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Geographic Ecology On islands and habitat fragments on continents, species richness increases with area and decreases with isolation. Species richness on islands can be modeled as a dynamic balance between immigration and extinction of species. Species richness generally increases from middle and high latitudes to the equator.
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Introduction MacArthur defined geographic ecology as the search for patterns of plant and animal life that can be put on a map.
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Island Area and Species Richness
Preston found fewest bird species live on smallest islands and most species on largest islands. Nilsson et.al. found island area was best single predictor of species richness among woody plants, carabid beetles, and land snails.
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Habitat Patches on Continents: Mountain Islands
As Pleistocene ended and climate warmed, forest and alpine habitats contracted to the tops of high mountains across American Southwest. Woodlands, grasslands, and desert scrub, invaded lower elevations. Once continuous forest converted to series of island-like fragments associated with mountains: montane.
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Kikuchi’s field vole Fig. Neighbor-joining tree based on 703 bp of mtDNA control region sequences.
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Number of species increases with area sampled.
Arrhenius first formalized the species-area relationship as: S = cAz where: S = number of species encountered A = area c and z are fitted constants After log transformation, the relationship is linear: logS = logc + zlogA
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Species-Area Relationships
Analyses of many species-area relationships have shown that values of the slope, z, fall within the range For continental areas, z is often between 0.15 and 0.25, which is lower than insular situations, where z is often between 0.20 to 0.40 Are species-area relationships artifacts of larger sample size (more individuals) in larger areas? comparisons of species numbers in different areas where samples of similar size were used still reveals a species-area relationship
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Why do larger areas have more species?
Larger areas have greater habitat heterogeneity. For islands, size per se makes the island a better target for potential immigrants from the mainland. Larger islands support larger populations, which persist because they have: greater genetic diversity broader distributions over habitats numbers large enough to prevent stochastic extinction
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Marine Islands MacArthur and Wilson found isolation reduces bird diversity on Pacific Islands.
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Williamson summarized data from relationship between island area and species richness in Azore Islands: Birds show clear influence of isolation on diversity, pteridophytes do not. Land birds fly across water barriers, pteridophytes produce large quantities of light spores easily dispersed in the wind. *dispersal ability
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Effect of distance on island immigration
Tabulated land birds on island close to the source area (New Guinea), and assumed 100% of the available birds Documented drop-off in species with increasing distance to New Guinea
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Equilibrium Model of Island Biogeography
MacArthur and Wilson: model explaining patterns of species diversity on islands as result of immigration and extinction rates. Reasoned rates of immigration would be highest on new island with no organisms. As species began to accumulate, rate of immigration would decline since fewer arrivals would be new species.
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Equilibrium Model of Island Biogeography
Predicted rate of extinction would rise with increasing number of species on an island for three reasons: Presence of more species creates a larger pool of potential extinctions. As # of species increases, population size of each must diminish. As # of species increases, potential for competitive interactions between species will increase.
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Equilibrium Model of Island Biogeography
Point where two lines cross predicts the number of species that will occur on an island. Proposed rates of extinction on islands would be determined mainly by island size. LG, near islands will support greatest #. SM, far islands will support lowest #. SM near and LG far will support intermediate #.
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Species Turnover Equilibrium model predicts spp. composition on islands is fluid: Change referred to as species turnover. Rate of species lost and other gained Diamond found birds in nine CA Channel Islands in a stable equilibrium as a result of immigration and extinction. - compared his list to that of A. B. Howell (1917) species per island were no longer present, but just as many species had not listed by Howell had apparently colonized the island – indicating turnover
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Experimental Island Biogeography
Simberloff and Wilson studied insect recolonization in Florida Keys. Chose 2 stands of mangroves as control islands, and 6 others as experimental islands. Defaunated islands Followed recolonization for 1 yr. Species number stayed constant, but composition changed considerably.
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Colonization of New Islands By Plants
Rydin and Borgegard found variation in spp. richness correlated positively with island area and accounted for 44-85% of variation in spp. richness among islands. Small and medium islands continued to accumulate species. Large islands attained equilibrium of immigration and extinction. Area or habitat effects? Difficult to separate effects of habitat diversity from area affects.
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Manipulating Island Area
Simberloff tested effect of island area on species richness. In all cases where area was reduced, species richness decreased. Richness on control island increased slightly. Islands with reduced area lost species with each reduction in area. Showed area has positive influence on species richness.
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Modifications to MacArthur & Wilson’s theory model
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Theory of Nature Reserve Design
Larger is better than smaller One large area is better than several smaller areas (SLOSS) Corridors connecting isolated areas are desirable Circular areas are better than elongate ones with much edge
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Latitudinal Gradients in
Species Richness
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Latitudinal Gradients in Species Richness
Most groups of organisms are more species-rich in the tropics. Hot Spot
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Species richness and elevation
decreases with increasing elevation peaks at mid-elevation (Sanders, 2002) There are two general predictions of how species richness and elevation are related: Either species richness decreases with increasing elevation Species richness peaks at mid-elevations
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Mid-elevation (small mammal diversity)
The elevation intermediate between the base and top of a mountain In tropics, mountains reaching about 3000 meters which allows full development of lowland, montane and mossy forest, the pattern shows mid-elevation peak In this kind of studies, mid-elevation peak means as peak in species diversity at some elevation intermediate between the base and top of a mountain. And Heaney (2001) suggested that “In tropics, mountains reaching about 3000 meters which allows full development of lowland, montane and mossy forest, the pattern shows mid-elevation peak” (Heaney, 2001)
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intermediate point in the gradient
Models of species diversity along enviromental gradients Partially overlapping requirements Diversity peaks at an intermediate point in the gradient Brown (2001) brought up two simple models of species diversity along environmental gradient. And this is the first one. The gradient described on the x-axis could apply to elevation or any environmental variable. The ranges of the species along the gradient are described as horizontal lines, and the light vertical lines with numbers show hypothetical samples at different positions along the gradient and the resulting number of species (The upper figure) is the simplest of only two species case and (the lower one) is case for 5 species The species have overlapping requirements and ranges, and some but not all species are able to occur at each extreme. This gives at least one peak in species richness at an intermediate position where ranges overlap (Brown, 2001)
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at an intermediate point Diversity peaks at an intermediate point
Models of species diversity along enviromental gradients Nested subset pattern at an intermediate point The second model is that The species have a nested subset pattern of requirements and ranges, such that the species all occur at some intermediate location, but they vary in how far they range toward the two extremes This gives a peak in diversity at some intermediated location in the gradient. Diversity peaks at an intermediate point (Brown, 2001)
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Mt. Kinabalu (4101 m), Malaysia
Plant diversity Small mammal diversity In Malaysia Mt. Kinabalu, Md. Nor (2001) found the small mammal diversity had a peak in about 1400 meters.(動畫1) x is elevation and y is number of species(動畫2) And the diversity was correlated with the distribution of plants such as tree, fern, orchid, and Gymnosperm species. They all had a diversity peak in about 1400~1500 meters. And then, I will introduce the condition in Taiwan……. (Md. Nor, 2001)
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Elevation distribution of small mammals in Yushan National Park
Niviventer culturatus Niviventer coxingi Apodemus semotus Microtus kikuchii Tamiops maritimus Ethenomys melanogaster Anourosorex squamipes Soriculus fumidus Apodemus agrarius And he reported the elevation distribution of 9 species of small mammals (include one species of squirrel, Tamiops maritimus, and two species of shrews) (動畫) We can see the peak of species diversity emerged between 2500 to 3000 meters. (modified from Yu, 1994)
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Latitudinal Gradients in Species Richness
Brown grouped hypotheses into six categories: -1. Time Since Perturbation More species in the tropics because tropics are older and disturbed less frequently. 2. Productivity High productivity contributes to high species richness. More energy to divide among population. 3. Environmental Heterogeneity More heterogeneity thus more potential habitat areas and niches.
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Latitudinal Gradients in Species Richness
4. Favorableness Tropics have more favorable environments. 5. Niche Breadth and Interspecific Interactions: a. tropical species limited more biological factors b. tropical species affected more by interspecific interaction c. niches of tropical species overlap more d. tropical species more specialized e. tropical species more subject to control by predation, parasitism, and pathogens f. tropical species more involved mutualistic interaction 6. Speciation and Extinction Rates Rosenzweig proposed immigration can be largely discounted at broad scales, thus speciation will be primary source of new species.
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Historical and Regional Influences
Latham and Ricklefs: reported striking contrast in diversity of temperate zone trees that cannot be explained by area effect. Temperate forest biome in Europe, Eastern Asia, and Eastern North America all have roughly equitable area, but support vastly different levels of biological diversity. Eastern Asia: 3x NA and 6x Europe.
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Historical and Regional Influences
Latham and Ricklefs: Must examine conditions trees in these regions faced during the last glacial period. Mountains in Europe form east-west oriented barriers. During last ice age, temperate trees had southward retreat largely cut-off. Lower species richness as consequence of higher extinction rate.
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Historical and Regional Influences
Appalachian Mountains in N.A run north-south, thus temperate trees had an avenue of retreat as temperatures became colder. Also no mountain barriers in Asia. Concluded from various lines of evidence that most temperate tree taxa originated in Eastern Asia and dispersed to Europe and N.A.. After dispersal lines were cut, speciation continued in Asia.
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Summary On islands and habitat fragments on continents, species richness increases with area and decreases with isolation. Species richness on islands can be modeled as a dynamic balance between immigration and extinction of species. Species richness generally increases from middle and high latitudes to the equator. Long-term historical and regional processes significantly influence ecosystem structure.
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