Competition

1. Competition Individual Interactions, part 1

2. Niche • A concept that encompasses all of the individual environmental requirements of a species • This is definitely an abstract concept, but it helps us to organize and explain ecological phenomena

3. What are some possible elements of this organism’s niche?

4. Niche • A species’ niche is composed of both physical (e.g., average temperature) and biotic (e.g., food sources) components • Resources comprise a critical subset of these niche elements

5. Resources • Include such things as: • Food or nutrients • Shelter • Space to grow • Water • Light (plants)

6. Resources • Resources are usually limited • Individuals compete for limited resources

7. Competition • Competition can be separated into two broad categories of interactions: • Interference Competition – direct antagonistic behavior towards other individuals (e.g., defending territory) • Resource Competition – individuals compete indirectly through the exploitation of a shared resource

8. Competition • Competition for resources between individuals of the same species = Intraspecific competition

9. Intraspecific Competition • Leads to the process of self-thinning in plants

11. Intraspecific Competition • Intraspecific competition regulates population growth in a density-dependent manner: • as individuals deplete resources, population growth slows until the population size = K K dN/dt = rmaxN(K-N/K)

12. Intraspecific Competition • When genetic factors influence the efficiency of resource use, evolution tends to increase the competitive ability within a population Resource availability K1 K2 Population density

13. Competition • Competition for resources between individuals of different species = Interspecific competition

14. Interspecific Competition • Played a prominent role in Darwin’s theory of natural selection • “struggle for existence” based on competition for limited resources • Competition should be most intense between closely related species

15. Modeling Interspecific Competition: Lotka-Volterra Model Population growth of species 1: dN1/dt = rmax1N1(K1-N1/K1) Population growth of species 2: dN2/dt = rmax2N2(K2-N2/K2) We can modify these logistic growth equations to account for interspecific competition by adding competition coefficients… -12N2 -21N1 and

16. Modeling Interspecific Competition: Lotka-Volterra Model Population growth of species 1: dN1/dt = rmax1N1(K1-N1-12N2/K1) Population growth of species 2: dN2/dt = rmax2N2(K2-N2-21N1/K2)

17. Modeling Interspecific Competition: Lotka-Volterra Model When population growth has stopped… dN1/dt = rmax1N1(K1-N1-12N2/K1) = 0 • dN2/dt = rmax2N2(K2-N2-21N1/K2) = 0 This can be rearranged algebraically…

18. Modeling Interspecific Competition: Lotka-Volterra Model To predict when population growth in each species will stop: N1 = K1-12N2 and • N2 = K2-21N1

19. Modeling Interspecific Competition: Lotka-Volterra Model

20. Modeling Interspecific Competition: Lotka-Volterra Model Species can only coexist when: K1> K2/21 K2> K1/12 and …that is, when intraspecificcompetition is greater than interspecificcompetition

21. Interspecific Competition • G.F. Gause (1934) integrated the idea of the niche and interspecific competition: • Competitive Exclusion Principle – • Two species with identical niches cannot coexist indefinitely (one will out-compete the other for limited resources)

22. K of P. aureliaalone = 195 K of P. caudatumalone = 137

23. Competitive Exclusion • Grown separately, P. aureliahad a higher K than P. caudatum • Grown together, P. aureliaout-competed P. caudatum for resources (growth medium), and P. caudatum was eliminated

24. Interspecific competition & the niche • Hutchinson: fundamental nichedefines the environmental conditions in which a species might live, in the absence of interactions with other species; realized nicheis the actual niche of a species, which is limited by biotic interactions (competition, predation, etc.)

25. Interspecific competition - Gallium G. saxatile G. pumilum A. Tansley (1917)

26. Interspecific competition

27. Interspecific competition - Gallium On limestone (basic) soils, G. pumilumovergrew and eliminated G. saxatile by the end of the first growing season On acidic soils, G. saxatilewas completely dominant, but G. pumilumwas not completely eliminated by the 6th year. Growth of both species was much slower on the acidic soils. A. Tansley (1917)

28. Interspecific competition - Gallium • The fundamental niches of both Gallium species include a wider variety of habitats (soil types) than those they actually inhabit in nature • Interspecific competition restricts the realized niche of each species to a narrower range of soil types • Asymmetric competition – each species is able to specialize in its realized niche because each is better at doing a different thing (e.g., exploiting resources vs. tolerating stress)

29. Interspecific competition - Gallium • Asymmetric competition – each species is able to specialize in its realized niche because each is better at doing a different thing (e.g., exploiting resources vs. tolerating stress)

30. Interspecific competition - barnacles Joseph Connell (1961)

32. REVIEW QUESTION • What type of selection pattern (stabilizing, directional, disruptive) would you expect to observe in a population undergoing intense intraspecific competition for resources?

33. REVIEW QUESTION • How might the realized niches of two competing species evolve?

34. Disruptive selection