Ecological Communities And Ecosystems Lecture Slides PDF

Summary

This document is a lecture on ecological communities and ecosystems, focusing on topics like interspecific interactions, competition, niche, exploitation, mimicry, herbivory, parasitism, mutualism, and commensalism. It also discusses species diversity, trophic structure, keystone species, and foundation species within community ecology.

Full Transcript

Module 1.2
Ecological
Communities and
Ecosystems
Interspecific Interactions between populations in
Interactions a biological community

 +: the interacting individual benefits
 : the interacting individual is harmed

 0: no effect on the interacting individual
 Interspecific Any -/- interspecific interaction in
which different species compete for
competition the same limited resources

?
Limited resources can be biotic or abiotic
(biotic; abiotic)
The interspecific competition between two closed
? than that
related species is typically more intense
between two unrelated species (as intense as;
more intense than; less intense than)

Figure 41.3 Resource partitioning among
Dominican Republic lizards
 The specific set of biotic and abiotic
Ecological
resources used by an organism and
Niche its role within its ecosystem

 Physical home or habitat
 Physical and chemical environmental factors
necessary for survival and reproduction
 Energy and materials

Figure 41.3 Resource partitioning among
Dominican Republic lizards
 The specific set of biotic and abiotic
Ecological
resources used by an organism and
Niche its role within its ecosystem

Do different species of Anolis lizards shown
in Figure 41.3 share aspects of their
ecological niche? Yes?
Do A. distichus and A. insolitus shown in
Figure 41.3 have the same ecological
niche? No ?

Figure 41.3 Resource partitioning among
Dominican Republic lizards
 If two species occupy exactly the same
Competitive niche, strong competition should lead
Exclusion to local elimination of an inferior
competitor

 Have different niches — can coexist
 Have identical niches — one
excludes the other

Figure 41.3 Resource partitioning among
Dominican Republic lizards
 One or more significant differences that
Resource ecologically similar species develop in
Partitioning their niches to reduce interspecific
competition

Resource partitioning by
occupying a different
? area of the habitat
allows seven species of Anolis lizards to
coexist in a community in close proximity
since competition for food ?
is reduced

Figure 41.3 Resource partitioning among Dominican Republic lizards
 Character differences between two similar
Character
species are greater when populations are
Displacement sympatric than allopatric

 There is more overlap in the traits of
A
the allopatric, or geographically
separate, populations
B  Interspecific competition drives
character displacement by causing
C natural selection for characters that
compete less

Figure 41.5 Character displacement: indirect evidence
of past competition.
 Character differences between two similar
Character
species are greater when populations are
Displacement sympatric than allopatric

The character being displaced in this
A
?
example is beak depth
On Floreana and San Cristobal islands,
B G. fuliginosa individuals with
shallower
? beaks and G. fortis
C individuals with deeper ?beaks
probably had less competition for food

Figure 41.5 Character displacement: indirect evidence
of past competition.
Competitive Exclusion

?
Intraspecific competition is usually a more intense form of
competition controlling population size (intraspecific;
interspecific)

?
Intraspecific competition exerts strong density-dependent
environmental resistance, limiting population size
(density-dependent; density-independent)
 Any +/- interspecific interaction in which
Exploitation individual of one species benefit by feeding
on living individuals of another species

 Predation

 Herbivory

 Parasitism
 An exploitative interaction in which an individual
Predation of one species, the predator, kills and eats an
individual of the other species, the prey

Any predatory
? species can be a predator

A. animals
B. plants
C. fungi
D. bacteria
E. protists
 One species resemble the appearance,
Mimicry sound, smell, or behavior of other species
to deter predators or to entice prey

 Batesian mimicry: a palatable or harmless
prey species resemble an unpalatable or
harmful model
 Predators also use aggressive mimicry to
attract or sneak up on prey

Figure 41.6c Batesian mimicry

https://www.youtube.com/watch?v=_5CRKTgFal0 https://www.youtube.com/watch?v=DDwwTE-P-WU
 An exploitative interaction in which an
Herbivory individual of one species, an herbivore,
eats parts of a plant or alga

In herbivory, herbivores
? kill plants or alga
usually don’t

A. kill
B. don’t kill

A West Indian manatee
Figure 41.7 A marine herbivore.
 An exploitative interaction in which an
Parasitism individual of one species, the parasite, derives
its nourishment from another organism, its host

 Parasites do not kill their hosts immediately
 Many parasites have complex life cycles

In Figure 41.8, cocoons of the parasitoid
wasp are ectoparasites
? of the tobacco
hornworm
A. endoparasites
B. ectoparasites

Figure 41.8 A parasitoid invasion.
 An exploitative interaction in which an
Parasitism individual of one species, the parasite, derives
its nourishment from another organism, its host

 Many parasites have multiple host species

What is the interspecific relationship
between the two hosts of the malaria
parasite of humans?

Parasitism: Anopheles
?
mosquitos are ectoparasites of
humans

https://www.cdc.gov/malaria/about/
 Any +/+ interspecific interaction in which
Mutualism members of both interacting species
benefit

 In some mutualisms, one or both
species cannot survive without the
other
 In other mutualisms, both species can
survive alone

? not all, mutualistic
Many, but
relationships are symbiotic (Few;
Many; All)
Clownfish and anemone fish

Figure 41.9 Mutualism between acacia trees
and ants.
 Any +/0 interspecific interaction that benefits
Commensalism individuals of one species without harming or
helping individuals of the other species

 Commensalism: an interaction that benefits
individuals of one species without harming or
helping individuals of the other species
 A commensal relationship may become
mutualistic

How can the commensal relationship
between cattle egrets and the
African buffalo shown in Figure
41.10 become mutualistic?
Figure 41.10 Commensalism between cattle
egrets and an African buffalo
Interspecific Interactions between populations in
Interactions a biological community

 Interspecific competition: ?
 Predation: +/ ?
 Herbivory: +/ ?
 Parasitism: +/ ?
 Commensalism: +/ ?
 Mutualism: +/+?
 The species richness and relative
Species Diversity abundance of species in a biological
community

 Species diversity increases with the species
richness and evenness

Community 1 and community 2 have the
same tree species ? richness (tree species
diversity; tree species richness; relative
abundance of tree species; all three)

Community 1 ? has greater tree
species diversity (1; 2)

Figure 41.12
 The species richness and relative
Species Diversity abundance of species in a biological
community

 Communities with higher diversity
usually able to produce more
biomass and resist invasive species

Typically, only ?
a few species have an
especially large impact on community’s
diversity and structure

A. all
B. most
C. a few
D. no Figure 41.12
 The feeding relationships between
Trophic Structure species in a community

 Food chains: linear feeding
relationship from producers to
top carnivores
 A food web: non-linear complex
trophic interactions from
producers to top carnivores

Figure 41.15 An Antarctic
Figure 41.14 Examples of terrestrial and
Marine Food Web
marine food chains.
 The feeding relationships between
Trophic Structure species in a community

In the Antarctic ocean,
phytoplankton are
primary producers
?
A. producers
B. primary consumers
C. secondary consumers
D. tertiary consumers

Figure 41.15 An Antarctic
Figure 41.14 Examples of terrestrial and
Marine Food Web
marine food chains.
 The position of a species in the
Trophic Level trophic structure of a community

 Primary producers (autotrophs): build
organic molecules from inorganic sources
 Primary consumers (herbivores): feed
directly and exclusively on producers
 Higher-level consumers: feed on
herbivores or other carnivores
 Decomposers: consumers that derive their
energy from detritus

Figure 42.4 An overview of energy and nutrient
dynamics in an ecosystem.
 The position of a species in the
Trophic Level trophic structure of a community

Squids can be C, D, or E?
in this Antarctic Marine food wed

A. producers
B. primary consumers
C. secondary consumers
D. tertiary consumers
E. quaternary consumers
Figure 41.15 An Antarctic
Marine Food Web
 Foundation A species that provides food/habitats
or exploit key resources due to their
Species high abundance or large size

 Foundation species dominates an ecosystem
in abundance and influence

?
Corals are dominant consumers
in a coral reef

A. producers
B. consumers

A coral reef. "Community ecology: Figure 13," by
OpenStax College, Biology, CC BY 4.0. Original work
by Jim E. Maragos, USFWS.
 A species that exerts a disproportionately
Keystone
large effect on community structure relative
Species to its abundance

In this classic experiment of community
ecology conducted in 1963, Dr. Robert
?
Paine discovered a sharp reduction
in species diversity of the intertidal zone
occurred within 1 and half year after the
sea stars were removed (no change; a Figure 41. 16 A sea star Pisaster ochraceus

reduction; an increase)
The sea stars were a keystone species
in the intertidal zone because
they kept the mussels
? in check
 A species that modify their environment in a
Ecosystem
significant manner, creating new habitats or
Engineers modifying existing ones

Ecosystem engineers such as
beavers change the distribution
and abundance of many other
?
species mostly by indirect
interactions

A. direct
B. indirect

Figure 14.17 Beavers as ecosystem engineers
Species with a Large Impact on Community
Structure

Most keystone?species have been recognized only after
their loss has had dramatic, unforeseen consequences
? species are more likely to be top predators
Keystone

A. foundation species
B. keystone species;
C. ecosystem engineers
 Pathogens Disease-causing agents

 Pathogens can affect
communities locally and
globally
 Zoonotic pathogens: infect
and cause disease in both
animals and humans
 Vectors: organisms that can
transmit infectious pathogens
between humans

SARS-CoV-2
 Pathogens Disease-causing agents

SARS-CoV-2 is a zoonotic
pathogen primarily spread among
humans though direct? contact
(a vector; direct contact)

Lyme ?
disease is a vector-borne
zoonotic pathogen (Malaria;
Lyme disease)

SARS-CoV-2
 Disturbances
New Zealand ecologists recorded
New Zealand streams the numbers of invertebrate
species in streambeds that
experienced different intensities
and frequencies of flooding. The
largest numbers of species were
present in streambeds with
intermediate
? disturbances.
Figure 41.19 Testing the intermediate disturbance hypothesis.
A. no
B. mild
C. intermediate
D. intense
 Disturbances
New Zealand streams
Low ? levels of disturbance
allow competitively dominant species
to exclude less competitive ones
(high; low; intermediate)

High ? levels of disturbance
exclude many slow-growing or slow-
Figure 41.19 Testing the intermediate disturbance hypothesis.
colonizing species (high; low;
intermediate)
 Ecological The sequential change in community
composition during colonization
Succession following a major disturbance

 Primary succession occurs
“from scratch,” where there is
no trace of a previous
community
 Secondary succession
begins with some remains of a
Figure 41. 21 Glacier retreat and succession at Glacier disrupted community
Bay, Alaska
 Ecological The sequential change in community
composition during colonization
Succession following a major disturbance

The succession at Glacial Bay,
Alaska after retreat of the glacier
since 1760 provides a valuable
field research opportunity for
observing primary ?
succession (primary; secondary)
Figure 41. 21 Glacier retreat and succession at Glacier
Bay, Alaska
 Ecosystems
 Law of conservation of mass: matter
cannot be created or destroyed

An entire ecosystem can? be
affected by changes in a single
component (can; can’t)
The mass of a given ecosystem
isn’t
? a constant (is; isn’t)

Figure 42.4 An overview of energy and nutrient
dynamics in an ecosystem.
Biogeochemical The pathways nutrients follow between
Cycles communities and reservoirs

 Limiting nutrients regulate
community’s structure and
composition of ecosystems

Figure 42.14 Visualizing Biogeochemical Cycles
Biogeochemical The pathways nutrients follow between
Cycles communities and reservoirs

Carbon, oxygen, nitrogen, water, and sulfur ?
cycle globally (phosphorus; sulfur; potassium; calcium)
Nutrient cycles involve both biotic?and abiotic components
(biotic; abiotic; both)
Phosphorus?and nitrogen are usually the limiting nutrients
in photic zones of aquatic ecosystems (phosphorus;
carbon, oxygen, nitrogen, water)
 Hydrologic Cycle
Figure 42.15 The water cycling

 The major reservoir: the oceans
 Key processes: evaporation, transpiration,
condensation, precipitation, and
movement through surface and
groundwater Movement over
land by wind

 Forms available to life: water liquid or Precipitation Evaporation
Precipitation
over land

vapor over ocean from ocean

Evapotranspiration
from land

The hydrologic cycle is primarily
driven by solar heat ?energy Percolation
through

(solar energy; photosynthesis; Runoff and
soil

cellular respiration) groundwater
 Carbon Cycle
Figure 42.15 the carbon cycle

 The major reservoirs: sedimentary
rocks, fossil fuels, the atmosphere,
the oceans, biomass
 Kay processes: photosynthesis,
cellular respiration, volcanic activity
and burning fossil fuels and wood
 Forms available to life: CO2 and
solute
 Carbon Cycle
Figure 42.15 the carbon cycle

? rocks are the largest
Sedimentary
reservoir for carbon (sedimentary
rocks, fossil fuels, the atmosphere, the
oceans, biomass)
The atmosphere ? and the oceans are
the major short-term reservoirs
(sedimentary rocks, fossil fuels, the
atmosphere, the oceans, biomass)
 Nitrogen Cycle
 The major reservoir: the atmosphere
 Key processes
 nitrogen fixation of N2 to ammonia (NH3) by
nitrogen-fixing bacteria
 nitrification of NH4+ to nitrate (NO3–) by nitrifying
bacteria
 incorporation of nitrogen from NO3– , NH4+ and
amino acids into biological molecules by producers
 denitrification of NO3– back to N2 by denitrifying
bacteria
 the fixing of nitrogen for fertilizer and burning fossil
fuels by humans
 Phosphorus Cycle

 The major reservoir: rocks
 Key processes: weathering of rocks,
incorporation of PO43+ into biological
molecules by plants, decomposition and
excretion , human production of
phosphate fertilizers
 Almost all phosphorus remains as PO43+
throughout its cycles
  List three types of ecological interaction and predict how
these interactions will affect a species
 Link the concept of resource partitioning to the
phenomenon of competitive exclusion
 Diagram a trophic structure or food web
 Contrast foundation species, keystone species, and
ecosystem engineers
Learning  List three types of disturbances and predict how the
Objectives effects on an ecosystem over time
 Predict how a change in the number of decomposers
would affect a biogeochemical cycle
 Diagram the water, carbon, phosphorous or nitrogen
cycle
 Relate the concepts of community ecology, ecological
disturbances, and zoonotic pathogens to predict the
emergence of pandemics
 Review Question 1

Which best describes resource partitioning?

A. avoiding direct competition.
B. encouraging mutualistic interactions.
C. enabling prey to hide from predators.
D. creating new resources.
E. allowing abiotic factors, such as climate or nutrient
availability, to influence the community
 Review Question 2

Niche partitioning enables species to coexist by
_________.
A. Two species can coevolve to share identical niches.
B. Competitive exclusion results in the success of the
superior species.
C. A climax community is reached when no new niches are
available.
D. Slight variations in niches allow similar species to coexist.
E. Differential resource utilization results in the decrease in
community species diversity.
 Review Question 3
Sympatric populations of closely related species, which could
compete for resources, show more differences in body
structures and the resources they use than do allopatric
populations. The term that describes this is __________.

A. exploitation
B. parasitism
C. character displacement
D. competitive exclusion
E. mutualism
 Review Question 4
Robert Paine removed Pisaster, an uncommon sea star, from some
communities and measured species diversity. Species diversity
dropped dramatically when Pisaster was not present. From this, one
can conclude that ___________
A. uncommon species are more vital to the community
than common species.
B. predators are more vital to the community than prey.
C. Pisaster likely consumed dominant organisms.
D. Robert Paine’s experiment was poorly designed.
E. removing one species always hurts the community.
 Review Question 5

Why does a natural disturbance favor the process of
succession?

A. It kills off all of the invasive species, leaving only native
species.
B. It allows for secondary succession to occur because the
seeds that are left behind colonize quickly.
C. It often leaves behind favorable conditions that allow for the
rapid growth of new species.
D. It saves the climax community and destroys the less-evolved
species.
 Review Question 6

A species that exerts control over community
structure by dramatically altering the physical
environment is called a(n) ___________
A. foundation species.
B. keystone species.
C. dominant species.
D. ecosystem engineer.
 Review Question 7

Which of the following communities would have a
higher diversity value?

A. A community with 12 species where all species have roughly
equal abundance.
B. A community with 12 species that has two species with high
abundance and 10 species with relatively low abundance.
C. Neither community A nor B is equally diverse because they
have the same number of species.
 Review Question 8

Unlike energy, matter cycles within an ecosystem.
This means that ___________.

A. chemicals cannot be lost from an ecosystem

B. a continuous input of matter from outside the system is
required to maintain an ecosystem

C. elements can be passed between living and nonliving
components of the ecosystem indefinitely

D. matter is being continually converted into heat and
back into matter
 Review Question 9

The biogeochemical cycle that excludes gases is
_________
A. phosphorus.
B. nitrogen.
C. carbon.
D. water.
 Review Question 10

Most of the atmosphere is nitrogen gas (N2).
_____________________ can convert nitrogen
gas into a form accessible to life.

A. plants
B. primary producers
C. nitrogen-fixing bacteria
D. decomposers