Island Biogeography and Biodiversity Part I: Background Reading
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- Part II: Island Biogeography and Shannon-Weiner Index Lab Background
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- Island Size Location from Mainland of pasta of beans
- Part III: Article Analysis
| Island Biogeography and Biodiversity
Part I: Background Reading (Miller 16th ed) Read the sections in your textbook pertaining to island biogeography on pages 90, 188, and 194 (under habitat fragmentation). Explain E.O. Wilson’s theory of island biogeography. What two factors influence the biodiversity of an island? What two features of an island affect the immigration and extinction rate of its species? Explain how these features affect biodiversity. Explain how the species-area relationship model is related to the theory of island biogeography. Does an island have to be a literal island in a body of water? Explain what can be meant by island. Describe three factors that can create these islands. Part II: Island Biogeography and Shannon-Weiner Index Lab Background: Island biogeography is the study of community diversity on islands. One of the variables studied is the rate of colonization by additional species – called recruitment. The farther an island is from the mainland (or the source of colonists), the less frequently new colonists will arrive and become established. Also, the larger an island, the more likely it is more colonists to “find” that space and establish themselves on the island. Another variable is the carrying capacity of the island. Small islands contain fewer resources and support populations of fewer individuals. Small populations are more susceptible to local extinction; so small islands have fewer species than equivalent large islands. Small islands also have a higher ratio of perimeter to area than larger islands. This is important because at the borders of habitats, the physical conditions are often a combination of the conditions of either habitat. An example on oceanic islands is the perimeter of the forest, which will be buffeted by salt spray, while the forest’s center will not be. This creates an “edge effect.” The principles from island biogeography can easily be applied to terrestrial situations. For example, alpine habitats are usually separated by lowland habitats, and lake habitats are separated by terrestrial and stream habitats. Fragmented habitats, such as rainforest parcels separated by farmlands, can be considered “islands.” Many wildlife managers have taken the effects of “island” size into account and have begun to link smaller fragments of habitat together using small corridors to effectively increase the island size. (Costa Rica is an example.) There has also been increasing concern that if a catastrophe damages a nature preserve that is essentially an island, the preserve may not recover quickly unless there is a source of colonists (equivalent to the mainland) fairly close by.
Materials per student: 3 pasta
3 beans 3 paper clips 3 cotton balls 3 coins
You are standing on the mainland and located around you are four islands. There are two large islands and two small islands located at varying distances from the mainland. You cannot leave the mainland for this activity. . Each of your species is going to be “migrating” to a new island. One island at a time, throw some of your species onto the target island. Remember, organisms will be aiming for land – they don’t want to end up in the ocean. . Students will go to each island and count the species that have managed to colonize the island. . The remaining students will go rescue the species that are drowning in the ocean (that means clean-up everything that missed an island). Class Data:
Data Analysis This index is determined by both the number of species and the even distribution of individuals among those species (relative dominance). It indicates the degree of uncertainty of predicting the species of a given individual picked at random from the community. In other words, if the diversity is high, you have a poor chance of correctly predicting the species of the next individual picked at random. The formula is: H = - sum (Pi ln [Pi]) Where: Pi (relative abundance) = ni/N Where:
ni = number of individuals in species i N = total number of individuals in all species H (the uncertainty of predicting the species) will range from 0 for a community with a single species, to over 7 for a very diverse community. Show your calculations for each of the islands. Conclusion Questions: Which island had the highest diversity according to your calculations? Explain why this might be. Did fragmentation of the mainland habitat affect the diversity of the species found? Explain. Would a habitat of 10 species (2 individual of each) be more or less diverse than a habitat containing 1 species with 85 individuals and 9 other species with 1 representative of each? Explain. You are working on designing a reserve, but the final size has been decided, and you must choose between two sites. Site 1 has a very low community diversity value because it is largely dominated by a single species; however, one of the rare species found there is so rare it is found in only one other park. Site 2 lacks this particular rare species, but has much higher diversity values because it contains more species than Site 1 and none of the species is particularly dominant. Which site would you choose for the reserve and why? Part III: Article Analysis Research into biodiversity was just published in the journal Science relating to man-made islands in Thailand. Read the following article summary and answer the questions about it that follow.
Anthony Lynam; (inset) Luke Gibson Going, going … Small mammal species have disappeared more quickly than expected from the forest fragments on islands created by flooding in southern Thailand. Populations of surviving species, such as this moonrat (inset), have plummeted. As deforestation accelerates around the world, ecologists have increasingly pinned their hopes of preserving biodiversity on nurturing the isolated patches of forest often left behind. But new research suggests that small mammal species native to these forest fragments are at greater risk of extinction than previously thought. The filling of the Chiew Larn Reservoir in southern Thailand in 1986 and 1987 created more than 100 islands and presented a rare opportunity to study the effects of sudden isolation on small-mammal communities. In the early 1990s, a team led by population geneticist David Woodruff of the University of California, San Diego, set traps to survey small mammals on 12 of the islands, ranging in size from 0.3 to 56.3 hectares. They found that after 5 to 7 years of isolation, the three biggest islands were still home to seven to 12 species of mice, rats, squirrels, and shrews. The range of species was similar to that found in a large, undisturbed forest on the nearby mainland. On the small islands, however, the researchers found just one to three species, indicating a rapid decline in diversity, presumably because the islands were too small to sustain animal communities. Ecologist Luke Gibson of the National University of Singapore and colleagues revisited those islands plus four more in 2012 and 2013 to repeat the surveys, with some dramatic results. Six of 12 species present in the early 1990s, including the pencil-tailed tree mouse and the red spiny rat, have apparently disappeared. Five other species have declined dramatically. For example, the 1993 survey turned up 47 common tree shrews, but only one was found in 2013. "We documented the near-complete extinction of an entire group of animals," Gibson says. In contrast, Malayan field rat numbers exploded, from 77 in 1992 to 289 in 2013. This rat is not normally found in the region’s undisturbed forests but likely migrated to the islands from villages and agricultural areas after inundation. It now dominates the islands but is rare in the intact forests of the nearby mainland. In the absence of other obvious causes, the researchers blame the loss of species on fragmentation and the impact of the invasive rat. This one-two punch "underscores a dire need to maintain large intact forest blocks to sustain tropical biodiversity," the authors write today inScience. Gibson adds that the loss of species occurred more quickly than has been reported by other groups studying other sites around the world. "This study makes a valuable contribution in quantifying how fast the extinctions take place—very fast in this case," says Ilkka Hanski, an ecologist at the University of Helsinki. But he notes that the study does not tease out whether the fragmentation or the rat invasion had a greater impact. Robin Chazdon, an ecologist at the University of Connecticut, Storrs, notes that the mechanism by which the invasive rats contributed to the demise of native species—whether they devoured available food or introduced new diseases—is not clear. "These findings are not directly relevant to forest fragments in terrestrial landscapes," where animals from surrounding areas could recolonize the isolated patch, she says. Gibson agrees that it is difficult to separate the impact of forest fragment size from that of the rats. "Our data don't show any direct mechanism," for how the rodents might have tipped the scales against the natives, he says. As for the implications for fragments on large land masses, he argues that these small islands provide "a sign of things to come." For example, he says a recent study of Brazil's Atlantic forests found that 80% of fragments remaining after deforestation are 50 hectares or smaller—about the size of the Thai island samples. Although most forest fragments are not ringed by water, they are nonetheless “increasingly surrounded by intensive agricultural landscapes that often harbor invasive animal species," Gibson says. Beyond preserving large intact forests, he adds, conservation efforts should aim to keep or create forested corridors to link small fragments of important habitat or to connect them to larger forests nearby. Questions: Explain how this forest ecosystem became fragmented. Summarize the scientists findings about biodiversity on the Small islands Large islands Make a simple graph of the overall findings by Luke Gibson between the early 1990s and 2012-13. 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