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Diversity and
Interdependence
of Life
Speciation
• We have learned that evolution is the process
of DNA mutations creating new species over
time.
• What determines if different organisms are
different species? What is a species?
A species consists of all individuals that can
breed together and produce fertile offspring.
This definition is called the Biological Species
Concept.
A female donkey mated to a male horse
produces what?
A mule, which is sterile.
Hence, donkeys and horses
are separate species.
Criticisms of the Biological Species Concept
• Cannot be used with asexual organisms
(bacteria).
• Cannot tell if fossil specimens were capable of
interbreeding.
• Doesn’t account for isolation:
– Behavioral isolation: having different
courtship rituals or behaviors
– Geographic isolation: separated by
geographic barriers
– Temporal isolation: reproduce at different
times
How are different species named?
• Taxonomy- The science of naming and classifying
organisms.
• A Swedish biologist named Carolus Linnaus came
up with a two-word system for naming organisms.
It is called binomial nomenclature.
• There are 7 levels of classification:
Kingdom-Phylum-Class-Order-Family-Genus-Species
• In binomial nomenclature, the first word is the
organism’s genus name and the second word is
the species name.
Human Classification
Kingdom: Animalia
Phylum: Chordata
Class: Mammalia
Order: Primate
Family: Hominidae
Genus: Homo
Species: Sapien (means “wise”)
• Using binomial nomenclature, we are
Homo sapiens. Always capitalize the genus
and italicize or underline both the genus
and species names.
The levels get more
specific as you work
down to the species.
Have all living things been
classified?
• NO! Our knowledge of all living things is
limited.
• Classification is based on anatomy,
embryology, DNA, behavior, and when the
organism evolved.
• If you are unsure of the binomial nomenclature
of an organism, you can use an identification
system called a dichotomous key.
Example of a Dichotomous Key
Interdependence of Life
• Ecology- The study of relationships
between living things and their environment.
• Biosphere- The area around the earth
where life exists.
– includes the hydrosphere, lithosphere, and
atmosphere
Levels of the Biosphere
• Biome- a large area characterized by certain
animal and plant species as well as climate
• Ecosystem- All of the living and non-living
components of a particular geographic area.
• Community- A naturally occurring group of
plants and animals living in a particular area.
• Population- A group of organisms of one
type (species) living in a particular area.
• Habitat- The physical area in which an
organism lives.
• Climate- The prevailing weather conditions
of a geographic area.
Levels of a Biosphere
BIOSPHERE
BIOME
ECOSYSTEM
COMMUNITY
NON-LIVING COMPONENT
(Habitat and Climate)
POPULATION
Components of an Ecosystem
• Abiotic- Non-living
Components
–
–
–
–
–
–
–
• Biotic – Living
Components
Sunlight
Temperature
Soil
Soil chemistry
Precipitation
Rocks
Erosion
Where do
–
–
–
–
–
Plants
Animals
Fungus
Bacteria
Protists
viruses belong?
Trophic Levels of Ecosystems
A trophic level is a
“feeding level”.
– The relationship
between what an
organism eats and
what eats it.
– Where it fits into a
food chain/web
– The 1st Trophic Level
is at the bottom of
the food chain.
How Biotic Factors Obtain Energy
Producer (Autotroph)
• Organisms that can make their own food =
organic (carbon containing) materials
• At the 1st Trophic Level
• Examples: plants and some bacteria
• Photosynthetic- Use energy from sunlight
and convert it into organic energy
• Chemosynthetic- Use energy from
inorganic compounds and convert it into
organic energy
Consumer (Heterotroph)
Organisms that cannot make their own food
and must get it from an external source.
• Primary (1st) consumer- herbivore- eats only
producers
• Secondary (2nd) consumer- carnivore- eats
only consumers
• Tertiary (3rd), quaternary (4th), etc.
• Omnivore- eats producers and consumers
• Detritivore- breaks down wastes and dead
bodies
• Decomposer- fungi, bacteria: return nutrients
to the soil for absorption
Food Chain
• Food Chain: Specific feeding sequence in
which organisms obtain energy in an
ecosystem
Grass  Caterpillar  Sparrow  Snake  Coyote
Arrows always point in the direction of energy flow!
• Food Web: Interrelated food chains
FOOD WEB :
• What is/are the producer(s)?
• What is a herbivore?
• What is a primary consumer?
• What is a secondary consumer?
• What is a tertiary consumer?
• What would be 3 consequences in the fish population died out?
How do we keep track of energy in
ecosystems?
• Ecological Pyramids- A diagram that shows the
amounts of energy at each trophic level in a food chain
or food web. (3 types)
1. Numbers Pyramid: counts the # of individuals
(does not discriminate by size) – can be an
inaccurate indicator of energy at that level
– Ex. Caterpillars outnumber the trees that they feed on
2. Biomass Pyramid: measures amount of living
tissue (dry weight) in grams
3. Energy Pyramid: measures amount of energy
stored in tissues (ex. fats = 9 Cal/gram;
carbohydrates/proteins = 4 Cal/gram)
Numbers Pyramid
Biomass Pyramid
Energy Pyramid
Energy Transfer
• Amount of energy available to do work
decreases as energy passes through a
system
• 10% transfer of energy (90% energy lost)
from one level to the next. Most is lost to the
air as heat.
• How much energy would be transferred to
each level of the following food chain?
GrassCaterpillarSparrow Snake Coyote
1200 kcal
?
?
?
?
Population Size
• Studying changes in population size is
called population ecology.
• This helps scientists predict future changes
in populations and better understand how to
conserve biodiversity.
• Counting members of a population is often
impossible. Estimation of population size
can calculated using the Capture-Recapture
Method.
Capture-Recapture Method
• In the Capture-Recapture Method, a sample
of animals are caught and tagged. They are
then released back into their habitat. Other
samples are then captured at various times
and each time the total number and marked
number of animals are noted.
• The following equation is then used to
estimate population size.
N= # originally marked x total # animals captured
# of animals marked that were captured
20 fish were captured, marked and put back into
a pond. On 10 different occasions, samples
were taken from the pond. What is the
estimated population size?
# obtained in the sample
# marked in the sample
15
2
12
4
18
0
22
2
12
1
16
1
13
3
11
4
16
2
20
2
What is the
estimated
population
size of geese?
What is this
method of
estimating
population?
What is the
estimated
mushroom
population in
this plot?
What is this
method of
estimating
population?
How do populations grow?
• Most populations grow either exponentially
or logistically.
• Exponential growth occurs when
resources are plentiful and the
reproduction rate is greater than the death
rate.
• On a graph, exponential growth looks like
a “J”.
How do populations grow?
• Logistic growth occurs if there are limited
resources and growth of the population
begins to slow as competition for those
resources increases. The growth of the
population eventually slows to nearly zero
as the population reaches the carrying
capacity for the environment.
• On a graph, logistic growth looks like a
“S”.
See Question #1 of EOY Practice