Competition–colonization trade-off

Ecological micro-succession and the competition-colonization trade-off in a bacterial meta-community on-chip. (A) sketch of a micron-scale structured bacterial environment based on microfluidics technology; (B) Fluorescent microscopy image of Escherichia coli (magenta) and Pseudomonas aeruginosa (green) inhabiting a device of the type depicted in A and which has been wettened with growth media and inoculated with both species; (C) a sequence of five snapshots of the bacterial community distributed over five patches (of an array with 85) depicting the spatial dynamics of competition between E. coli (magenta) and P. aeruginosa (green); (D) Representation of the succession pattern exhibited by the two bacterial species when competing for space and resources in a patchy environment.^[1]

In ecology, the competition–colonization trade-off is a stabilizing mechanism that has been proposed to explain species diversity in some biological systems, especially those that are not in equilibrium.^[2][3] In which case some species are particularly good at colonizing and others have well-established survival abilities.^[4] The concept of the competition-colonization trade-off was originally proposed by Levins and Culver, the model indicated that two species could coexist if one had impeccable competition skill and the other was excellent at colonizing.^[5] The model indicates that there is typically a trade-off, in which a species is typically better at either competing or colonizing. A later model, labelled The Lottery Model was also proposed, in which interspecific competition is accounted for within the population.

Mathematical models

Levins and Culver model

${\displaystyle {\frac {{\text{d}}p_{1}}{{\text{d}}t}}=c_{1}p_{1}(1-p_{1})-m_{1}p_{1}}$

${\displaystyle {\frac {{\text{d}}p_{2}}{{\text{d}}t}}=c_{2}p_{2}(1-p_{1}-p_{2})-m_{2}p_{2}-c_{1}p_{1}p_{2}}$

Where: ${\displaystyle p_{i}=}$ fraction of patches that are occupied by species ${\displaystyle i}$;

${\displaystyle c_{i}=}$ colonization rate of species ${\displaystyle i}$;

${\displaystyle m_{i}=}$ mortality rate of species ${\displaystyle i}$ (independent of patch density).

Species 1 = competitor, can colonize in area that is uninhabited or inhabited by species 2 ${\displaystyle (1-p_{1})}$.

Species 2 = colonizer, can only colonize in uninhabited areas ${\displaystyle (1-p_{1}-p_{2})}$.

Species 2 is subject to displacement by its competitor ${\displaystyle (-c_{1}p_{1}p_{2})}$.

If species 2 has a higher colonization rate it can coexist with species 1: ${\displaystyle c_{2}>{\frac {c_{1}(c_{1}+m_{2}-m_{1})}{m_{1}}}}$.

This model is described as the displacement competition model, it has been observed in marine mollusks and fungi. This model makes two large assumptions: 1. "a propagule of a superior competitor takes over a patch from an adult of the inferior competitor".^[6] 2. The adult must be displaced fast enough to ensure that it does not reproduce while it is being displaced.

Lottery model

${\displaystyle {\frac {{\text{d}}p_{1}}{{\text{d}}t}}=c_{1}{\frac {f}{f+p_{2}}}p_{1}(h-p_{1}-p_{2})m_{1}p_{1}}$

${\displaystyle {\frac {{\text{d}}p_{2}}{{\text{d}}t}}=c_{2}{\frac {g}{g+p_{1}}}p_{2}(h-p_{1}-p_{2})m_{2}p_{2}}$

Colonization rate is now described by interspecific competition.

${\displaystyle {\frac {f}{f+p_{2}}}}$ and ${\displaystyle {\frac {g}{g+p_{1}}}}$. Both f and g > 0.

An increase in p1 is related to a decrease in the colonization rate of species 2.

g < f implies a competitive advantage of species 1 and c2 > c1 implies a colonization advantage for species 2.

In plants

The competition-colonization trade-off theory has primarily been used to examine and describe the dispersal-linked traits of a plant's seeds.^[7] Seed size is a primary feature that relates to a species ability to colonize or compete within a given population, the effect of seed size was displayed in dicotyledonous annual plants.^[8] Turnbull and colleagues indicated that the competition/colonization trade-off has a stabilizing effect on the population of plants.

In algae

For example, in a classic study on an intertidal zone in Southern California,^[9] it was shown that when a boulder was overturned, it would quickly be colonized by green algae and barnacles (which were better colonizers). However, if left undisturbed, the boulders would eventually be overtaken by red algae (which was the stronger competitor in the long term).

In bacteria

It has been shown experimentally that in a two-species artificial metacommunity of motile strains on-chip, bacteria Escherichia coli is a fugitive species, whereas Pseudomonas aeruginosa is a slower colonizer but superior competitor. ^[10] The pattern of ecological succession driving dynamics of the metacommunity in a patchy habitat landscape is as follows: Starting with a pristine one-dimensional (array) archipelago of island habitats (patches) which is inoculated with E. coli and P. aeruginosa from opposite ends; locally E. coli colonizes first and later P. aeruginosa takes over while at the landscape scale E. coli persists as a fugitive species scrambling for patches.

See also

• Intermediate disturbance hypothesis

References

1. Wetherington MT, Nagy K, Dér L, Ábrahám Á, Noorlag J, Galajda P, Keymer JE (November 2022). "Ecological succession and the competition-colonization trade-off in microbial communities". BMC Biology. 20 (1): 262. doi:10.1186/s12915-022-01462-5. PMC 9710175. PMID 36447225.
2. Hastings A (December 1980). "Disturbance, coexistence, history, and competition for space". Theoretical Population Biology. 18 (3): 363–373. doi:10.1016/0040-5809(80)90059-3.
3. Cadotte MW (April 2007). "Competition-colonization trade-offs and disturbance effects at multiple scales". Ecology. 88 (4): 823–829. Bibcode:2007Ecol...88..823C. doi:10.1890/06-1117. PMID 17536699.
4. Calcagno V, Mouquet N, Jarne P, David P (August 2006). "Coexistence in a metacommunity: the competition-colonization trade-off is not dead". Ecology Letters. 9 (8): 897–907. Bibcode:2006EcolL...9..897C. doi:10.1111/j.1461-0248.2006.00930.x. PMID 16913929.
5. Levins R, Culver D (June 1971). "Regional Coexistence of Species and Competition between Rare Species". Proceedings of the National Academy of Sciences of the United States of America. 68 (6): 1246–1248. Bibcode:1971PNAS...68.1246L. doi:10.1073/pnas.68.6.1246. PMC 389163. PMID 16591932.
6. Yu DW, Wilson HB (July 2001). "The competition-colonization trade-off is dead; long live the competition-colonization trade-off". The American Naturalist. 158 (1): 49–63. doi:10.1086/320865. PMID 18707314. S2CID 12137882.
7. Cadotte MW, Mai DV, Jantz S, Collins MD, Keele M, Drake JA (November 2006). "On testing the competition-colonization trade-off in a multispecies assemblage". The American Naturalist. 168 (5): 704–709. doi:10.1086/508296. PMID 17080367. S2CID 22179221.
8. Turnbull LA, Coomes D, Hector A, Rees M (2004). "Seed mass and the competition/colonization trade-off: competitive interactions and spatial patterns in a guild of annual plants". Journal of Ecology. 92 (1): 97–109. Bibcode:2004JEcol..92...97T. doi:10.1111/j.1365-2745.2004.00856.x.
9. Sousa WP (December 1979). "Disturbance in Marine Intertidal Boulder Fields: The Nonequilibrium Maintenance of Species Diversity". Ecology. 60 (6): 1225–1239. Bibcode:1979Ecol...60.1225S. doi:10.2307/1936969. JSTOR 1936969.
10. Wetherington MT, Nagy K, Dér L, Ábrahám Á, Noorlag J, Galajda P, Keymer JE (November 2022). "Ecological succession and the competition-colonization trade-off in microbial communities". BMC Biology. 20 (1): 262. doi:10.1186/s12915-022-01462-5. PMC 9710175. PMID 36447225.