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Transcript
4/15/11 Organisms don't live in a vacuum! Introduction to Ecology by Dr. W. Without any controls, given unlimited resources, a population would grow exponentially—as shown by this exponential curve, or J-curve. • Ecology is the study of how organisms interact with each other and with their surroundings. • Ecology can be studied at various levels of organization: – Population — the set of all members of a single species in one area. – Community — a set of interacting populations of different species in one area. – Ecosystem — the sum of communities and their abiotic (non-living) surroundings in one area. – Biome — a set of similar ecosystems. – Biosphere—all life on Earth. Suppose we had a single E. coli bacterium which was kept under perfectly ideal conditions. Under such conditions a bacterium can divide about once every twenty minutes. 1 4/15/11 The life cycle of common fruit flies (Drosophila melanogaster) takes about seven days under ideal conditions. Starting with one pair of flies, in one year you would have a ball of flies as large as the Earth. Clearly this can’t happen in the real world—something must act to keep populations down. Carrying Capacity • Many factors, both biotic (living) and abiotic (nonliving), determine an ecosystem's carrying capacity —the maximum number of individuals in a population that it can stably support. In a simple model, populations often grow to meet the carrying capacity and then level off. This is called logistic growth, and this type of growth curve is called a sigmoid curve. – Biotic factors might include presence of predators or parasites, presence of prey or other food sources, etc. . . . – Abiotic factors might include amount of sunlight, temperature, moisture levels, nutrient availability, oxygen levels, etc. . . . 2 4/15/11 In other cases, a population might increase, overshoot the carrying capacity, and then fall back—or possibly oscillate around the carrying capacity. (Note that the carrying capacity is abbreviated K in the mathematical equations that describe population behavior.) In many other cases, populations may influence each other. In northern Canada, the Hudson Bay Company buys animal furs from trappers, and it keeps records of the furs that are bought — its records go back over 150 years. . . This could be caused by some factor in the environment— but notice how the lynx population usually peaks just slightly after the hare population peaks. The populations of snowshoe hares, and of lynxes, follow regular cycles of boom and bust. 3 4/15/11 The reason seems to be that the hares are the lynxes' primary food supply. As hares increase in numbers, there's more food for the lynxes, and the lynxes raise more kittens and become more abundant. . . But when lynxes are abundant, they eat many hares, and the hare population falls. Then there's less food for the lynxes, and the lynxes become less abundant. . . . . . but with few lynxes, the hares start increasing in number again. Thus you have these regular cycles of population size in both hares and lynxes. Carrying Capacity • The carrying capacity of an environment is not fixed. – An organism might modify the carrying capacity of its own environment by its own activities. – EXAMPLE: New farming methods have increased the world's food supply dramatically over the past few hundred years, thus boosting the carrying capacity of humans. – On the other hand, 10% of the world's fertile topsoil has been lost since 1945, often due to human mismanagement, pulling the carrying capacity down. . . 4 4/15/11 Largely because of overgrazing by livestock and poor irrigation, 3900 square miles of the Sahel becomes desert each year. (That's about equal to six medium-sized counties in Arkansas.) Case Study: The dry grassland south of the Sahara Desert is called the Sahel. The carrying capacity of the countries in the Sahel— such as Mali, Burkina Faso, Chad, Niger, etc. — is dropping. At the same time, the human population itself is rapidly rising. . . Life Histories • Organisms tend to evolve towards one of two possible life history strategies (although inbetween strategies are very common as well): – r-selected life history: Many offspring, but low parental investment of energy in each one. Most of the mortality is among the younger members. – K-selected life history: Few offspring, but high parental investment of energy in each one. Most of the mortality is among the older members. 5 4/15/11 Humans are a strongly K-selected species, as are most mammals. Reproduction is relatively low, but we invest much energy (in pregnancy, nursing, and child care) in each offspring. Oysters are strongly r-selected species. The clouds of "smoke” are countless millions of eggs and sperm being released freely into the water. The vast majority of the larvae will die before reaching adult size. 6
