three steady states of the system (Equations 1–4 and Figure 1) and analysed their stability conditions (Table 2). The stability of the steady states depends on two threshold levels of leakiness in vertical transmission, λ. The lower and the upper thresholds are

$$T_1 = \displaystyle{{\beta \gamma + cs} \over {c( {1 + s} ) }}-\displaystyle{{\beta \gamma + cs} \over {\gamma ( {1 + s} ) }}, \;$$

and

$$T_2 = \displaystyle{{\beta \gamma + sc} \over {c( {1 + s} ) }}$$

respectively. In equilibrium 1, the other bacteria in the environment that compete with the mutualist are absent (E _o = 0, E _m = 1). In equilibrium 2, both types of microbiota and bacteria in the environment are present (the interior equilibrium). In equilibrium 3, the mutualists from both the population and the environment are absent (M = 0, E _m = 0).

Table 2. Non-negative equilibria of the basic model and the corresponding conditions for stability

*Here we define $R = \sqrt {{( {\beta -s + \lambda ( {1 + s} ) } ) }^2 + 4\beta s}$.

We summarise the equilibria and their corresponding stability conditions (necessary and sufficient) in Table 2. The full mathematical analysis can be found in the Supplementary Material 1.1.

To visualise the relationships among the three equilibria, we plot the steady states of the model as functions of λ (Figure 3a). The stable interior equilibrium (equilibrium 2, in which a proportion of the population carries the mutualist) occurs when λ lies between the two thresholds T ₁ and T ₂ (dotted black lines in Figure 3a), and the mutualist is extinct when λ is greater thanT ₂. This is also shown in the longitudinal dynamics (Figure S1 in the Supplementary Material).

Figure 3. Dynamics of equilibria and threshold values in a culturally homogeneous population (the basic model) obtained by solving Equations (1)–(4). (a) The proportion of microbiota types at equilibria against λ (the leakiness of microbial vertical transmission), from numerical solutions. An estimate of the equilibrium is obtained when the difference between two consecutive iterations is smaller than an error of 1 × 10⁻⁵. The leakiness decreases the proportion of the mutualist in the population M ⁺ and the environment E _m. The black dotted lines represent the lower and upper thresholds (T ₁ and T ₂), as labelled. (b) and (c) The thresholds of λ shift the equilibria of the basic model as a function of β and s (Table 2). Unless indicated otherwise, the parameters are set at γ = 0.15, β = 0.1, s = 0.1 and c = 0.1.

We consider the effect of the fitness cost c to the mutualist in the environment on the stability of these states by observing that T ₁ = T ₂(1 − c/γ). As T ₂ is always positive, T ₁is always smaller than T ₂ (Table 2). The sign of T ₁ depends on whether the fitness cost c is larger than the rate of microbial shedding by the host, γ. If the mutualist shedding (to the environment) is higher than the cost of the mutualist in the environment, i.e. 0 < c < γ, then T ₁ > 0. If 0 < βγ < c ≤ γ then T ₁ > 0 and T ₂ < 1. Therefore, the condition for a stable interior equilibrium is T ₁ < λ < T ₂. As the value of λ increases from 0 to 1 it passes through T ₁ and T ₂, and the stable equilibrium shifts from equilibrium 1 to equilibrium 2, and finally to equilibrium 3 (extinction of the mutualist), as shown in Figure 3. Sufficiently leaky vertical transmission leads to the extinction of the mutualist in the population and the environment (equilibrium 3). Nevertheless, a degree of leakiness is tolerated for some parameter combinations which allow part of the population to carry the mutualist (equilibria 1 and 2); in Figure 3a where λ < T ₂, the mutualist is able to persist in the population (solid green line).

Extinction of the mutualist can be prevented if the rates of microbial shedding and acquisition from the environment are high enough. When the product of shedding and acquisition is higher than the cost (i.e. c < βγ < γ), we get T ₂ > 1. Because λ is smaller than 1, by definition, λ is always smaller than T ₂. In this case, equilibrium 3 (E _m = 0) does not exist, and therefore the mutualist persists. That is, some of the individuals in the population still carry the mutualist despite highly unfaithful vertical transmission. To illustrate the effect of microbe acquisition from the environment on the steady states of the system we plot the thresholds T ₁ and T ₂ as functions of the acquisition rate β and s (Figure 3b and c). As β increases, T ₂ exceeds 1 (dashed line in panel b); extinction of the mutualist is prevented.

A positive fitness advantage allows the mutualist to persist in a population with some degree of leakiness λ even without acquisition or shedding. Both thresholds increase with the fitness benefit s of hosts with the mutualist as illustrated in Figure 3c. When the value of the fitness benefit s is small, the upper threshold is sensitive to changes in its value (Figure 3c). Hence, a slight increase in the fitness of the mutualist-carrying host allows the persistence of the mutualist to have a much higher tolerance for unfaithful vertical transmission.

However, as the fitness benefit s approaches infinity, T ₂ (Table 2) approaches 1. If the microbial shedding and acquisition are low compared with the fitness cost (βγ < c), an increase in host fitness increases the value of T ₂ while T ₂ is always smaller than 1. That is, an increase in host fitness allows the system to tolerate more leaky vertical transmission, but it will not prevent the eventual loss of the mutualist as leakiness increases (Figure 3c).

Overall, T ₂ is linear with respect to βγ/c, which can be viewed as a measure of the ‘strength’ of horizontal transmission, and it is the balance of these parameters that can sustain the presence of the mutualist even under extremely leaky conditions. In the following section we identify a generalisation of the T ₂ threshold that accounts for cultural factors and explore its dependence on other parameters.

3.2. Cultural factors can help the mutualist persist

In the extended model, we introduce the transmission of a cultural practice that affects the rate of acquisition of the mutualist. An example of the dynamics over time is shown in Figure S2 (Supplementary Material). We are interested in how cultural factors may affect the conditions under which the mutualist can enter the host population and persist. Thus, we investigate a boundary at which the mutualist is absent in the host population. From Equations 11 and 12, when E _o ≠ 0, we have E _m = γ(M _x + M _y)/c. At the mutualist-free boundaries, $M_y^{\prime} = M_y = 0$ (Equation 7) and $M_x^{\prime} = M_x = 0$ (Equation 9); the mutualist proportion in the environment E _m then goes to zero. The resulting steady states and the conditions for stability are summarised in Table 3. The full mathematical analysis can be found in Supplementary Material 1.2.

Table 3. Non-negative equilibria and stability conditions at the mutualist-free boundaries. The mutualists are excluded at these equilibria ($\widehat{{M_y}} = \widehat{{M_x}} = \widehat{{E_m}} = 0$)

The cultural transmission model allows the adoption and abandonment of the cultural practice across generations. When the rate of abandonment is higher than the rate of adoption (δ > k), the system stabilises at equilibrium 1 where the cultural practice is excluded from the population (Table 3). A special case of this model where only one type of host (in the absence of the practice) exists at equilibrium (therefore no cultural factors) reduces to the basic model (Equations 1–4). Thus, the stability of equilibrium 1 depends on the upper threshold T ₂ of λ in the same manner as for the basic model (Table 2 and 3).

When the rate of adoption is higher than the rate of abandonment (k > δ), the system stabilises at equilibrium 2; a fraction of the population has the cultural practice. This proportion is determined by the ratio of the adoption and abandonment rate (Table 3). The stability of equilibrium 2 requires the leakiness of vertical transmission λ to be higher than a threshold $\tilde{\lambda } = T_2 + \alpha \beta \gamma ( {1-\delta {\rm /}k} ) {\rm /}( {cs + c} )$. Therefore, increasing α (elevation in the rate of mutualist acquisition from the environment) and k (cultural transmission rate parameter) increases the value of λ above which the mutualist will go extinct (Table 3).

Since k > δ is one of the conditions for stability, a stable equilibrium 2 ensures that the threshold leakiness is always greater than T ₂, as long as α is positive. Hence, transmission of a cultural factor that elevates microbial acquisition improves the ability of a mutualist to persist under leaky vertical transmission. On the other hand, a cultural practice that suppresses the acquisition of the mutualist (negative α) results in a threshold smaller than the basic model, which makes the mutualist more likely to go extinct owing to leaky vertical transmission. In Figure 4 we verify this threshold against the equilibria of the system computed with numerical solutions of Equations 7–12 across a range of λ values. As in the basic model, increasing the leakiness of vertical transmission λ decreases the proportion of mutualist carriers in the population (M _y and M _x).

Figure 4. The proportion of microbiota types at equilibrium against λ (the leakiness of microbial vertical transmission) for the extended model with cultural practice. The curves show equilibria obtained numerically by solving Equations (7)–(12) using γ = 0.15, λ = 0.1, β = 0.1, s = 0.1, c = 0.1, α = k = 0.1 and δ = 0.02. An estimate of the equilibrium is obtained when the difference between two consecutive iterations is smaller than an error of 1 × 10⁻⁵. Increasing leakiness of vertical transmission reduces the proportion of the mutualist in the population and the environment. The black dotted line represents the threshold $\tilde{\lambda } = T_2 + \alpha \beta \gamma ( {1-\delta {\rm /}k} ) {\rm /}( {cs + c} )$.

In Figure 5 we explore the behaviour of the threshold $\tilde{\lambda }$ as a function of the equilibrium frequency of hosts with the cultural practice $\widehat{{N_y}}$, and the fitness benefit of the microbe to the hosts. As the benefit to the host increases, the threshold above which the mutualist is excluded increases. As the equilibrium frequency of the cultural practice increases, the threshold increases linearly. The host–microbe association is able to tolerate greater leakiness in vertical transmission when the rate of adoption of the cultural trait k is greater than the rate of abandonment δ. The figure also shows that the threshold increases as a function of the compound parameter βγ/c which reflects the strength of horizontal transmission. Although not shown in the figure, the threshold leakiness also increases linearly with the elevated rate of acquisition from the environment owing to the cultural practice α.

Figure 5. Heatmap of threshold leakiness $\tilde{\lambda } = T_2 + \alpha \beta \gamma ( {1-\delta {\rm /}k} ) {\rm /}( {cs + c} )$ as a function of the equilibrium frequency of hosts with the cultural practice, $\widehat{{N_y}} = 1-\delta {\rm /}k$ and benefit to the host s for three values of the strength of horizontal transmission βγ/c. The threshold leakiness $\tilde{\lambda }$ is the value of λ above which the mutualist will go extinct. The green lines are contours of the threshold at the values given in the labels. In all three heatmaps α = 0.1.

The holobiont concept requires microbiota to be transmitted vertically with high fidelity (Rosenberg & Zilber-Rosenberg, Reference Rosenberg and Zilber-Rosenberg2016; Skillings, Reference Skillings2016). To study the dynamics of the mutualist in the context of holobionts, we investigate a special case of the model where vertical transmission is perfect. We solve the system (Equations 7–12) with λ = 0. The positive equilibria and corresponding conditions for stability are summarised in Table S1 (Supplementary Material). Under perfect vertical transmission, all individuals carry the mutualist because the two equilibria without the mutualist are both unstable, and some fraction of hosts have the cultural practice. The proportion of individuals with the cultural practice is an increasing function of the ratio of adoption and abandonment rates, k/δ (Table S1 in the Supplementary Material). The persistence of the mutualist under perfect vertical transmission is verified by our numerical solutions where microbiota without the mutualist M ⁻ are eliminated under perfect vertical transmission λ = 0 (Figure 4). Therefore, perfect vertical transmission guarantees the presence of the mutualist at the individual level. However, as shown above, mutualists can persist in a population in the long run without this strict requirement.

The basic model (Equations 1–4) is a boundary of this extended model in which the individuals with the cultural practice are absent (M _y = N _y = 0). We can therefore use this model to consider a new cultural practice that appears in a population. A cultural practice can spread in the population if the rate of adoption is positive and greater than the rate of abandonment (Table 3 and Table S1 in the Supplementary Material). Interestingly, this criterion is independent of any properties of the mutualist, reflecting the fact that the cultural practice is itself selectively neutral.