Biology Exam 3 Study Guide PDF

Summary

This study guide covers various topics in biology, including biotechnology, agriculture, human health, forensic science, genes and inheritance, and evolution. It provides definitions, examples, and important processes within each module.

Full Transcript

**Biology Exam 3 Study Guide**

**Module 7: Biotechnology**

**Biotechnology Definition and Examples**

Definition: The use of living organisms or their components to produce
useful products

Examples:

Genetic engineering

Fermentation

Vaccine production

Enzyme production

**Important Processes in Biotechnology**

Chop: Using restriction enzymes to cut DNA at specific sequences

Amplify: Making multiple copies of DNA using PCR (Polymerase Chain
Reaction)

Insert: Introducing DNA into host cells using vectors like plasmids

Grow: Culturing modified organisms to produce desired products

**CRISPR**

Definition and Overview:

Gene-editing technology that acts like molecular scissors

Uses Cas9 enzyme to cut DNA at specific locations

Allows precise modification of genes

Risks of CRISPR:

Off-target effects (unintended DNA modifications)

Potential ecological impacts

Ethical concerns about human germline editing

**Agriculture**

Genetic Engineering:

Direct manipulation of an organism\'s genes

Introduction of desired traits

Recombinant DNA Technology:

Combining DNA from different sources

Creating organisms with new genetic combinations

Factors Driving Modified Crop Adoption:

Insecticides/Insect Resistance:

Crops engineered to produce their own pesticides

Reduced need for chemical spraying

Herbicide Resistance:

Crops tolerant to specific herbicides

Allows better weed control

Rewards vs. Risks:

Transgenic Salmon Example:

Faster growth rate

Concerns about ecological impact

Featherless Chicken Example:

Easier processing

Animal welfare concerns

GMO Concerns:

Environmental impact

Gene transfer to wild species

Food safety

Biodiversity loss

**Human Health**

Treat vs. Prevent and Cure:

Treatment: Managing symptoms

Prevention: Stopping disease before it occurs

Cure: Eliminating disease completely

Applications:

Diabetes: Synthetic insulin production

Human Growth Hormone: Treatment for growth disorders

Gene Therapy:

Direct modification of genes to treat diseases

Poor success record due to:

Immune responses

Difficulty targeting specific cells

Complex nature of genetic diseases

Genetic Testing:

Parental carrier testing

Prenatal diagnosis

Predictive testing for late-onset conditions

**Forensic Science**

DNA Sequences in Humans:

99.9% identical between individuals

0.1% variation makes each person unique

STRs (Short Tandem Repeats):

Repeated DNA sequences

Vary between individuals

Used for identification

DNA Fingerprinting:

Pros:

Highly accurate

Small sample needed

Long-term stability

Cons:

Cost

Privacy concerns

Processing time

**Module 8: Genes and Inheritance**

**Key Definitions**

Heredity: Transmission of traits from parents to offspring

Dominant vs. Recessive Traits:

Dominant: Expressed when only one copy is present

Recessive: Expressed only when two copies are present

Test-cross: Crossing with homozygous recessive to determine genotype

Pedigrees: Family trees showing inheritance patterns

Incomplete Dominance: Neither allele completely dominant

Codominance: Both alleles expressed equally

Polygenic Traits: Traits influenced by multiple genes

Additive Traits: Genes have cumulative effect

Pleiotropy: One gene affecting multiple traits (e.g., Marfan syndrome)

Phenotypes: Observable characteristics

Dihybrid: Cross involving two traits

Independent Assortment: Random separation of different gene pairs

Linked Genes: Genes close together on same chromosome

**Mendel\'s Research**

Critical Features:

Pure-breeding plants

Controlled breeding

Statistical analysis

Important Ideas:

Traits are controlled by factors (genes)

Factors come in pairs

Factors separate during gamete formation

Law of Segregation:

Allele pairs separate during gamete formation

Each gamete receives one allele

**Using Punnett Squares**

Tool for predicting offspring genotypes

Shows all possible combinations of gametes

Helps calculate probability of traits

**Module 9: Evolution**

**Darwin\'s Contributions**

Observed Patterns:

Variation within species

Fossil evidence

Geographic distribution

Origin of Species:

Common descent

Natural selection

Gradual change

**Evolution Mechanisms**

Mutations:

Random genetic changes

Source of new alleles

Can be beneficial, harmful, or neutral

Genetic Drift:

Random changes in allele frequencies

Founder Effect: Small group establishes new population

Bottleneck Effect: Population severely reduced

Gene Flow:

Movement of genes between populations

Migration and interbreeding

Natural Selection:

Conditions:

Variation exists

Traits are heritable

Differential reproduction

Fitness Elements:

Survival

Reproduction

Resource acquisition

Sexual Selection:

Mate choice

Competition for mates

**Types of Selection**

Directional: Favors one extreme

Stabilizing: Favors intermediate traits

Disruptive: Favors both extremes

**Evidence for Evolution**

Fossil Record:

Radiometric dating determines age

Fossilization preserves remains

Missing links show transitions

Biogeography:

Geographic distribution of species

Example: Marsupial distribution

Comparative Anatomy/Embryology:

Homologous Structures: Same origin, different functions

Vestigial Structures: Reduced, non-functional

Convergent Evolution: Similar traits in unrelated species

Molecular Biology:

DNA/protein similarities

Genetic code universality

Laboratory/Field Studies:

Observable evolution

Experimental evidence