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Transcript
Interspecific Competition BIOL400 14 September 2015 Environmental Resource Consumed or utilized item in the environment, which results in population increase if it becomes more abundant Food Space (sessile organisms) Sunlight Soil nutrients and water Refugia Etc. Limitation It is only important to study resources which limit rate of population growth of species using them Mechanisms of Competition Exploitative/Scramble Out-consume others for food Pre-empt space Grow over, to intercept sunlight or raining aquatic detritus Contest/Interference Drive other competitors away • with chemicals (plants) • with aggressive behavior (animals) Principle of Competitive Exclusion No two species using the same limiting resource can coexist over the long term Experimental Demonstrations of Competitive Exclusion H.F. Gause—1920s and 1930s Used two species of ciliated protozoan (Paramecium) P. aurelia always survived, P. caudatum always went extinct HANDOUT—Gause’s Paramecium Studies Experimental Demonstrations of Competitive Exclusion Gause’s results mimicked by researchers using short-lived organisms Flour beetles • Winner moisture- or temperature-dependent Mice Drosophila Diatoms Etc. Figs. 10.11 & 10.12 pp. 171-172 29.1C 32.3C HANDOUT—Tilman et al. Diatom Studies Experimental Demonstrations of Competitive Exclusion Coexistence, without competitive exclusion, occurred in some pairings Lotka-Volterra Equations Elaborations of logistic population growth Logistic model assumes growth rate is reduced by the extent to which members of a population compete for limited resources intraspecifically L-V model introduces the effect on resource availability of the members of second, competing species Text p. 166 and Competition coefficients Extent to which a member of a second species impinges on the ability of a member of the first to harvest resources The higher and , the more intense the competition between species Isocline (Figs. 10.2-10.4) Points on the graph—combinations of N1 and N2—at which present population growth rate for one is zero e.g., r1[(K1-N1-N2)/K1] = 0 Starting points above the isocline go down to it, while starting points below the isocline go upward to it Fig. 10.2 p. 166 Isocline Example = 1000, = 0.60 Realized r1 = 0 when [N1 + (N2)] = K1 r1 = 0 when: K1 N1 = 1000 N1 = 800 N1 = 500 N1 = 200 N1 = 0 and N2 = 0 and N2 = 333 and N2 = 833 and N2 = 1333 and N2 = 1667 Fig. 10.3 p. 166 Fig. 10.4a p. 167 "Good" for species 1—K1 > K2/ "Bad" for species 2—K2 < K1/ Fig. 10.4b p. 167 "Bad" for species 1—K1 < K2/ "Good" for species 2—K2 > K1/ Fig. 10.4c p. 167 "Bad" for both species—stable equilibrium of species abundances Fig. 10.4d p. 167 "Good" for both species—outcome of competition is unpredictable exclusion Schoener (1983) 164 experimental tests for effects of interspecific competition 148 (90%) showed one species affecting N and r of another Of 390 spp. tested, 76% showed competition effects in at least some conditions tested 57% always showed effects But—surely NOT a random sample of study species Gurevitch et al. (1992) Effect Size = difference in biomass between experimental species with and without competitors, divided by pooled standard deviations of the two treatments 218 competition experiments Large effect sizes, esp. for herbivores Fig. 10.18 p. 177 Niche Grinnell (1917)— literally a subdivision of habitat Elton (1927)—"role" in an ecosystem Hutchinson (1958)— mathematically, an ndimensional hypervolume Fig. 10.13 p. 173 Restating the Gaussian Principle of Competitive Exclusion Using Hutchinsonian Terminology Species with high overlap in their hypervolumes (high and ): Exclusion of one or the other Species with little overlap (low and ): Resource partitioning and coexistence Resource Partitioning Closely related or ecologically similar species that coexist generally differ in resource use, reducing competition Concept stems from doctoral work of Robert MacArthur Fig. 10.14 p. 174 Niche Complementarity Two species that overlap greatly in one major type of resource (e.g., diet) will tend to overlap little in another (e.g., microhabitat) HANDOUT—Cody 1968 HANDOUT—Lindeman 2000 Slider, Trachemys scripta River cooter, Pseudemys concinna Ouachita map turtle, Graptemys ouachitensis Mississippi map turtle, Graptemys pseudogeographica Smooth Softshell, Apalone mutica
