Animal Behavior -merged (2).pdf

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Animal Behavior and Learning
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Types of Animal Behavior
(00:47 - 00:59)
Innate Animal Behaviors:
Instinct
Reflexes
Fixed Action Patterns
Imprinting
Mnemonic: FURI (Fur)
Instincts
(01:11 - 01:36)
Circadian rhythm - internal clock that synchronizes with light/dark cycles
Controlled by the brain, influenced by light hitting the retinas
Reflexes
(01:36 - 02:10)
Automatic, involuntary responses to stimuli
Examples:
Switching to non-slipping leg when slipping
Patella reflex (knee-jerk)
Mediated by simple neural pathways
Fixed Action Patterns
(02:10 - 02:31)
Predictable, species-specific behaviors triggered by a "sign stimulus"
Increase fitness over generations
Example: Goose retrieving egg outside nest
Imprinting
(02:31 - 02:44)
Rapid learning of a specific stimulus, often in a critical period
Allows young animals to recognize and bond with parents/caregivers
Animal Communication
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Animals use various methods to communicate:
Visual (body language, displays)
Auditory (vocalizations)
Chemical (pheromones)
Tactile (touch)

Social Behavior and Mating
(03:00 - 03:20)
Social behaviors include:
Cooperation
Competition
Dominance hierarchies
Courtship and mating rituals

Animal Learning and Conditioning
Critical Period Learning
(00:02:56 - 00:03:10)
Animals learn behaviors during a critical period, like goslings/ducklings following their mother
These are behaviors learned by observing their immediate parental figure
Types of Learning
(00:03:10 - 00:03:23)
There are multiple types of learning:
Associative learning
Classical conditioning
Operant conditioning
Observational learning

Classical Conditioning
(00:03:23 - 00:04:16)
Also known as Pavlovian conditioning
Involves an unconditioned stimulus (like food) that elicits an unconditioned response (like
salivation)
A neutral stimulus (like a whistle) is paired with the unconditioned stimulus
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 After repeated pairings, the neutral stimulus becomes a conditioned stimulus that elicits the
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conditioned response (salivation)
Operant Conditioning
(00:04:16 - 00:04:49)
A way to encourage or discourage behaviors
Reinforcement increases a behavior
Positive reinforcement adds a pleasant stimulus
Negative reinforcement removes an unpleasant stimulus
Punishment decreases a behavior
Positive punishment adds an unpleasant stimulus
Negative punishment removes a pleasant stimulus

Examples of Operant Conditioning
(00:04:49 - 00:05:34)
Positive reinforcement: Giving a child a lollipop for cleaning their room
Positive punishment: Making a child mop the floor as punishment for making a mess
Negative reinforcement: Removing a chore for a child who did their homework

Reinforcement and Punishment
(00:05:55 - 00:06:07)
Positive reinforcement: Adding a pleasant stimulus to increase a behavior
Negative reinforcement: Removing an unpleasant stimulus to increase a behavior
Positive punishment: Adding an unpleasant stimulus to decrease a behavior
Negative punishment: Removing a pleasant stimulus to decrease a behavior
Example: Johnny didn't clean his room, so he is not allowed to go to sports practice (negative
punishment)
(00:06:07 - 00:06:22)
Reinforcement increases a behavior, punishment decreases a behavior
Positive is adding a stimulus, negative is removing a stimulus
It's important to understand the differences between these concepts
(00:06:22 - 00:06:43)
Associative learning: Associating one thing with another
Sensitization: Increased stimulus leads to increased behavioral response
Habituation: Repeated stimulus leads to decreased response
(00:06:43 - 00:07:00)
Habituation example: Fire alarm going off frequently leads to not reacting to it anymore
The person becomes habituated to the stimulus
(00:07:00 - 00:07:12)
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 Observational learning: Learning by observing others
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Example: Child observing parent folding laundry and copying the behavior
(00:07:12 - 00:07:28)
Insight: Ability to solve a problem using previous experiences
Improves as animals become more advanced in the phylogenetic tree
(00:07:28 - 00:07:46)
Kinesis: Change in rate of random movement in response to a stimulus
Example: Bug moving randomly until it finds a moist environment
(00:07:46 - 00:08:10)
Taxis: Change in direction towards or away from a stimulus
Example: Bug moving towards a moist environment

Animal Behavior and Communication
Kinesis vs. Taxis
(00:08:35 - 00:09:00)
Kinesis is a change in the rate of movement in a random direction
Example: Gas particles moving randomly and bouncing around
Taxis is a change of movement in a specific direction
Example: A car driving in a certain direction

Migration
(00:09:00 - 00:09:10)
Migration is a seasonal, long-distance movement
Example: Geese or other migratory birds moving from one location to another based on
changing seasons

Animal Communication
(00:09:10 - 00:10:21)
There are four main forms of animal communication:
1. Visual: Courtship and mating rituals, dances
2. Auditory: Vocalizations like wolf howling to signal location and group cohesion
3. Tactile: Animals bonding through touch, like elephants touching trunks
4. Chemical: Pheromones signaling readiness to mate, danger, etc.
Mnemonic: FACT (Visual, Auditory, Chemical, Tactile)
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 Social Behavior and Mating
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(00:10:21 - 00:11:09)
Cooperation: Animals working together to achieve a goal
Agonistic Behavior: Threats or aggression to make another animal submit
Aggression: Behavior intended to harm both animals involved
Dominance Hierarchy: A social hierarchy with a defined order
"Any animals can cooperate, and agonistic behavior is threats or aggression. This is ways in
which an animal would get another animal to submit to them."

Term Definition
Cooperation Animals working together to achieve a goal
Agonistic Behavior Threats or aggression to make another animal
submit
Aggression Behavior intended to harm both animals
involved
Dominance Hierarchy A social hierarchy with a defined order
(Video timestamps in parentheses)

Animal Behavior
Territoriality
(00:11:09 - 00:11:22)
Territoriality is an animal's protecting a given territory
This could be done with pheromones
Even dogs will urinate to mark their scent on a specific territory and claim it as their own
This is where the animal hunts, stays, and breeds
Altruistic Behaviors
(00:11:22 - 00:11:37)
Many animals use altruistic behaviors, which involve sacrificing for relatives
This is an adaptive type of behavior that would lead to improved survival of the species
Inclusive Fitness
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Inclusive fitness is an animal's direct fitness (number of genes it can pass down on its own) plus
its indirect fitness (number of genes its relatives can pass down)
Kin selection is natural selection in favor of behavior by individuals that may decrease their
chance of survival, but increase that of their kin
Reciprocal Altruism
(00:12:27 - 00:12:42)
Reciprocal altruism is the sacrifice for an unrelated animal of the same species
This benefits the species as a whole, rather than just the individual's kin
Sexual Selection
(00:12:54 - 00:13:20)
Sexual selection is the difference between males and females in mating behaviors
Male competition: Stronger males have more mating opportunities (e.g. deer fighting for mates)
Female choice: Females select mates with desirable characteristics, increasing the frequency of
those traits
Sexual Dimorphism
(00:13:20 - 00:13:38)
Sexual dimorphism is the differences between males and females, physically and in color
patterning, build, etc.
Mating Strategies
(00:13:38 - 00:13:50)
Monogamy: Having only one partner at a time
Polygamy: Having multiple mating partners
Semelparity: Mating once during a lifetime
Iteroparity: Mating many times during a lifetime

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 Ecology and Evolution
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Environmental Ecology
(00:00:39 - 00:01:55)
Key Terms:
Species: A group of organisms that can interbreed to produce viable, fertile offspring
Habitat: The place where an organism lives
Population: A group of organisms of the same species in a given location
Ecological Community: All the populations of different species in a given area
Ecosystem: The ecological community and its abiotic factors
Abiotic Factors: The non-living elements of an environment (e.g., water, soil)
Biotic Factors: The living elements of an environment
Biosphere: All the ecosystems on Earth
Ecological Factors:
Density-Dependent Factors: Factors that depend on population density (e.g., disease, resource
competition)
Density-Independent Factors: Factors that are independent of population density (e.g., weather,
climate)
Niche:
Realized Niche: The environment where an organism actually lives
Fundamental Niche: The range of environmental conditions where an organism can survive
Competitive Exclusion Principle: Two species cannot occupy the same niche and maintain
population levels; they will compete for limited resources
Diagram Example:
Shows different bird species foraging at different heights in a forest, demonstrating how they
occupy different niches to avoid competition for resources.
Biological Interactions
(00:04:01 - 00:04:58)
Types of Competition:
Exploitation Competition: Competition for a common, depleted resource
Indirect Competition: Competition for a common, depleted resource
Interspecies Competition: Competition between members of the same species for resources
Apparent Competition: Competition between two species mediated by a shared predator

Types of Biological Interactions
(00:05:10 - 00:05:24)
Mnemonic for types of competition: Apparent, Exploitation, Interspecies
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 Symbiosis is an important type of biological interaction to understand
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Symbiotic Relationships (00:05:24 - 00:05:41)
Mutualism: Both species benefit
Example: Clownfish and sea anemone
Commensalism: One species benefits, the other is unaffected
Parasitism: One species benefits, the other is harmed
Example: Mosquito or tick

Ecosystem Ecology Terminology
Food Chains and Food Webs (00:05:54 - 00:06:07)
Food Chain: Linear depiction of food interactions
Food Web: Interconnected food chains
Trophic Levels (00:06:07 - 00:06:37)
Autotrophs: Produce their own energy, typically from the sun
Heterotrophs: Consume organic compounds for energy
Predation: When a predator consumes prey
Biomass: Total mass of living organisms in an area
Producers, Consumers, and Predators (00:06:37 - 00:07:25)
Producers: Primary consumers (e.g., herbivores like cows)
Secondary Consumers: Prey on primary consumers
Tertiary Consumers: Prey on secondary consumers
Apex Predator: Top predator in a given area
Energy Flow in Ecosystems (00:07:25 - 00:08:50)
Only 10% of energy is converted to organic tissue at each trophic level
Energy is lost as heat, waste, and decomposition
This limits the biomass at higher trophic levels
Decomposers and Scavengers
(00:09:04 - 00:09:38)
Decomposers: Microorganisms and invertebrates that break down organic material at the
molecular level
e.g., fungi, bacteria
Scavengers: Animals that feed on dead or decaying matter
Also called detritivores
Scavengers break down large organic material, while decomposers break it down at the molecular
level
(00:09:38 - 00:10:01)
Decomposers are essential for the integrity of the environment
Without decomposers, we would be surrounded by undecomposed organic material
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 Decomposition and Nutrient Cycling
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(00:10:01 - 00:10:12)
During autumn, leaves fall to the ground and accumulate as debris
In the spring, the snow melts and the debris is left behind
(00:10:12 - 00:10:24)
Decomposers break down the fallen leaves during the winter
This turns the leaves back into fresh soil
Population Ecology
(00:10:24 - 00:10:38)Biotic Potential
The ability of a species to have the highest possible birth rate and lowest possible death rate
This is the maximum population size a species can achieve
(00:10:38 - 00:10:50)Carrying Capacity
The maximum population size that an environment can sustainably support
This is the limit to the biotic potential of a species
(00:10:50 - 00:11:03)Population Growth
The population will initially grow exponentially, following the biotic potential
But it will then level off at the environmental carrying capacity
(00:11:03 - 00:11:15)
The population growth will be a sinusoidal curve
It will reach a threshold based on the carrying capacity
(00:11:15 - 00:11:34)
The carrying capacity is limited by resources like food, water, and habitat
As resources are depleted, the death rate will increase, limiting the population
(00:11:34 - 00:11:54)
Even if a species can produce many offspring, the population will stabilize at the carrying capacity
Excess deaths from lack of resources will balance the high birth rate
r/K Selection Theory
(00:11:54 - 00:12:07)
Different species employ different tactics to produce offspring
r-selected species focus on quantity, K-selected species focus on quality
(00:12:07 - 00:12:22)K-selected Species
Have long gestation periods to produce a few large, robust offspring
The offspring take a long time to mature but have a low mortality rate
(00:12:22 - 00:12:35)r-selected Species
Produce many small offspring that mature quickly
Many of the offspring do not survive, but some will reach adulthood
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r-selected species have a "quantity over quality" approach
K-selected species have a "quality over quantity" approach
(00:12:52 - 00:13:06)Survival Curves
Type I: High percentage of individuals reach maximum lifespan
Type II: Constant mortality rate over lifespan
Type III: Very few individuals reach maximum lifespan
(00:13:06 - 00:13:31)
K-selected species have a Type I survival curve with many survivors
r-selected species have a Type III curve with few survivors reaching maximum lifespan
(00:13:31 - 00:13:54)
Catastrophic events are more detrimental to K-selected species, as they have invested heavily in
few offspring
r-selected species can better withstand losses since they produce many offspring
Ecological Succession
(00:14:28 - 00:14:42)Ecological Succession
The process by which a community develops and changes over time
The first species to inhabit an area are called pioneer species
(00:14:42 - 00:15:04)
There are typically not totally "unfounded" areas, as some life will exist even in newly formed
environments
The pioneer species begin the process of ecological succession

Primary Succession and Secondary
Succession
(00:15:04 - 00:15:18)
Most areas on our planet have had life at some point, even if they are currently uninhabitable like
Antarctica or the Arctic
These areas can change over time and become re-inhabited
Primary Succession (00:15:18 - 00:16:19)
Occurs after a large disturbance in an area that has previously not supported life
For example, if Antarctica suddenly became very warm
Starts with bare rocks and pioneer species
Progresses through different stages of succession (lichen, small plants, grasses, shrubs, trees)
until it reaches a climax community
Climax community is a steady state where ecological succession has achieved a mature, stable
ecosystem
Secondary Succession (00:16:19 - 00:17:19)
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 Occurs after a smaller disturbance in an area that has recently supported life
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For example, a large forest fire
Still has a pioneer species and intermediate species, but the process is more rapid
Often has some surviving seeds or species that can reestablish more quickly since there is still
soil present
Keystone Species and Predators
(00:17:19 - 00:18:33)
Keystone species and keystone predators are critical to maintaining the balance of an ecosystem
Example: Sharks are keystone predators that feed on cownose rays
If sharks were eliminated, the cownose ray population would explode and decimate other species
like bivalves and arthropods
This can cause a cascading disruption throughout the entire ecosystem
Similar effects were seen when wolf populations were disrupted in the northeastern US, leading to
deer overpopulation and coyote invasions
Biomes
(00:19:07 - 00:19:39)
Biomes are areas of land or water defined by their biotic factors, rainfall, and temperature
Key terrestrial biomes include:
Tropical rainforests
Savannas
Temperate grasslands
Deciduous forests
Chaparrals
Deserts
Taiga
Tundra
Polar regions
Each biome has its own specific temperature and rainfall patterns that define its unique ecosystem

Biomes and Ecosystems
Tropical Rainforests
(00:19:39 - 00:19:57)
Unique tropical rainforests have heavy rainfall
Very hot and high humidity, allowing for a great diversity of plant species
Diverse plant species provide a diverse structure for animals to live in, resulting in a diverse
selection of animals
Savannas
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Hot with very little rainfall
Dominated by grasses and some trees
Suitable for ungulates (hoofed animals) like giraffes that can move throughout the savanna, graze
on the grasses and trees, and find shade
Adapted to low amounts of water and rainfall
Temperate Grasslands
(00:20:24 - 00:20:39)
Cool winters, hot summers, and seasonal rain
Dominated by grasses and shrubs
Many grazing animals thrive in this environment
Temperate Deciduous Forests
(00:20:39 - 00:21:05)
Warm summers, cold winters, and moderate rain
Dominated by hardwood trees that shed their leaves in the fall
Home to many smaller mammals like birds, rodents, squirrels, porcupines, weasels, and deer
Chaparral
(00:21:05 - 00:21:32)
Hot and dry summers, mild winters
Dominated by trees, shrubs, and cacti
Home to animals like foxes, deer, and jackrabbits
Deserts
(00:21:32 - 00:21:57)
Hot days, cold nights, very little rain
Mainly home to cacti, reptiles, arachnids, and coyotes
Hard to support a large biomass due to the harsh conditions
Taiga (Coniferous Forests)
(00:21:57 - 00:22:13)
Cold winters with snowfall, warm rainy summers
Dominated by coniferous trees
Home to larger mammalian species like bears, otters, and wolves, as well as smaller mammals
Tundra
(00:22:13 - 00:22:26)
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 Cold with little precipitation
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Dominated by mosses and shrubs
Home to bears, wolves, caribou, and reindeer
Polar Regions
(00:22:39 - 00:22:57)
Cold, snowy weather, mostly ice, very little plant life
Home to penguins and polar bears
Aquatic Biomes
(00:23:14 - 00:23:26)
Saltwater biome is the largest on Earth
Freshwater biome has less than 0.1% salt content
Aquatic Ecosystem Zones
(00:23:26 - 00:23:52)
Euphotic Zone: Closest to the surface, with good light penetration
Littoral Zone: Part of the euphotic zone where sunlight reaches the bottom
Dysphotic Zone: Semi-radiated, not enough light for plants to survive
Aphotic Zone: No light, few if any species can survive (deep ocean)

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 Evidence and Theories of Evolution
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(00:00:46 - 00:00:59)The evidence for evolution includes:
Fossil record
Biogeography
Embryology
Comparative Anatomy
Biochemical methods
Fossil Record
(00:01:10 - 00:01:28)
Fossils can be actual remains or impressions/traces (e.g., footprints, scat)
Petrification is the process where organic matter becomes stone over time
Biogeography
(00:01:28 - 00:01:57)
The geographical distribution of plants and animals
Pangaea was a large supercontinent that broke apart over time, allowing organisms to evolve in
isolation on the new landmasses
Embryology
(00:02:08 - 00:02:19)
The study of embryos and their development
Similarities in embryological development across related organisms support common ancestry
Comparative Anatomy
(00:02:32 - 00:03:13)
Anatomical similarities between organisms indicate a shared common ancestor
Homologous structures are similar in structure but may have different functions
Analogous structures have similar functions but did not evolve from a common ancestor
Vestigial structures are remnants of structures that no longer serve a purpose
Biochemical Evidence
(00:03:59 - 00:04:21)
Similarities in biochemical pathways and genome structure between organisms support
evolutionary relationships
Chimpanzees and humans share a high degree of genetic similarity, indicating a close
evolutionary relationship

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 Mnemonic for Evidence of Evolution:Emily Compares Biochemistry, Grades, Biography Reports,
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and Fossils
Important Figures and Theories
(00:04:57 - 00:05:26)Baron George Cuvier
Founder of paleontology
Proposed the theory of catastrophes, where sudden environmental changes led to mass
extinctions
Jean Baptiste Lamarck
Proposed the theory of use and disuse, where increased use of a body part leads to its growth
and development, while unused parts atrophy
(00:05:26 - 00:05:44)
Lamarck's theory of use and disuse suggested that changes acquired during an organism's
lifetime could be passed on to offspring, which is now known to be incorrect.
(00:05:44 - 00:05:56)
Lamarck's theory was an early attempt to explain evolution, but it was later superseded by
Charles Darwin's theory of natural selection.

Lamarck's Theory of Acquired Traits
(00:05:56 - 00:06:10)
Lamarck proposed the theory of acquired traits
This theory states that if an organism acquires a trait during its lifetime, that trait can be passed
on to its offspring
This idea was disproven by Charles Darwin
Epigenetics and Heritable Traits
(00:06:10 - 00:06:29)
There is some evidence that certain epigenetic factors can allow for adaptation and changes
during an organism's lifetime
These changes could potentially be heritable
However, this is not the main mechanism by which evolution takes place
Charles Darwin and Natural Selection
(00:06:40 - 00:06:53)
Charles Darwin proposed the theory of natural selection
This theory states that organisms better adapted to their environment will survive and produce
more offspring
These offspring will then inherit the same beneficial traits as their parents
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 Terminology of Natural Selection
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(00:07:04 - 00:07:28)
Natural selection is a gradual, non-random process where alleles become more or less common
due to an organism's interactions with the environment
Survival of the fittest refers to reproductive success, not just longevity
Requirements for natural selection:
Competition for scarce resources
Variation in fitness among organisms
Heritability of traits
Organisms produce more offspring than can normally survive

Types of Natural Selection
(00:08:34 - 00:10:37)
Stabilizing Selection
Maintains a non-extreme, mainstream trait
Example: Robins typically laying 4 eggs
Extreme traits are selected against
Directional Selection
Shifts the population towards one extreme trait
Example: Light-colored moths being selected for on a light background
Disruptive Selection
Selects for extreme traits, diversifying the population
Example: Gray and Himalayan rabbits being selected for in different environments
Table: Comparison of Natural Selection Types

Type Description Example
Stabilizing Maintains non-extreme, Robins laying 4 eggs
mainstream traits
Directional Shifts population towards one Light-colored moths on light
extreme trait background
Disruptive Selects for extreme traits, Gray and Himalayan rabbits
diversifying population

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 Types of Natural Selection
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(00:10:52 - 00:11:06)
Stabilizing Selection: A bell curve where the mainstream is favored, forcing everything to the
mean. This gives a stable life.
(00:11:06 - 00:11:17)
Directional Selection: One extreme is favored, going in one direction.
Disruptive Selection: The graph looks like a mountain, with two peaks split by disruption.
Microevolution vs. Macroevolution
(00:11:17 - 00:11:37)Microevolution:
Changes in a gene pool, the allele frequency of a single population
Genes will increase in frequency as they suit the environment
Macroevolution:
Sources of genetic variation
Speciation
(00:11:37 - 00:11:54)
Example of microevolution:
In a population of multicolored beetles, green beetles may have an advantage if there is a lot of
plant life, so the population will shift towards being more green.
Then, if the environment changes (e.g., a fire, land becomes dry), the beetles may shift towards
being more brown to better suit the new environment.
(00:12:04 - 00:12:18)
The Hardy-Weinberg formula can be used to determine allele frequencies within a population,
assuming no changes in gene frequency.
P + Q = 1, where P is the frequency of the dominant allele and Q is the frequency of the recessive
allele.
(00:12:18 - 00:12:30)
The Hardy-Weinberg formula also states that P^2 + 2PQ + Q^2 = 1, where P^2 is the frequency of
homozygous dominant individuals, Q^2 is the frequency of homozygous recessive individuals,
and 2PQ is the frequency of heterozygous individuals.
(00:12:30 - 00:12:54)
Example: If the frequency of the dominant allele (P) is 0.5, then the frequency of the recessive
allele (Q) is also 0.5.
The formula can be used to calculate the frequencies of different genotypes within a population.
(00:12:54 - 00:13:24)
The Hardy-Weinberg equilibrium requires certain assumptions to hold true:
No selection
No mutation
No migration
Large population
Random mating
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(00:13:24 - 00:13:56)
Example: In a garden of 100 pea plants, 86 have yellow peas and 16 have green peas
(homozygous recessive).
Using the Hardy-Weinberg formula, we can calculate:
Q^2 = 0.16, so Q = 0.4
P = 1 - Q = 0.6
Frequency of homozygous dominant plants = P^2 = 0.36 (36 plants)
Frequency of heterozygous plants = 2PQ = 0.48 (48 plants)
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The Hardy-Weinberg equilibrium assumptions must be met for the formula to be applicable:
No selection
No mutation
No migration
Large population
Random mating
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Mnemonic for the Hardy-Weinberg equilibrium requirements:
Large population
Random mating
Minimizing the effects of genetic drift
No mutations
Minimizing the effects of natural selection

Allele Frequencies and Genetic Drift
(00:15:57 - 00:16:07)
Allele frequencies are stable and not impacted when a population is isolated with no migration
Genetic drift is a factor that can cause evolution in an isolated population
Mechanisms of Evolution
(00:16:07 - 00:16:20)
Evolution can occur through:
Mutations
Bottleneck effect
Founder effect
Non-random mating
Natural selection
Gene flow

Bottleneck Effect vs. Founder Effect
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Bottleneck Effect:
A population is drastically reduced, and only a few alleles can survive
Analogous to a forest fire where most of the population dies off
Founder Effect:
A segment of a population breaks off and forms a new population
The new population may lack the same genetic diversity as the original

Non-Random Mating
(00:16:49 - 00:17:16)
Outbreeding: Breeding with non-familiar members
Inbreeding: Breeding with relatives
There can be selection for non-random mating based on accessibility and desirable characteristics
Natural Selection and Gene Flow
(00:17:34 - 00:17:58)
Natural selection favors traits based on fitness
Gene flow is the movement of alleles between populations
Gene flow can introduce new changes and alter the dynamics within a population
Macroevolution
(00:18:14 - 00:18:25)
Macroevolution is major evolutionary change over long periods of time
Examples include dinosaurs evolving into birds or fish evolving into mammals
Pre-Zygotic Isolation Mechanisms
(00:18:25 - 00:19:06)
Gametic Isolation: Eggs and sperm cannot fuse
Mechanical Isolation: Physical barriers prevent mating
Habitat Isolation: Populations live in different habitats
Temporal Isolation: Populations breed at different times
Behavioral Isolation: Populations have different mating behaviors
Post-Zygotic Isolation Mechanisms
(00:19:21 - 00:19:43)
Hybrid Mortality: Hybrid zygote is not viable
Hybrid Sterility: Hybrid cannot reproduce
Hybrid F2 Breakdown: Hybrid offspring have decreased fitness
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Mutation: Random changes in the genetic code
Sexual Reproduction: Crossing over and independent assortment during meiosis
Balanced Polymorphism: Heterozygote advantage, such as sickle-cell trait providing resistance
to malaria

Genetic Variation and Speciation
Minority Advantage and Hybrid Advantage
(00:21:36 - 00:21:54)
Minority Advantage: A rare phenotype is favored over a common phenotype
Hybrid Advantage: Breeding two different strains of organisms produces an organism that is
better adapted to its environment
Neutral Variations
(00:21:54 - 00:22:07)
Variations that neither benefit nor harm an organism
Many different polymorphisms present in a cross human species that have no discernible, positive
or negative effect
Polymorphisms and Polyploid
(00:22:07 - 00:22:32)
Some polymorphisms can be loosely associated with different disease states
Polyploid: Another source of genetic variation, typically very deleterious but can occur
Diploid: The dominant allele can mask the effect of recessive alleles, allowing them to drift
through a population
Sources of Genetic Variation
(00:22:32 - 00:23:09)
Mutation: A source of genetic variation
Balanced Polymorphisms: Maintain genetic variation in a population
Polyploid: Increased number of chromosome pairs
Sexual Reproduction: Mixes genetic material, creating new combinations
Speciation
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Speciation: Species formation from a single ancestral species
Allopatric Speciation: Occurs due to geographical barriers, leading to adaptive radiation
Patterns of Evolution
(00:23:38 - 00:24:25)
Divergent Evolution: Initial species branches and splits off
Convergent Evolution: Two separate species become more similar over time
Parallel Evolution: Two separate species change individually on their own
Co-evolution: Two species impart selective pressures on each other
Mimicry
(00:24:25 - 00:25:36)
Batesian Mimicry: Harmless animals mimic the coloring of a harmful animal
Müllerian Mimicry: Different poisonous species resemble each other
Phylogenetic Trees
(00:25:52 - 00:26:19)
Clade: A cluster of species in a phylogenetic tree
Homoplasy: Convergent evolution, where two clades develop similar characteristics
Parsimony: Choosing the simplest scientific explanation that fits the evidence

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Reproduction and Developmental Biology
Asexual Reproduction
(00:00:37 - 00:01:29)

Binary Fission
Process by which a prokaryotic cell divides in half
The cell replicates its DNA and then a septum is created to divide the cell into two daughter cells

Budding
Outgrowth that forms on organisms like hydra and yeast
A smaller version of the organism forms and then breaks off to become an independent organism

Regeneration
Organism can be fragmented into multiple pieces, and each piece will form a new adult organism

Parthenogenesis
Embryo develops from an unfertilized egg in a sexually reproducing species
Example: Honey bees

Human Reproduction
(00:01:29 - 00:03:40)

Male Reproductive System
Spermatogenesis
Spermatogonia are the stem cells that produce sperm
Spermatids are the partially differentiated sperm cells

Sperm Structure
Head contains the nucleus and acrosome (enzymes to penetrate egg)
Midpiece contains mitochondria to power the tail/flagella
Tail/Flagella provides motility to reach the egg

Reproductive Anatomy
Seminiferous tubules are the site of spermatogenesis
Epididymis stores sperm
Vas deferens transports sperm
Ejaculatory ducts release sperm during ejaculation
Urethra and penis allow sperm to exit the body

Accessory Glands
Seminal vesicles secrete fructose
Prostate gland increases alkalinity
Bulbourethral glands secrete mucus
These fluids help protect and nourish the sperm
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Hormonal Regulation
FSH from pituitary stimulates Sertoli cells to facilitate spermatogenesis
LH from pituitary stimulates Leydig cells to produce testosterone

Female Reproductive System
Oogenesis
Oogonia are the stem cells that produce oocytes
Primary oocytes undergo meiosis to form secondary oocytes and polar bodies

Ovarian Cycle
Follicle development is stimulated by FSH
Ovulation is triggered by a surge of LH
Corpus luteum produces progesterone to prepare the uterus

Uterine Cycle
Menstruation occurs when the uterine lining is shed
Proliferative phase rebuilds the uterine lining
Secretory phase prepares the lining for implantation

Fertilization and Embryonic Development
Sperm must penetrate the egg's acrosome and zona pellucida
Zygote undergoes cleavage divisions to form a blastocyst
Blastocyst implants in the uterine lining and develops into an embryo

Embryology
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Germ Layers
Ectoderm forms the nervous system and epidermis
Mesoderm forms muscles, bones, circulatory system
Endoderm forms the digestive and respiratory systems

Organogenesis
Development of the major organ systems from the germ layers
Includes formation of the heart, lungs, brain, and other vital organs

Fetal Development
Placenta and umbilical cord provide nutrients and oxygen to the fetus
Fetus undergoes dramatic growth and differentiation over 9 months
Birth occurs when the fetus is ready to survive outside the uterus

The Reproductive System
The Male Reproductive System
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The hypothalamus releases GnRH, which stimulates the anterior pituitary to release FSH and LH
Testosterone from Leydig cells in the testes will:
Inhibit the anterior pituitary and hypothalamus via negative feedback
Stimulate the Sertoli cells

The Female Reproductive System
(00:03:51 - 00:04:03)
The ovaries produce ova (eggs)
The fallopian tubes are where the egg travels to reach the uterus

(00:04:03 - 00:04:14)
Ectopic pregnancy occurs when the embryo develops in the fallopian tube instead of the uterus
The uterus is where the egg develops into an embryo
The uterus has 3 layers: perimetrium, myometrium, and endometrium
The endometrium is the layer that is shed during menstruation

(00:04:14 - 00:04:28)
The cervix is the entrance to the uterus from the vagina

(00:04:28 - 00:04:39)
Oogenesis produces 1 mature egg and several polar bodies, unlike spermatogenesis which produces 4 viable
sperm

(00:04:39 - 00:04:51)
FSH stimulates follicle development in the ovaries
LH stimulates ovulation of the egg
Estrogen and progesterone regulate the menstrual cycle and secondary sex characteristics

(00:04:51 - 00:05:04)
Diagram of the menstrual cycle:

Phase Hormone Levels
Menstrual Flow Estrogen and progesterone low, FSH and LH
somewhat higher but LH low
Proliferative FSH and LH increase, estradiol increases
Secretory Progesterone surges, then drops off

(00:05:04 - 00:05:24)
If pregnancy occurs, progesterone is maintained by the embryo's production of human chorionic gonadotropin
(hCG)
If no pregnancy, progesterone drops, signaling shedding of the endometrial lining (menstruation)

(00:05:24 - 00:05:42)
Hormone feedback loops in females:
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Hypothalamus releases GnRH
Anterior pituitary releases FSH and LH
Ovarian hormones (estradiol, progesterone) provide negative feedback to the hypothalamus and pituitary

(00:05:42 - 00:07:03)
Inhibin from Sertoli cells and testosterone from Leydig cells provide negative feedback to the hypothalamus
and pituitary, regulating FSH and LH levels

Fertilization and Early Embryonic
Development
Fertilization Events
(00:07:03 - 00:07:25)

Capacitation:
Destabilizes the sperm's plasma membrane and increases its permeability to calcium
Prepares the sperm to penetrate the egg

Acrosome Reaction:
Contact between the sperm and egg initiates the acrosome reaction
The acrosome membrane fuses with the sperm head membrane, releasing enzymes that break down the zona
pellucida (coating of the egg)

Polyspermy Block:
Prevents more than one sperm from fertilizing an egg
Fast block: Depolarization of the egg's membrane helps repel sperm
Slow block: Calcium ions released inside the egg's plasma membrane stimulate the cortical reaction

Meiosis II:
The fertilized egg completes meiosis II, releasing the second polar body

Stages of Embryonic Development
(00:09:13 - 00:10:26)

Day 1: Fertilization
Fertilization occurs, creating the zygote

Day 2-3: Cleavage
The zygote undergoes cell division, forming a compact mass of cells

Day 4: Differentiation
The cells differentiate into the inner cell mass and the trophoblast
The blastocyst cavity forms

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Day 5: Implantation
The blastocyst implants in the uterine epithelium
The trophoblast cells begin to form the placenta

Day 12: Bilaminar Disc
The mesoderm forms and spreads
The amniotic sac begins to enlarge

Day 23: Amnion and Umbilical Cord
The amniotic sac, chorion, and umbilical cord begin to form and function

Monozygotic Twins
Occur when a single fertilized egg divides into two separate embryos
Can have different chorion and amnion configurations depending on the timing of the division

Anterior Pituitary Hormones
(00:07:03)
LH (Luteinizing Hormone) is released from the anterior pituitary

Fertilization and Early Embryonic
Development
Monozygotic vs. Dizygotic Twins
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Monozygotic (identical) twins:
Derived from the same embryonic origin
Genetically identical

Dizygotic (fraternal) twins:
Two eggs fertilized by two sperm
Genetically distinct, like siblings

Cleavage Patterns
(00:11:26 - 00:12:31)
Spiral cleavage:
Occurs at the 8-cell stage

Radial cleavage:
Occurs in protostomes and deuterostomes
Differences in mouth and anus formation

Determinate cleavage:
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Fate of blastomeres is not predetermined

Indeterminate cleavage:
Fate of blastomeres is predetermined

Holoblastic cleavage:
Even division throughout the embryo
Embryos with little yolk

Meroblastic cleavage:
Uneven division
Embryos with a lot of yolk

Morula and Blastula
(00:12:31 - 00:13:11)
Morula:
Ball of 12-16 cells

Blastula:
Formed after blastocoel (hollow space) is created
Contains trophoblast (outer layer) and inner cell mass
Trophoblast becomes extra-embryonic structures (placenta, amnion)
Inner cell mass becomes the embryo

Gastrulation
(00:13:11 - 00:14:17)
Blastula cells rearrange to form the germ layers:
Ectoderm
Mesoderm
Endoderm

Primitive streak forms, leading to the formation of the germ layers
Ectoderm forms outer surface and central nervous system
Mesoderm forms muscle, blood, kidneys, bone
Endoderm forms internal organs

Germ Layer Derivatives
(00:14:17 - 00:14:35)
Ectoderm:
Outer surface
Central nervous system

Mesoderm:
Muscle
Blood system
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Kidneys
Bone

Endoderm:
Internal organs

Embryonic Development and Organ
Formation
Digestive Tube and Germ Cells
(00:14:35 - 00:14:46)
The digestive tube, pharynx, and lungs form as a budding off of the gastrointestinal tract
The germ cells of the new embryo will also form during this process

Ectoderm
(00:14:46 - 00:15:07)
Ectoderm Mnemonic: Ectoderm is the attracted derm, pretty skin and health
Ectoderm will form:
Epidermis and skin
Nails
Jaws and teeth
Brain, central nervous system (CNS), and peripheral nervous system (PNS)
Sensory parts of skin and nails
Sweat glands

Mesoderm
(00:15:07 - 00:15:24)
Mesoderm Mnemonic: Mesoderm means "of having sex"
Mesoderm will form:
Gonads
Bones and skeleton
Muscles
Cardiovascular system
Blood
Spleen

Endoderm
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Endoderm Mnemonic: Endoderm is the "end internals of the end P TT"
Endoderm will form:
Epithelial lining of internal organs
Pancreas
Liver
Thyroid
Parathyroid
Thymus

Organogenesis
(00:15:47 - 00:15:58)
Organogenesis is the process by which organs are formed from the three germ layers
Patterning and adult structure formation occurs during this process

Neurulation
(00:15:58 - 00:16:30)
Neurulation is the formation of nervous tissue
It begins with the formation of a neural plate from the ectoderm
The neural plate then folds inward to form the neural tube, which will become the central nervous system

Embryonic Models
(00:16:30 - 00:17:58)
In mammals, the amnion secretes amniotic fluid to cushion and protect the embryo
The embryo will inhale and drink the amniotic fluid, then excrete it, recirculating the fluid
If the embryo cannot excrete the fluid (e.g., renal agenesis), it can lead to birth defects
The chorion forms the placenta, the allantois becomes the umbilical cord, and the yolk sac nourishes the fetus
Chick embryos are nourished by a yolk sac, while human embryos are nourished by the placenta and umbilical
cord

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