Community Interactions Chapter 29
Forest of New Guinea Community includes nine species of pigeons that partition the food supply Pigeons disperse seeds of the trees that provide their food (fruit) These are just a few of the many interactions that shape this community
Community All the populations that live together in a habitat Habitat is the type of place where individuals of a species typically live Type of habitat shapes a community’s structure
Factors Shaping Community Structure Climate and topography Available foods and resources Adaptations of species in community Species interactions Arrival and disappearance of species Physical disturbances
Niche Sum of activities and relationships in which a species engages to secure and use resources necessary for survival and reproduction
Realized & Fundamental Niches Theoretical niche occupied in the absence of any competing species Realized niche Niche a species actually occupies Realized niche is some fraction of the fundamental niche
Species Interactions Most interactions are neutral; have no effect on either species Commensalism helps one species and has no effect on the other Mutualism helps both species
Species Interactions Interspecific competition has a negative effect on both species Predation and parasitism both benefit one species at a cost to another
Symbiosis Living together for at least some part of the life cycle Commensalism, mutualism, and parasitism are forms of symbiosis
Mutualism Both species benefit Many examples in nature Some mutualisms are obligatory; partners depend upon each other
Yucca and Yucca Moth Example of an obligatory mutualism Each species of yucca is pollinated only by one species of moth Moth larvae can grow only in that one species of yucca
Mycorrhizae Obligatory mutualism between fungus and plant root Fungus supplies mineral ions to root Root supplies sugars to fungus
Competition Interspecific - between species Intraspecific - between members of the same species Intraspecific competition is most intense
Forms of Competition Competitors may have equal access to a resource; compete to exploit resource more effectively One competitor may be able to control access to a resource, to exclude others
Competitive Exclusion Principle When two species compete for identical resources, one will be more successful and will eventually eliminate the other
Competitive Exclusion Expt Paramecium caudatum Paramecium aurelia
Keystone Species A species that can dictate community structure Removal of a keystone species can cause drastic changes in a community; can increase or decrease diversity
Lubchenco Experiment Periwinkles promote or limit diversity in different habitats Tidepools Rocks exposed at high tide
Resource Partitioning Apparent competitors may actually have slightly different niches Species may use resources in a different way or time Minimizes competition and allows coexistence
Predation Predators are animals that feed on other living organisms Predators are free-living; they do not take up residence on their prey
Coevolution Natural selection promotes traits that help prey escape predation It also promotes traits that make predators more successful at capturing prey
Predator-Prey Cycles Predator and prey populations may show an apparent correspondence PREY POPULATION PREDATOR POPULATION
Variation in Cycles An association in predator and prey abundance does not always indicate a cause and effect relationship Variations in food supply and additional predators may also influence changes in prey abundance
Prey Defenses Camouflage Warning coloration Mimicry Moment-of-truth defenses
Predator Responses Any adaptation that protects prey may select for predators that can overcome that adaptation Prey adaptations include stealth, camouflage, and ways to avoid chemical repellents
Parasitism Parasites drain nutrients from their hosts and live on or in their bodies Natural selection favors parasites that do not kill their host too quickly
Types of Parasites Microparasites Macroparasites Social parasites Parasitoids
Change in the composition of species over time Succession Change in the composition of species over time
Types of Succession Primary succession - new environments Secondary succession - communities were destroyed or displaced
Pioneer Species Species that colonize barren habitats Lichens, small plants with brief life cycles Improve conditions for other species who then replace them
Climax Community Stable array of species that persists relatively unchanged over time Succession does not always move predictably toward a specific climax community; other stable communities may persist
Cyclic Changes Cyclic, nondirectional changes also shape community structure Tree falls cause local patchiness in tropical forests Fires periodically destroy underbrush in sequoia forests
Restoration Ecology Natural restoration of a damaged community can take a very long time Active restoration is an attempt to reestablish biodiversity in an area Ecologists are actively working to restore reefs, grasslands, and wetlands
Community Instability Disturbances can cause a community to change in ways that persist even if the change is reversed
Species Introductions Introduction of a nonindigenous species can decimate a community No natural enemies or controls Can outcompete native species
Exotic Species Species that has left its home range and become established elsewhere Becomes part of its new community Can have beneficial, neutral, or harmful effects on a community
Endangered Species A species that is extremely vulnerable to extinction Close to 70 percent of endangered species have been negatively affected by exotic competitors
Nile Perch in East Africa Nile perch were introduced into Lake Victoria as a food source This predator ate native cichlids; drove many species to extinction Now Nile perch species is close to crashing
Rabbits in Australia Rabbits were introduced for food and hunting Without predators, their numbers soared Attempts at control using fences or viruses have thus far been unsuccessful
Kudzu in Georgia Imported for erosion control No natural herbivores, pathogens, or competitors Grows over landscapes and cannot be dug up or burned out May turn out to have some commercial use
Diversity by Latitude Diversity of most groups is greatest in tropics; declines toward poles Ant diversity
Why Are Tropical Species Rich? Resources are plentiful and reliable Species diversity is self-reinforcing Rates of speciation are highest in the tropics
Distance Effect The farther an island is from a mainland, the fewer species Closer islands receive more immigrants Species that reach islands far from mainland are adapted for long-distance dispersal and can move on
Distance Effect