principlesofecology-141216082016-conversion-gate02.ppt

ECOLOGY & EVOLUTION
DETAILS
By
Vaibhav Kumar Maurya
PhD

Ecology is the scientific study
• of the interactions between organisms and their environment
• Interactions between organisms and their environment
Components of ecology
• Abiotic factors – non-living parts
of an organism’s environment
– Air currents, temperature,
moisture, light, soil
• Biotic factors – all the living
things that inhabit the environment

Principles of Ecology
• Ecology – study of
relationships between
living and nonliving parts
of the world
• Ernst Haeckel (1866) – first
to use the word to name the
study of how organisms fit
into their environment

Levels of Organization
Organism
Population
Community
Ecosystem
Biosphere
Biome

Niche vs. Habitat vs. Ecosystem
• Ecosystem – all the organisms in a given area and the
abiotic factors that affect them
• Habitat – place an organism lives out its life
• Niche – role and position a species has in its
environment
– Includes all biotic and abiotic interactions as an organism
meets its needs for survival
– If two species are competing for the same niche, one will
most likely drive the other out and take control of the niche.
• What is your niche?

Niche vs. Habitat vs. Ecosystem
A great blue heron that lives around the
Wye Marsh is part of the Wye river
ecosystem. The heron and its mate eat
fish, frogs, salamanders, snakes, crayfish,
mice, aquatic insects, crickets,
grasshoppers, and a variety of other
insects in Georgian Bay and the Wye
Marsh and build a nest in a tree along side
the marsh.
• What is the heron’s habitat?
• What is the heron’s niche?
• What is the heron’s ecosystem?

Relationships
• All living things form
relationships with other
living things
• Symbiotic Relationship
– a relationship between
organisms of two
different species that live
together in direct contact

Commensalism
• One organism benefits – The other is not
affected
– Examples
– Spanish moss on a tree
– Barnacles on a whale
– Burdock seeds on a passing animal

Mutualism
• Both organisms benefit
– Acacia tree and ants (Pseudomyrmex sp.) – tree provides
food for the ants and the ants protect the tree from animals
that would eat the leaves
– Lichens: algae and fungus living together.
Algae provides food (photosynthesis)
and the fungus provides protection and
attaches the lichen to the rock or
wood where it lives.

Parasitism
• One organism benefits,
the other is harmed
– Some live with in the host
• Tapeworms
• Heartworms
• Bacteria
– Some feel on the external surface of the host
• Ticks
• Fleas
• Mistletoe
– Most do not kill their host
(at least not quickly)

Ecosystem Requirements
• #1 - Continuous supply of Energy
• #2 – A flow of energy from one population to
another

Obtaining Energy
• Autotrophs - use energy from
the sun or energy stored in
chemical compounds to produce
energy
• Heterotrophs – must consume
their energy
– Herbivores
– Carnivores
– Omnivores
– Detritivore (AKA decomposers)

Herbivores
• Eat plants (autotrophs)

Carnivores
• Eat other heterotrophs
– Predators – kill their own food
– Scavengers – eat animals that are already dead

Omnivores
• Eat both autotrophs and heterotrophs (plants
and animals)

Decomposers and Scavengers
Decomposers – decompose organic matter and
return nutrients to soil, water, and air.
Scavengers consume dead organisms.
– Ex. fungus, bacteria

Energy Flows through an Ecosystem in a Complex
Network of Feeding relationships called a FOOD
WEB.

Energy Pyramid
• The energy pyramid is made of several trophic levels
• A Trophic Level (or feeding level) is a group of
organisms whose feeding source is the same number
of steps from the Sun.
– Primary Producers (Autotrophs) are the First Trophic
Level.
– Primary Consumers (Herbivores) are the Second
Trophic Level.
– Secondary and Tertiary Consumers (Carnivores and
Omnivores) are the Third and
Fourth Trophic Levels.
– Most Animals feed at more
than one Trophic Level.

Trophic Levels
• Energy is Lost or Used as it Flows through the
Trophic Levels of an Ecosystem.
• Producers (Plants) absorb Energy from the Sun, but
only about ½ of the Energy capture from the Sun
becomes part of the Plants Body. The other ½ is used
for Living and Growing or Lost as HEAT.
• At each Trophic Level, the Energy stored in an
organism is about 1/10 that of the Level Below it.
(10%).

Trophic Levels
• Because Energy diminishes at each successive
Trophic Level, Few Ecosystems can contain
more than 4 or 5 Trophic Levels.
• Organisms at Higher Trophic Levels, Large
Carnivores, tend to be Fewer in number than
those at Lower Trophic Levels, Producers.

Number and Biomass Pyramids
• The number of
organisms at
each trophic
levels decreases
as you step up
the pyramid.
• Biomass (living
organic matter) is
reduced at each
trophic level as
well

Ecology and evolutionary biology are closely
related sciences
•Events that occur in the framework of ecological time
(minutes, days, years) translate into effects over
evolutionary time (decades, millennia).
•Example: Hawks feeding on mice impact mouse
population and may eventually lead to selection for mice
with fur as camouflage.
• Ecological research scale ranges from individuals to the
biosphere

What determines distribution & abundance of species?
Two classes of answers
1. Contemporary, local factors (domain of traditional
Ecology)
2. Historical factors (= evolutionary ones)
•Why different species live in different environments?
(Adaptation)
•E.g., long necked giraffe in savannas of Africa (widely
dispersed, umbrella-shaped trees); white coated polar
bear in Arctic (invisible to prey)

Nature selection as a force of evolution
What is Darwin’s natural selection?
The differential success (survival and reproduction) of
individuals within the population that results from their
interaction with their environment.
“Survival of fitness, elimination of ‘inferior’ individual”
Two conditions (assumptions):
• 1. There is variation in populations. Variation is heritable.
• 2. In every generation some organisms are more successful at
surviving and reproducing than others. Survival and reproduction
are not random, but are related to variation among individuals.
Organisms with best characteristics are ‘naturally selected.’
If 2 conditions are met then the population will change from one
generation to the next. Evolution will occur.

Evidence of natural selection
• Evolution of beak shape in Finches.
• Peter and Rosemary Grant’s (and colleagues) work
on Medium Ground Finches Geospiza fortis.
• Darwin’s Finches
Genetic studies show all arise from a single ancestral
species.

Heritability is an essential feature of NS
Heritability: individual’s characteristics are passed from one generation to the next. Measured
as proportion of the variation in a trait in a population that is due to variation in genes.
• Mendel’s genetics and inheritance
Genetic variation is the ingredient for Natural Selection
Sources of genetic variation
– Mutation: inheritable changes in a gene or a chromosome
• Gene mutation: (point mutation)
• Chromosome mutation
– deletion, duplication, inversion, translocation
– Genetic recombination
Sexual reproduction
two individuals produce haploid gametes (egg or sperm) – that combine to form
a diploid cell or zygote.
– Reassortment of genes provided by two parents in the offspring
– Increases dramatically the variation within a population by creating new
combinations of existing genes.
Asexual reproduction: less variation (only mutation)

Evolution is a change in gene frequency
• Evolution is a change of gene frequencies within a population (or species)
over time
– Individuals do not evolve, populations evolve
– Focus on gene pool, collective
But why do we see populations are still the ‘same’ over many generations?
• The Hardy-Weinberg Principle:
Gene frequencies will remain the same in successive generations of a
sexually reproducing population if the following five conditions hold:
– Random mating
– There is no mutation
– The population is very large
– There is no selection
– There is no migrations (isolated from other populations)

Five Causes of evolution
• Mutations
• Gene flow - Emigration and immigration of individuals (Flow of alleles)
• Genetic Drift – Changes in the gene pool of a small population due to chance
• Nonrandom mating: (AA mates AA, Aa)
• Natural selection
Speciation and mechanisms
• Speciation: splitting of one species into 2 different species.
• Concept of species:
– Biological Species: a species is a group of organisms whose individual
have the potential to interbreed and produce fertile offspring.
• Reproductively isolated: don’t produce fertile hybrids
• Natural conditions: artificial breeding doesn’t count. For example,
artificial insemination, keeping 2 species locked up together.
– Morphological species: members of the same species look similar to
each other. Many examples of organisms that look similar but can’t
produce fertile offspring.
– No one species concept applies to all organisms

Mechanism of Speciation
– Allopatric speciation (probably most vertebrates)
• allopatric species occupy areas separated by time or space.
– Sympatric speciation (especially plants and insects)
• Sympatric species occupy the same place at the same time
• The traits selected for by natural selection need to be inheritable
so that the next generation after selection retains the change
• Three types of selection
– Directional
• See finches
– Stabilizing
• Long necks in giraffes
– Disruptive
• Sexual dimorphism

Summary
• What is ecology?
• What are the components of ecology?
• What is niche?
• What are the relationships in ecosystem?
• What is natural selection?
• Different types of NS
• Gene and genetic variation
• Evolution
• Concept of species.
• Speciation and mechanisms

principlesofecology-141216082016-conversion-gate02.ppt

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