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Ecology: Lectures 4 & 5

Ecology: Lectures 4 & 5. Properties of Populations. “Population” defined. A group of organisms of the same species occupying a particular space at a particular time. Should define “space” and “time” in terms that are of ecological relevance to the organism and/or your particular study.

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Ecology: Lectures 4 & 5

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  1. Ecology: Lectures 4 & 5 Properties of Populations

  2. “Population” defined • A group of organisms of the same species occupying a particular space at a particular time. • Should define “space” and “time” in terms that are of ecological relevance to the organism and/or your particular study.

  3. Laysan’s albatross:Population at Midway I., breeding season Photo courtesy of Painet photos

  4. Population of overwintering monarchs in Central Mexico Photo courtesy of The Chicago Wilderness Magazine

  5. Defining a mobile population • Tracking tuna in the Atlantic • Barbara Block, Nature 2005

  6. “Population” as related to genes and evolution • Populations as genetic units • Gene pool: Sum of all the genetic material within a population • Evolution is the change in the gene frequencies of a population over time (>1 generation.)

  7. Characteristics of populations • Density is the most basic characteristic of a population (from an ecologist’s perspective) • Four population parameters change density • Natality • Mortality • Immigration • Emigration • Several important “secondary” characteristics such as age distribution, patterns of distribution, genetic composition, etc…

  8. Quantifying populations • Unitary organisms • Examples? • Modular organisms • Examples?

  9. Modular organisms:Ramets and genets of aspen trees

  10. What is the “ramet” of a coral? Where are the “genet” boundaries? Modular organisms: Coral

  11. Groups of isolated populations linked together by gene flow What causes these populations to be fragmented rather than continuous? How is “gene flow” accomplished? Real examples… Metapopulations

  12. Queen conch metapopulations

  13. “Crude” vs. “ecological” density • What is the difference? • Example 1: Sea urchins (S. purpuratus) in the low intertidal • Example 2: Macroinvertebrates in a stream

  14. Spatial patterns of dispersion

  15. Uniform distribution of golden eagle territories

  16. Clumped distributionEuphydryas editha and its host plant, Plantago Photos courtesy of Paul Ehrlich

  17. Populations & metapopulation of Euphydryas editha on Jasper Ridge Photos and diagram courtesy of Paul Ehrlich

  18. Temporal patterns of dispersion • Examples? • Emmigration/immigration (one-way) • Migration (round trip)

  19. Pacific gray whale migration (blue arrows) Benefits? Costs? Yearly migrations

  20. Arctic and Antarctic terns Arctic ternPhoto by Brian Small Antarctic ternPhoto by Danny Gallant

  21. Arctic tern migration

  22. Age structure • Stable age distribution • Continuously breeding populations should tend towards an age distribution where ratio of ages remains constant Age class Percentage of population

  23. Age structure • Stationary age distribution • Deaths balance births; population remains a constant size • Stationary populations are also stable. • But stable populations aren’t always stationary! Age class Percentage of population

  24. When might a shrinking population show a high proportion of young? Age structure and population growth rates

  25. Time Effects of missing year class in cactus ground finch • Notice progression of individual cohorts. • Why are some cohorts missing? • Why are some cohorts large?

  26. Effects of missing year class in cactus ground finch

  27. Sex ratios • Tends toward 1:1 • Often different between conception and birth • 1:1 at conception slightly favors males at birth Slightly favors females at sexual maturity • Why is male mortality higher than female mortality between birth and maturity. Possible reasons include… • Males are hemizygous (why would this matter?) • Male behavior may be more stressful (male-male competition during the breeding season) • Males of many species more prone to risky behavior

  28. Survivorship curves

  29. What caused the difference in curves for this species? Variation in survivorship pattern for the annual garden rocket

  30. Mortality curve compared to survivorship curve

  31. Fecundity curve

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