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006 Species Interaction & Community Ecology

Environment & Ecology. 006 Species Interaction & Community Ecology. Case Study: Black and white and spread all over. Species interactions. Species interactions are the backbone of communities. Competition occurs with limited resources.

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006 Species Interaction & Community Ecology

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  1. Environment & Ecology 006 Species Interaction & Community Ecology

  2. Case Study: Black and white and spread all over

  3. Species interactions Species interactions are the backbone of communities.

  4. Competition occurs with limited resources Competition: relationship where multiple organisms seek the same limited resources they need to survive Generally subtle, not outright fighting Food, water, space, shelter, mates, sunlight, etc. Intraspecific competition: between members of the same species Interspecific competition: between members of 2 or more species Effective competitors can completely exclude other species i.e., Zebra mussels displace native mussels But some species can coexist by using different resources

  5. Resource partitioning Avoids competition for resources

  6. Predation Exploitative interactions: a type of interaction where one species benefits while another is harmed Predation, parasitism, herbivory Predation: process by which individuals of one species (predators) capture, kill, and consume individuals of another species (prey) Structures food webs Influences community composition by determining numbers of predators and prey

  7. An example of predation: zebra mussels Zebra mussels prey on zooplankton. Zooplankton decrease in lakes with zebra mussels. Zebra mussels prey on phytoplankton. Compete with zooplankton Zebra mussels are becoming prey for some North American predators. Ducks, fish, muskrats, crayfish

  8. Predation has evolutionary ramifications Natural selection leads to evolution of adaptations that make predators better hunters. Individuals who are better at catching prey… Live longer, healthier lives Take better care of offspring Since prey are at risk of immediate death… They develop elaborate defenses against being eaten

  9. Natural selection to avoid predation

  10. Parasites exploit living hosts Parasitism: a relationship in which one organism (parasite) depends on another (host) for nourishment or other benefit, while simultaneously harming the host Usually does not immediately kill the host

  11. Coevolution Coevolution: evolution of hosts and parasites in response to each other They become locked in a duel of escalating adaptations. Has been called an “evolutionary arms race” Each evolves new responses to the other It may not be beneficial to the parasite to kill its host.

  12. Herbivores exploit plants Exploitation in which animals feed on the tissues of plants Widely seen in insects May not kill the plant, but affects its growth and survival Defenses against herbivory include: Toxic or distasteful chemicals Thorns, spines, or irritating hairs

  13. Mutualists help one another

  14. Ecological communities Community: an assemblage of species living in the same place at the same time Members interact with each other. These interactions determine the composition, structure, and function of the community. Community ecologists: people interested in: How species coexist and relate to one another How communities change Why patterns exist

  15. Energy passes among trophic levels

  16. Predation can drive population dynamics

  17. Trophic levels Autotrophs (“self-feeders”): organisms that capture solar energy for photosynthesis to produce sugars Green plants, cyanobacteria, algae Primary consumers: organisms that consume producers and comprise the second trophic level Herbivores such as deer and grasshoppers Secondary consumers: prey on primary consumers and comprise the third trophic level Carnivores (wolves, birds) that consume meat Tertiary consumers: predators that feed at higher trophic levels Hawks, owls

  18. Detritivores and decomposers Organisms that consume non-living organic matter Detritivores: scavenge waste products or dead bodies Millipedes, and other invertebrates Decomposers: break down leaf litter and other non-living material Fungi, bacteria Enhance topsoil and recycle nutrients

  19. Food Chains • Artificial devices to illustrate energy flow from one trophic level to another • Trophic Levels: groups of organisms that obtain their energy in a similar manner

  20. Energy and Biomass Pyramids Kaneohe Bay 10 J Tertiary consumers 100 J Secondary consumers 1000 J Primary consumers 10,000 J Limu Primary producers 1,000,000 J of sunlight

  21. Energy decreases at higher trophic levels • Ecological efficiency (food chain efficiency) is the percentage of energy transferred from one trophic level to the next: • range of 5% to 20% is typical • greater efficiency in fewer trophic levels Where did the rest of the energy go?

  22. Energy Use By An Herbivore Algae eaten by Uhu Cellular Respiration Feces Growth

  23. Food webs show relationships and energy flow Antarctic Food Web

  24. Keystone Species A species whose presence in the community exerts a significant influence on the structure of that community.

  25. Keystone predator hypothesis - predation by certain keystone predators is important in maintaining community diversity.

  26. Paine’s study on Pisaster and blue mussels

  27. Keystone Species Kelp Forests

  28. Food Webs

  29. Keystone Species Algal turf farming by the Pacific Gregory (Stegastes fasciolatus)

  30. Ecological Succession The progressive change in the species composition of an ecosystem.

  31. New Bare Substrate Colonizing Stage Successionist Stage Climax Stage Ecological Succession

  32. 2 types of succession SECONDARY PRIMARY • Growth occurring after a disturbance changes a community without removing the soil • Growth occurs on newly exposed surfaces where no soil exists • Ex. Surfaces of volcanic eruptions

  33. Primary Succession For example, new land created by a volcanic eruption is colonized by various living organisms

  34. Secondary Succession Disturbances responsible can include cleared and plowed land, burned woodlands

  35. Mount St. Helens prior 1980

  36. Mount St. Helens Sep. 24, 1980 May 18, 1980

  37. Mount St. Helens Fireweed 1980 after eruption 2004 2012

  38. Succession after Volcanic Eruption What organisms would appear first? How do organisms arrive, i.e., methods for dispersal? Volcanic eruption creates sterile environment Hanauma Bay Tuff Ring (shield volcano)

  39. Early species improve habitat. Ex. Early marine colonists provide a substrate conducive for settling of later arriving species. First arrivals take precedence. Competition for space, nutrients and light; allopathic chemicals. As resources become scarce due to depletion and competition, species capable of tolerating the lowest resource levels will survive. Mechanisms of Succession Facilitation Inhibition Tolerance

  40. high reproductive output high growth rate short life span low competitive ability low reproductive output higher maternal investment per offspring high competitive ability long life span slow growth rate r & K Selected Species Pioneer species- 1st species to colonize a newly disturbed area r selected r & K refer to parameters in logistic growth equation Late successional species K selected

  41. Invasive species threaten communities • Invasive species: non-native (exotic) organisms that spread widely and become dominant in a community • Can substantially alter a community • Growth-limiting factors (predators, disease, etc.) are removed or absent • They have major ecological effects • Fish introduced for sport outcompete and exclude native fish • Some species help people (i.e., European honeybee).

  42. Two invasive mussels Zebra mussels impact other species, either positively or negatively.

  43. Controlling invasive species • Techniques to control invasive species: • Remove manually • Toxic chemicals • Drying them out • Depriving of oxygen • Introducing predators and diseases • Stressing them • Heat, sound, electricity, carbon dioxide, ultraviolet light Prevention, rather than control, is the best policy.

  44. Changed communities need to be restored • Humans have altered Earth’s landscape to such a degree, that no area is truly pristine. • Ecological restoration: returning an area to unchanged conditions • Informed by restoration ecology: the science of restoring an area to the condition that existed before humans changed it • It is difficult, time-consuming, expensive • Best to protect natural systems from degradation in the first place

  45. Restoration efforts • Prairie Restoration • Native species replanted and invasive species controlled • The world’s largest project: Florida Everglades • Depletion caused by flood control practices and irrigation • Populations of wading birds dropped 90-95%. • It will take 30 years and billions of dollars to undo dams and diversions. • Restoring ecosystem services will prove economically beneficial.

  46. Biomes of the World tundra chaparral deciduous forest alpine taiga desert scrub savannah grassland desert rainforest

  47. A variety of factors determine the biome • The biome in an area depends on a variety of abiotic factors. • Temperature, precipitation, ocean and air circulation, soil • Climatograph: a climate diagram showing an area’s temperature and precipitation Similar biomes occur at similar latitudes.

  48. Aquatic systems have biome-like patterns • Various aquatic systems have distinct communities. • Coastlines, continental shelves • Open ocean, deep sea • Coral reefs, kelp forests • Coastal systems (marshes, mangrove forests, etc.) • Freshwater systems (lakes, rivers, etc.) • Aquatic systems are shaped by: • Water temperature, salinity, and dissolved nutrients • Wave action, currents, depth • Substrate type and animal and plant life

  49. Aquatic Biomes

  50. Temperate deciduous forest • Deciduous trees lose their leaves each fall and remain dormant during winter • Mid-latitude forests in Europe, East China, Eastern North America • Fertile soils • Forests: oak, beech, maple

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