Cross-feeding yields high-dimensional chaos and coexistence of species beyond exclusion principle

TL;DR

This study models microbial communities with cross-feeding interactions, revealing that high-dimensional chaos enables coexistence of many species beyond traditional limits, which may explain microbial diversity.

Contribution

It demonstrates that high-dimensional chaotic dynamics can stabilize coexistence of numerous species beyond the competitive exclusion principle in microbial communities.

Findings

High-dimensional chaos allows many species to coexist beyond traditional limits.

Chemical and population dynamics explore high-dimensional space with intermittent switching.

High-dimensional chaos is common when uptake chemicals outnumber leaked chemicals.

Abstract

Species interactions through cross-feeding via leakage and uptake of chemicals are important in microbial communities, and play an essential role in the coexistence of diverse species. Here, we study a simple dynamical model of a microbial community in which species interact by competing for the uptake of common metabolites that are leaked by other species. The model includes coupled dynamics of species populations and chemical concentrations in the medium, allowing for a variety of uptake and leakage networks among species. Depending on the structure of these networks, the system exhibits different attractors, including fixed points, limit cycles, low-dimensional chaos, and high-dimensional chaos. In the fixed-point and limit-cycle cases, the number of coexisting species is bounded by the number of exchangeable chemicals, consistent with the well-known competitive exclusion principle. In contrast, in the low-dimensional chaotic regime, the number of coexisting species exhibits noticeable but limited excess over this limit. Remarkably, in the high-dimensional chaotic regime, a much larger number of species beyond this limit coexist persistently over time. In this case, the rank-abundance distribution is broader than exponential, as often observed in real ecosystems. The population dynamics displays intermittent switching among quasi-stationary states, while the chemical dynamics explore most of the high dimensions. We find that such high-dimensional chaos is ubiquitous when the number of uptake chemicals is moderately larger than the number of leaked chemicals. Our results identify high-dimensional chaos with intermittent switching as a generic dynamical mechanism that stabilizes coexistence in interacting systems. We discuss its relevance to sustaining diverse microbial communities with leak-uptake cross-feeding.