BIOL227 Discussion 11 - Ecological Biodiversity PDF

Summary

This document discusses community ecology, focusing on species diversity, richness, and relative abundance. It explores interspecific interactions, competition, predation, herbivory, and symbiosis. Key ecological concepts such as ecological niches and resource partitioning are also examined.

Full Transcript

Community Ecology
 The biosphere Organelles
1 µm
Ecosystems Cell
Cells

Atoms

Molecules
10 µm
Communities Tissues

50 µm
Populations

Organs and organ systems
Organisms
Species Diversity

Species diversity of a community is the variety of organisms that
make up the community

It has two components:
1. Species Richness
Species richness is the total number of different species
in the community

2. Relative Abundance
Relative abundance is the proportion each species
represents of the total individuals in the community
Richness versus Abundance

Two communities can have
the same species richness but
a different relative abundance

A community with an even
species abundance is more
diverse than one in which one
or two species are abundant
and the remainder are rare
The basis for understanding community ecology:

Ecological interactions

Interspecific vs. Intraspecific Interactions
Interspecific Interactions
Ecologists call relationships
between species in a community
interspecific interactions

For example, two species engage in
interspecific competition for a limiting
resource, the result is detrimental to
one or both species (−/−).

Interspecific interactions affect
species survival and reproduction

Examples are competition,
predation, herbivory, symbiosis
(parasitism, mutualism, and
commensalism), and disease
Interspecific Interactions
Can have differing effects on the populations involved
Competition (-/-)

Interspecific competition
Occurs when different species
compete for a particular
resource that is in short
supply

Strong competition can lead to
competitive exclusion
The local elimination of one
of the two competing species
Competitive Exclusion
The ecological niche is the total of an
organism’s use of the biotic and abiotic
resources in its environment

The competitive exclusion principle (Gause’s
Law) states that two species competing for
the same limiting resources cannot coexist in
the same place

Can lead to the local elimination of one of
the two competing species, a process called
competitive exclusion.

Coexistence occurs when overlap between
niches is reduced
Experimental Evidence
Ecological Niche
The total requirements of a species for all resources and physical conditions determine
where it can live and how abundant it can be at any one place within its range.
The ecological niche of an organism depends not only on where it lives but also on what it
does.
Ecological Niche

Fundamental niche
Potential ecological niche for an organism
The fundamental niche is the niche that an organism would
occupy in the absence of competition

Realized niche
Niche an organism actually occupies
niche that an organism occupies in the presence of competition
Resource Partitioning
When competition between two
species with identical niches
does not lead to the local
extinction of either species

It is generally because evolution
by natural selection has resulted
in the modification of the
resources used by one of the
species.

Resource partitioning is the
differentiation of niches that
enables two similar species to
coexist in a community.
Character Displacement
Character displacement is the
tendency for characteristics to
be more divergent in sympatric
populations of two species

Competing species evolve
slightly different niches to
avoid competition

Reduces Interspecific
Competition

An example is variation in beak
size between populations of two
species of Galapagos finches
Predation (+/-)
Refers to an interaction
where one species, the
predator, kills and eats
the other, the prey
(+/– interaction)

Feeding adaptations of
predators include:
Claws, teeth, fangs,
stingers, and poison

Natural selection shapes
the body forms and
behaviors of both
predators and prey
Prey Strategies
Prey animals have evolved adaptations
that help them avoid being eaten.

Behavioral defenses include fleeing,
hiding, and self-defense.

Alarm calls may summon many
individuals of the prey species to mob
the predator.

Cryptic coloration, or camouflage -
makes prey difficult to spot

Aposematic coloration:
Warns predators to stay away from
prey
Aposematic coloration
Cryptic coloration
 In some cases, one prey
species may gain significant
protection by mimicking the
Batesian Mimircy
appearance of another

In Batesian mimicry
A palatable or harmless
species mimics an
unpalatable or harmful
model

A Batesian mimic is a sheep
in wolf's clothing.
 Müllerian Mimicry
Two or more species resemble each other
The animal mimics the attributes of a poisonous creature, when it
actually is itself is unpalatable
Predators will quickly adapt by avoiding this particular appearance
Herbivory (+/-)
Herbivory, the process in
which an herbivore eats
parts of a plant (+/–)

Has led to the evolution of
plant mechanical (spines,
tough leaves) and chemical
defenses and consequent
adaptations by herbivores

Milkweeds produce
chemicals that are
poisonous to all but a few
insects
Symbiosis
Any intimate or long-term association between two or more species

Symbiosis is always ‘inter-specific’; that is it occurs only between different species

Two main types of Symbiosis
1. Parasitism (+/-)
2. Facilitation

Facilitation is when one organism benefits and the other is unaffected or benefits as
well (MUTUALISM OR COMMENSALISM
1) Parasitism
In parasitism (+/-), one organism,
the parasite derives its nourishment
from another organism, its host,
which is harmed in the process

Endoparasites live within the
body of the host

Ectoparasites live and feed on
the external surface of the host.

Mites living in the trachea of
honeybees

Clog airways which eventually kills
them
Fruitbody of the fungus, growing
out of an infected ant that clings
itself to a tree
2) Commensalism (+/0)
One species benefits and the other is not significantly affected
Who benefits?
 One species benefits and the other is not affected (in any
known way)
These interactions hard to document…

An epiphyte is a plant that normally grows
on another plant for support. It is not
parasitic but uses the host plant for support Clownfishes & sea
only. anemones.
3) Mutualism
Mutualistic symbiosis, or
mutualism (+/+), is an
interspecific interaction
that benefits both species

A mutualism can be
Obligate, where one
species cannot survive
without the other

Facultative, where both
species can survive
alone
 Rhizobium &
legume plants

Coral: zooxanthallae & polyp

Humans & microbes Mycorrhizae: plant & fungus
Alga provides fungi with food (“fixed” organic carbon) & fungi provide alga /cyanobacteria with
minerals, water, shelter, secrete chemicals which ward off predators and repel microbes.

fungal hyphae
Lichen
structure: algae (or cyanobacteria)
Species with a Large Impact: Dominant Species
Dominant species are those that
are most abundant or have the
highest biomass

They exert powerful control over
the occurrence and distribution
of other species

Example: the sugar maple that
dominates the North American
forest

Dense and high tree canopy
reduces the light for species
living on the ground
Species with a Large Impact: Invasive Species

Invasive species,
typically introduced to a
new environment by
humans, often lack
predators or disease
Species with a Large Impact: Keystone Species
Species with a Large Impact: Foundation
Species (ecosystem engineers)
Ecosystems
Two Concepts About Ecosystems

1. Energy flow thru ecosystems (refer back to
lecture 2)

2. Cycling of chemical elements in ecosystems
 Primary Production in an Ecosystem

Primary production is the amount of light
energy converted to chemical energy by
autotrophs during a given time period

The extent of photosynthetic production
sets the spending limit for the energy
budget of the entire ecosystem

The amount of solar radiation reaching the
surface of the Earth limits the
photosynthetic output of ecosystems
 Food Webs
In real life, food chains are not this
simple as several different, but
interrelated (connected) food chains
combine together into a food web.

At the next level, carnivores also tend
to eat a number of different prey

This results in an interconnected food
web

Food webs describe the movement of
energy from one species to another in
the community
Nutrient Cycles in The Ecosystem
Nitrogen Cycle
Carbon Cycle
Water Cycle
The Phosphorus Cycle
Threats to Biodiversity
Species Diversity Endangerment