Post on 05-Jan-2016
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Chapter 4: Biological Communities Chapter 4: Biological Communities and Species Interactionsand Species Interactions
Understand the fundamental factors driving community development
I. Who Lives Where and Why?I. Who Lives Where and Why?
A. Critical Factors and Tolerance Limits– Examples of limiting conditions are
temperature, moisture levels, nutrient supply, and soil
– Liebig’s principle (law) states, the single factor in shortest supply relative to demand is the critical determinant to species distribution
• Called the principle of limiting factors
I. Who Lives Where and Why?I. Who Lives Where and Why?
A. (cont)– Shelford used Liebig’s principle to formulate
that there are maximums and minimums for environmental factors (resources)
• Called tolerance limits• Zones of intolerance are areas of species extinctions
in that habitat• The factor closest to the zone of intolerance
determines where an organism can survive• Sometimes called Shelford’s Law
I. Who Lives Where and Why?I. Who Lives Where and Why?
A. (cont)– Some variations of the 2 rules exist
• Could be multiple factors working together to limit distribution
– Some organisms have a specific critical factor• Passenger Pigeons (land), Saguaro Cacti (cold)
– Some limitations may occur during a specific portion of the life cycle
• Desert Pupfish (temperature and salinity levels for juveniles only)
I. Who Lives Where and Why?I. Who Lives Where and Why?
A (cont)– Indicator species are species with defined
tolerance limits and are used to indicate the health of the habitat
• For some, if missing there is a problem• For some, if present there is a problem
– Environmental indicators are species of organisms which can give specific information about a habitat
• May indicate specific nutrients present or missing• May indicate pollution
I. Who Lives Where and Why?I. Who Lives Where and Why?
B. Natural Selection, Adaptation, and Evolution– 1. General Information
• Organisms adapt to special conditions– One form of adaptation is acclimation
• Organisms experiences physiological modifications or changes
• Non-permanent, reversible– Another form is genetic, part of evolution
• Will change the population• Inheritance of specific traits• Natural selection allows the organism “best
suited” for an environment to reproduce
Darwin’s FinchesDarwin’s Finches
I. Who Lives Where and Why?I. Who Lives Where and Why?
B. (cont)• Acts on pre-existing genetic diversity
– Mutations can add to the genetic diversity
• Genes that suit the environment will become the dominant trait over time
• Darwin’s finches is a good example– Common, general ancestor becoming specialized
multiple current species
• Also called selective pressure
I. Who Lives Where and Why?I. Who Lives Where and Why?
B. (cont)– Factors affecting selective pressure are
• Physiological stress due to inappropriate levels of some critical factors
• Predation, parasitism and disease• Competition• Luck?
• Geologic isolation can aid in different gene expression
– Possibly leading to speciation
I. Who Lives Where and Why?I. Who Lives Where and Why?
B. (cont)• Natural Selection and Adaptation can cause
similar species or 2 groups of the same species to drift genetically apart
– Called Divergent Evolution
• Natural Selection and Adaptation can cause 2 different species to drift genetically together (considered the same species)
– They look and act alike– Called Convergent Evolution
I. Who Lives Where and Why?I. Who Lives Where and Why?
C. The Ecological Niche– 1. General Information
• Habitat is the place where an organism lives• Ecological niche is a description of the role
of a species in a biological community– Niches can change as physical characteristics
change
I. Who Lives Where and Why?I. Who Lives Where and Why?
C. (cont)– 2. Law of competitive exclusion
• States that no two species will occupy the same niche and compete fro exactly the same resources in the same habitat (for a long period of time)
• Creates niche specialization, which creates behavioral separation, when two niches overlap
Paramecium GraphParamecium Graph
Resource partitioning and niche Resource partitioning and niche specializationspecialization
I. Who Lives Where and Why?I. Who Lives Where and Why?
C. (cont)– 2 (cont)
• The number of niches is determined by the resources and the extent by which they can be separated
– Some animals can share resources, but use them at different times
• Ex. Owls and Hawks, Bats and Mockingbirds
– Some animals can use the same resources, but use different portions of the same resource
• Ex. Finches, MacArthur's Warblers, Flickers and Woodpeckers
MacArthur's Warblers : Splitting the MacArthur's Warblers : Splitting the same resourcesame resource
Left to right: Cape May, Yellow-rumped, Black-throated Green, Left to right: Cape May, Yellow-rumped, Black-throated Green, Blackburnian, and Bay-breasted Warblers. Black areas in stylized conifers Blackburnian, and Bay-breasted Warblers. Black areas in stylized conifers show where feeding is concentrated.show where feeding is concentrated.
II. Species Interactions and II. Species Interactions and Population DynamicsPopulation DynamicsA. Predation
– An organism that feeds directly on another organism (living)
• Yes, Herbivores are predators!• Scavengers, detritovores and decomposers
(that feed on dead organisms) are NOT predators
• Parasites? , pathogens
– Predation is an influence on population balance in a community
II. Species Interactions and II. Species Interactions and Population DynamicsPopulation Dynamics
A. (cont.)• Involves 3 scenerios
– 1. Influences all stages of the life cycle for both predators and prey– 2. influences food obtaining mechanisms– Influences prey- predator adaptations to resist or encourage
predation
– As prey species mature, the predators change– As predators mature, the prey species change– Tend to be the most successful with the old and the
young (book says least fit)– Some prey have created defenses
• Spines, thorns, thicker bark, poisonous chemical mimicry, speed, etc
II. Species Interactions and II. Species Interactions and Population DynamicsPopulation DynamicsB. Keystone Species
– A species or group of species whose impact on its community is much larger and more influential than would be expected from mere abundance
– At one time they were thought to be top predators
– May be a species that has a significant impact on other organisms
• Ex: tropical figs, sea otters, prairie dogs
Keystone Species: Prairie DogsKeystone Species: Prairie Dogs
Keystone Species: Sea OttersKeystone Species: Sea Otters
Keystone Species: American BeaverKeystone Species: American Beaver
II. Species Interactions and II. Species Interactions and Population DynamicsPopulation Dynamics
B. (cont.)– In some conditions microscopic organisms
may be the keystone species• Ex: mycorrhzae (root fungus)
C. Competition– When organisms compete over resources– 2 types:
• Interspecific: between organisms of different species• Intraspecific- between organisms of the same species
Interspecific CompetitionInterspecific Competition
Intraspecific Competition: Intraspecific Competition: TerritoriesTerritories
II. Species Interactions and II. Species Interactions and Population DynamicsPopulation Dynamics
C. (cont.)– Interspecific competition is responsible for
niche specificity– Physically designed to tolerate conditions,
acquire foods, and reproduce at a time different from competitors
• Animal kingdom’s “arms race”• Bigger, stronger, faster, and smarter
– Avoids fighting as much as possible
– Where 2 different species that occupy the same niche compete in a habitat, one species will out compete the other
II. Species Interactions and II. Species Interactions and Population DynamicsPopulation DynamicsC. (cont)
• Described as the Lotka-Volterra Competition Model
• Mathematical equations to predict which species will out compete the other
• Depends on 2 factors– 1. The number of individuals of species 2
present; and (2) the intensity of the interference with species 1’s growth; or the intensity of the competition of species 2 on species 1
– It will be a negative factor
Lotka-Volterra Competition Model Lotka-Volterra Competition Model
II. Species Interactions and II. Species Interactions and Population DynamicsPopulation DynamicsC. (cont.)
– Intraspecific competition is more intense
• Battling with organisms with the exact same set of needs
• Plants have to battle with mature adults• Adaptive tendencies lead to greater
dispersal of seeds• Territories are a direct result of intraspecific
competition
II. Species Interactions and II. Species Interactions and Population DynamicsPopulation Dynamics
C. (cont.)• Battle for an area with all of the needs of the
organism at all stages of the life cycle– Those animals without all either don’t reproduce or don’t
reproduce successfully
D. Symbiosis– Interactions between species
• Not always antagonistic
– Intimate living together of members of two or more species
II. Species Interactions and II. Species Interactions and Population DynamicsPopulation DynamicsD. (cont.)
– 4 types of symbiosis• Commensalism- one benefits while another
has no apparent effect• Mutualism- both organisms benefit• Predator/Prey- one benefits while the other
dies• Parasitism- one benefits the other has no
effect or bad effect
II. Species Interactions and II. Species Interactions and Population DynamicsPopulation DynamicsE. Defensive Mechanisms
– Toxic chemicals, body armor, similar coloration, and others to defend against predation
• Poison ivy, thorns• Batesian mimicry• Mullerian mimicry, 2 different species
unpalatable and dangerous looking very similar
III. Community PropertiesIII. Community Properties
General Information– Try to understand the factors which make up
the properties involving communities• Productivity, diversity, complexity, resilience,
stability, and structure
A. Productivity– Photosynthetic rates are regulated by light
levels, temperature, moisture, and nutrient availability.
III. Community PropertiesIII. Community Properties
A. (cont.)– Corn and sugar cane; under ideal
conditions, in the tropics can approach productivity as high as the rain forest
– A very small amount of available sunlight is captured by photosynthetic communities
B. Abundance and Diversity– Abundance is the total number of
organisms of a species in an area
III. Community PropertiesIII. Community Properties
B. (cont.)– Diversity is the number of different
species in an area– Abundance and diversity are inversely
related• High abundance means low diversity• High diversity means low abundance
– Diversity decreases away from the equator and toward the poles
III. Community PropertiesIII. Community Properties
B. (cont.)– Abundance increases away from the
equator and toward the poles– Diversities decreases moving upward in
attitudeC. Complexity and Connectedness
– Complexity is the number of species at each trophic level and the number of trophic levels in a community
III. Community PropertiesIII. Community Properties
C. (cont.)• A diverse community may not be a complex
community• Tropical rainforests have many trophic
levels that are compartmentalized – Called guilds
• Species that occupy the same trophic level• Fruit enters, leaf nibbles, seed gnawers, etc
III. Community PropertiesIII. Community Properties
D. Resilience and Stability– 3 Types
• 1. constancy, lacks fluctuations in composition and function
• 2. inertia, which indicates resistance to perturbations
• 3. renewal, which is the ability to repair damage after disturbances
III. Community PropertiesIII. Community Properties
D. (cont)– MacArthur believed the more complex a
community the more stable and resilient the community will be when disturbed (studies show no real consistency with this conclusion)
– Disturbances are based on the organism
• Ex. Earthquakes, flooding, traveling, spitting, etc.
III. Community PropertiesIII. Community Properties
E. Edges and Boundaries– Areas between 2 adjacent and different
communities– Edge effect is the relationship of communities
and the organisms that inhabit the edge of the 2 communities or habitats
• Considered secondary habitats
– Some boundaries are sharp and distinct, called edges
III. Community PropertiesIII. Community Properties
E. (cont)– When the 2 habitats or communities blend
together, it is called a boundary– Edges and boundaries are also called
Ecotones• Sharp divisions are called closed communities• Boundary divisions where many species cross are
called open communities
– Adjacent communities may be important for species that need both types during different stages of development in the life cycle
IV. Communities in TransitionIV. Communities in Transition
A. Ecological Succession– Transition of communities in an area
over time– 2 types
• Primary Succession – development starts with a site that is newly broken rock or an area unoccupied previously by organisms
– Starts with pioneer species, such as lichens and bacteria
IV. Communities in TransitionIV. Communities in Transition
A. (cont)• Secondary Succession – an existing
community is disrupted and a new, previous, community redevelops in the habitat or community
– Caused by wildfires, or farmland restoration• Starts with weeds or grasses, when dealing
with a fire (depends on the severity of the fire)
• Starts with grasses and shrubs when dealing with overgrown farmland
IV. Communities in TransitionIV. Communities in Transition
A. (cont)• Typical primary succession
– Rocks, lichens, weeds, grasses, shrubs, conifers, deciduous trees (TDF)
• Typical secondary succession– Climax community, fire, weeds, grasses, shrubs,
coniferous trees, deciduous trees– May be much faster and may skip some steps,
depending on what community surrounds the fire area and what plants are ready to spread seeds into the open area
IV. Communities in TransitionIV. Communities in Transition
B. Introduced Species and Community Change– Introduced species are non-native species – They can replace existing organisms or (by out
competing them for the same resources) or– They can wipe out an unintended species
• Ex. Mongooses in Hawaii