Units 1-8 Ap Bio Lecture Notes

Unit 1 🟢

Unit 1

The Study of Life

• Biology is the scientific study of life.

• Properties of life include:   - Order: Organisms are complex and organized.   - Regulation: Homeostasis, such as body temperature regulation in mammals.   - Growth and Development: Organisms grow and develop according to specific instructions coded for by their genes.   - Energy Processing: Living organisms take in energy to perform work. For example, plants convert sunlight into chemical energy via photosynthesis.   - Response to the Environment: Organisms respond to environmental stimuli. For instance, plants grow towards light.   - Reproduction: Organisms reproduce their own kind, either sexually or asexually.   - Evolution: Populations of organisms evolve over time.

The Scientific Method

• The scientific method is a systematic approach to understanding the natural world and includes:   1. Observation: Gathering information in a systematic way.   2. Question: Asking a question based on observations.   3. Hypothesis: Formulating a testable explanation based on observations.   4. Experiment: Testing the hypothesis through experimentation.   5. Analysis: Analyzing data to draw conclusions about the hypothesis.   6. Conclusion: Determining whether to reject or fail to reject the hypothesis. If rejected, reformulate a new hypothesis.

Themes in Biology

• Evolution: The core theme that unifies all of biology, describing the descent with modification from common ancestors over time.

• Structure and Function: The relationship between structure and function in biological systems, exemplified in various forms of life.

• Information Flow: The concept that information is passed from one generation to the next through DNA; gene expression governs the characteristics of organisms.

• Energy and Matter: The flow of energy and cycling of nutrients are essential to the survival of organisms.

• Interactions: Biological systems interact, and these interactions can result in complex behaviors and emergent properties.

Levels of Biological Organization

• Atoms: The basic units of matter.

• Molecules: Groups of atoms bonded together (e.g., DNA).

• Cells: The basic unit of life, can be prokaryotic or eukaryotic.

• Tissues: Groups of similar cells performing a specific function.

• Organs: Structures composed of different tissues serving a specific function.

• Organ Systems: Groups of organs that work together.

• Organisms: Individual living entities.

• Populations: Groups of organisms of the same species living in the same area.

• Communities: Different populations living and interacting in a particular area.

• Ecosystems: Communities interacting with their physical environment.

• Biosphere: The global sum of all ecosystems.

Basic Chemistry for Biology

• Atoms: Comprised of protons, neutrons, and electrons. The atomic structure influences the chemical properties of elements.

• Ionic Bonds: Formed when one atom transfers electrons to another atom, resulting in charged ions.

• Covalent Bonds: Formed when two atoms share one or more pairs of electrons, creating molecules.

• Hydrogen Bonds: Weak attractions between molecules or within a single molecule (e.g., between water molecules).

• Water: Essential for life, it has unique properties such as being a polar solvent, having a high heat capacity, and being less dense as a solid than a liquid.

The Cell Theory

• The cell is the basic unit of life.

• All living organisms are composed of one or more cells.

• All cells arise from pre-existing cells.

Types of Cells

• Prokaryotic Cells: Simple cells without membrane-bound organelles. Examples include bacteria.

• Eukaryotic Cells: More complex cells containing membrane-bound organelles. Examples include plant and animal cells.

The Importance of DNA

• DNA serves as the genetic blueprint for all living organisms. It carries instructions for development, functioning, growth, and reproduction.

Unit 2 🟢

Cells

Cells: the basic unit of life

• Prokaryotic Cells: no membrane bound organelles

  • Has ribosomes

  • Small in comparison to eukaryotic cells

• Eukaryotic Cells: Membrane bound organelles

• Endosymbiosis Theory: hypothesized that some prokaryotes begin to live together in symbiotic relationships with the smaller prokaryotes living inside larger ones

• Nucleus: This structure controls the activities of a cell by holding the DNA

Organelles

• Nucleus: Controls the activities of a cell by holding the DNA

  • The DNA of eukaryotes is enclosed within a membrane called the nuclear membrane or envelope

  • Prokaryoic DNA floats in the cytoplasm and is sometimes referred to as nucleoid (nucleus-like)

• Cytoplasm/cytosol: Fluid filled space contains the nucleus and other organells

  • Makes up most of the volume of the cell

• Plasma “cell” membrane : holds the cell together

  • The membrane is important for transporting substances into and out of the cell

• Ribosomes: Synthesize (make) proteins according to mRNA instructions

  • Evidence for common ancestry

  • Non-membrane bound

• Endomembrane System: Group of membrane bound organelles that work together to modify and package materials

  • Er, Golgi Complex, Lysosomes, Vacuolies, Vesticles, Nuclear Membrane

• Endoplasmic reticulum: Plays a role in intracellular transport

  • Rough Er: helps sysnthesize and package proteins

  • Smooth ER: helps synthesize lipids and breakdown catbs

    • Helps detoxify the blood

• Golgi Apparatus: Folds, modifies and synthesizes cellular products and packages proteins for trafficing

  • Makes glycoproteins

• Mitochondria: Performs the process of cellular respiration

  • Double membrane allows for different compartments for different metabolic reactions

  • Has its own DNA

  • Evidence for endosymbiotic theory

    • Mitocondria has its own DNA and does it’s own reacions; cell respirations.

• Lysomsomes: help carry out the process of cellular digestion

  • Contains hydrolytic enzymes

  • Plays a role in apoptosis

    • Cell death when there isn’t enough energy to live

  • Membrane bound

• Vacuoles: plays different roles in animal and plant cells

  • Membrane bound

  • Plants: large vacuole maintains turgor pressure through water/nutrients storage

    • More tugor presser allows plant cells to maintain shape and hold water

  • Animals: more, smaller vacuoles that store cellular material

• Chloroplast: Where photosynthesis takes plae

  • Has its own DNA, ribosomes, and enzymes

  • Has double membrane

  • Contains chlorophyll

  • Evidence of endosymbiotic theory

    • Cloroplast has it’s own DNA and use to be it’s own cells and prokaryote and

Size Matters: Cell size and efficiency

• Cells that have large surface area to volume ratios are more efficient at exchanging materials with their environment

  • The smaller the ratio of the cell the more efficient

• Organisms have certain adaptations that allow them to increase their surface area to increase their efficiency

  • Typically: smaller organisms= higher metabolic rate per unit body mass

Cell’s Bouncer: Plasma Membrane

• Plasma membranes are made up of phospholipids

  • Phospolipids have hydrophilic heads and hydrophobic tails

  • Separates cells from their outside environment

  • Selectively Permeable: only allows certain materials in/out

  • Extracellular: outside the cell

  • Intracellular: Inside the cell

• Proteins embedded into the membrane can be hydrophobic (Nonpolar sides groups) or hydrophilic (charged, polar side groups) or both

  • Hydrophilic regions are inside the interior of the protein or exposed to cytosol

  • Hydrophobic region of proteins make up protein surface

• Peripheral Protein: on oen side of the membrane

• Intergral Protein: embedded in the plasma membrane

• Glycoprotein/glycolipidsL on the outside of the membrane for sgnalling

• Cholesterol: lipid molecule functions to keep the membrane from being too fluid, and too permeable to soem small molecules.

  • helps to secure the proteins that are embedded in the membrane

  • helps to keep the cell membranes of plant cells from freezing solid in very cold temperatures

Let me in Please!: Membrane Permeability

• Because the membrane is semi-permable, concentration gradents occur across the membrane

• Small, Nonpolar molecules freely pass through the membran

  • N2, O2, CO2

• Large polar molecules and ions have to move through the membrane with embedded channels and transport proteins

  • K+, Na+

  • The nonpolar hydrocarbon tails prevent these molecules from moving

• Small, polar uncharged molecules pass through the membrane in small amonts

  • H2O, NH3

Let me in Please!: Membrane Transport

• Passive Transport: movement of molecules from high concentration to low concentration without energy

  • Diffsion: molecules moving from high to low concentration through the membrane

  • Facilitated Diffusion: Requires transport or channel proteins

    • Aquapirins specifically transport water

• Active Transport: requires the direct input of energy

  • In some cases, moves molecules from low concentration to high concentration

• Endocytosis (Bulk Transport)L cell takes in large molecules by folding the membrane in on itself forming small vesticles

  • Requires energy

• Exoocytosis (bulk transport): Internal vesicles release materials from cells by fusing with the membrane

  • Requires energy

Let me in Please!: Tonocity and Osmoregulation

• Osmosis: type of diffusion. This means that water oves form area of high water concentration to areas of low water concentration. JUST WATER

  • Hypotonic enviroment: Lower concentration of solutes in the environment than a cell

  • Hypertonic Environment: Higher concentration of solutes than a cell in the environment

  • Isotonic Environment: The same concentration of solutes in the cell and in the environment

• Water moves form hypotonic to hypertonic regions

  • High water potential to low water potetial

• Water potential equation Ѱ = Ѱp + Ѱs

  • Ѱ = Water potential

  • Ѱp = pressure potential

  • Ѱs = solute potential

    • Ѱs - -iCRT

      • i = ionization content

      • C= molar concentration

      • R= pressure content (.0831)

      • T= Kelvin temperature

Flashcards

• What is the basic unit of life?

  • Cells

• What is the main difference between prokaryotic and eukaryotic cells?

  • Prokaryotes lack membrane-bound organelles. Eukaryotes have membrane-bound organelles.

• Which organelle controls cell activities by holding DNA?

  • Nucleus

• Where is DNA found in prokaryotes vs eukaryotes?

  • Prokaryotes: nucleoid region in cytoplasm. Eukaryotes: inside the nuclear envelope.

• What is the function of ribosomes?

  • Synthesize proteins according to mRNA instructions

• What is the endomembrane system?

  • Group of membrane-bound organelles that modify and package materials: ER, Golgi, lysosomes, vacuoles, vesicles, nuclear membrane.

• Rough ER vs Smooth ER functions

  • Rough ER: synthesizes and packages proteins. Smooth ER: synthesizes lipids, breaks down carbs, detoxifies.

• Function of the Golgi apparatus

  • Modifies, folds, and packages proteins. Makes glycoproteins.

• Mitochondria key features

  • Double membrane, compartmentalization, own DNA. Evidence for endosymbiosis.

• Function of lysosomes

  • Intracellular digestion with hydrolytic enzymes. Role in apoptosis.

• Plant vs animal vacuoles

  • Plants: one large central vacuole for turgor. Animals: multiple smaller storage vacuoles.

• Chloroplast traits and function

  • Site of photosynthesis. Double membrane, own DNA and ribosomes, chlorophyll. Endosymbiosis evidence.

• Why are small cells more efficient?

  • Higher surface-area-to-volume ratio improves exchange.

• Main components of the plasma membrane

  • Phospholipids, embedded proteins, cholesterol, glycoproteins, glycolipids.

• Peripheral vs integral proteins

  • Peripheral: on one side of the membrane. Integral: embedded in the membrane.

• Role of cholesterol in membranes

  • Prevents excessive fluidity and permeability. Stabilizes proteins. Helps prevent freezing in plants.

• Molecules that freely cross bilayer

  • Small nonpolar molecules: N2, O2, CO2

• Molecules requiring transport proteins

  • Ions and large polar molecules, e.g., K+, Na+

• Passive transport definition

  • Movement from high to low concentration without energy.

• Simple vs facilitated diffusion

  • Simple: directly through membrane. Facilitated: via channels or carriers.

• Aquaporins

  • Channel proteins that transport water.

• Active transport

  • Often moves molecules from low to high concentration using energy.

• Endocytosis vs exocytosis

  • Endocytosis: intake via vesicles. Exocytosis: release via vesicle fusion.

• Osmosis

  • Diffusion of water from high to low water concentration.

• Hypotonic vs hypertonic vs isotonic

  • Hypotonic: lower solute outside. Hypertonic: higher solute outside. Isotonic: equal solute.

• Direction of water movement

  • From hypotonic to hypertonic regions.

• Water potential equation

  • Ψ = Ψp + Ψs, where Ψp is pressure potential and Ψs is solute potential (Ψs = −iCRT).

Unit 3🟢

First law of Thermodynamics: Cells need to take energy from somewhere

Second law of Thermodynamics : Energy transfer leads to less organization

• The Universe tends towards disorder (entropy)

  • Less energy to clean room, more mess in room

• Energy input must exceed energy loss to maintain order.

  • Put more energy in that you are losing

• Celllar processes that release energy can be coupled with cellular processes that require an input of energy

  • Using more energy than we have means we have to use a reaction that makes energy

    • Couples - Happens together

• Exergonic

  • Will happen on it’s own. Makes energy

• Endergonic

  • Need energy and needs to be paired with an exergonic reaction to maintain energy

Enzymes

Enzyme: Biological catalysts

• Protiens that speed up the rate of chemical reactions by lowering the activation energy

  • Primary, Secondary, and Treterairy structures

  • Made with amino acids

  • All it does is lower the activation energy

• Enzyme Specificity: Each enzyme catalyzes only one kind of reaction

  • Only one enzyme can fit into one group

  • — — —

  ---

• Co-factors: Molecules that help enzymes in catalyzing a reaction

• Inorganic co-factors are usually metal ions (Fe2+, Mg2+)

• Vitamins are examples of organic co enzymes

Environmental Impact on Enzymes

If enzymes are outside of their optimal conditions, they will denature (Change shape)

Temperature and pH will have an effect

The concentration of substrates and products can also effect the rate of an enzyme-catazlysed reaction

• An increase in substrate concentration will start off initially speeding up the reaction. Then, once all of the enzyme in solution is bound by substrate, the reaction can no longer speed up.

• Saturation Point: This concentration of substrates where all of the enzyme in a reaction is bound by substrate

At this point, the reaction rate reaches a maximum velocity (V_max), and further increases in substrate concentration will not affect the rate of the reaction.

Reactions

Photosynthesis

Light dependent Reactions

• Occurs in the chloroplast thylakoid membrane

• Starting materials

  • Water: provides electrons for the ETC

  • Photons (light): Energy

• Products

  • ATP

  • NADH

Light Dependent Reatcion

1. Photons (light) is absorbed by the chlorophyll in PS2

2. The energy from the excited photons in PS2 split H2O molecules into H+ and O2

   1. Electrons from the split we loose electrons and used in the ETC

3. Excited electrons moved from PH2

   1. Excited electrons - Move from low to hight

   2. When the electrons move, H= is moved form the stroma to the thylakoid lumen, creating the proton/electrochemical gradient

4. Electrons reach PS1

5. PS! absorbs more hotons and excites the electrons

6. Excited electrons are used to fix NAD+ into NADPH in the stroma

   1. NADPH is then used in the Calvin cycle )light independent reactions)

7. H+ gradient (high in lumen, low in stroma) drives ATP synthase

   1. Converts ADP+P into ATP

Light Independent Reaction

• Occurs in the stroma

• Starting Materials

  • 3CO2

  • 9 ATP

  • 6 NADPH

• Products

  • G3P → Glucose

More

   1.Carbon Fixation: CO2 from the atmoshere is attached to the RUBP (5 carbon acceptor) by rubisco (enzyme)

1. Unstable 6 carbon intermediate is formed that immediately splits into 2, 3carbon molecules (PGA)

1. Reduction: the PGAs are reduced by AT and NADPH which makes G3p

   1. ADP and NADP+ are sent back to the light reaction

2. Carbohydrate Output: for every 1 G3P, the cycle must fix 3 CO2 molecules

   1. The G3 is later combined into larger carbohydrate molecules (glucose)

TLDR - Photosynthesis

Know where each stage happens

• light reactions = thylakoid membrane/ lumen (ATP/NADPH produced)

• Calvin cycle = stroma (used ATP/NADPH to fix CO2

Be able to explain chemiosmosis (proton gradients → ATP synthase) and how electron carriers move electrons

Understand Rubisco’s role (CO₂ fixation) and the three core Calvin phases (fixation, reduction, regeneration). Rubisco is often tested conceptually (limitations, oxygenase activity/photorespiration may be discussed in context).

Glycolysis

• Occurs in cytoplasm/cytosol

• Glucose → 2 pyruvate + 2 ATP + 2 NADH

1. Glucose in phosphorylated by ATP → Glucose - 6 - phosphate

2. The results is phosphorylated again by another ATP → Fructose 1,6-biphosphate

3. 6 carbon molecules is cleaved into 2, 3-carbon molecules

   1. 2 G3P

4. G3P is oxidized: NAD+ →NADH

5. Substrate level phosphorylation

   1. 4 ATP

Link Reaction/Pyrucate Oxidation

• Happends in the mitochondrial matrix

1. Carbon removed: CO2 released

2. NAD+ → NADH

3. Remainign 2 carbon is attached to coenzyme A → Acetyl CoA (enters Krebs’s cycle)

Per glucose: 2 Pyruvate → 2 Acetyl CoA, 2 NADH, 2 CO2

Kreb’s Cycle/Citric Acid Cycle

• happens in the mitochondrial matrix

For 1 glucose there has to be two cycles, er 2 cycles

• 6 NADH

• 2 FADH2

• 2 ATP

• 4 CO2

ETC and Chemiosmosis/Oxidative Phosphorylation

• Happens in the mitochondrial membrane

• Goal: Use energy from NADH/FADH2 to pump H+ and create proton gradient

1. NADH donates electrons to complex 1

   1. Electrons move down the chain

   2. Energy used to mover H+ into intermembrane space

2. FADH2 donates electrons to Comples 2 (no proton pumping)

3. Electrons move via ubiquinone (Q) and cytochrome complexes

4. O2 is the final electron acceptor, combining with electrons + H+ turns into H2O

   1. W/O oxygen, the ETC stops

5. Proton gradient builds in intermembrane space (igh H+ outside, low inside)

6. H+ flows back into the matrix through ATP synthase (Chemiosmosis)

7. ATP synthase phosporylate AD to lost of ATP

Main idea: Electron flow creates a gradient; the gradient powers ATP synthase

Environmental Imact on Enzymes

Light Dependent Reactions

• Protein channel is used to charge the electrons

Light Indendent Reaction

Glycolysis

• happens twice

Link Reaction/ Pyrucate Oxidation

Krebs Cycle

ETC and Chemiosmosis

Unit 4 🟢

How do cells communicate?: Cell Phones

Cell use chemical signal to “talk” to each other

• Autocrine: Cell talking to itself

• Paracrine: Short distance

  • growth factors

  • like a dog and clothing

• Juxtacrine/Direct contact: To a cell directly

  • A back and forth conversation with a friend

  • Gap junctions (animals) plasmodesmata (plants)

• Endocrine: Long distance, through bloodstream

  • A paper airplane to your friend on the other side of the classroom

  • Hormones (from the back of your head to the location)

Big girl AP common questions

• Quorum Sensing: Bacteria regulates population-based behaviors like biofilm formation

  • Smalls signals increase with the increasing population density. When the max is hit a gene expression is triggered.

  • Based on weight sensing

• Epinephrine Signaling (adrenaline): when cells convert glycogen into usable sugar/energy

  • Flight or flight reaction

  • liver cells break down glycogen into glucose

  • smooth muscle cells in blood vessels tighten or loosen based on the type of receptor

Signal Transduction Pathways:

Stimulus→ Signal sent → Reception by target cell → transduction → cellular response

1. Stimulus → Signal Sent

• Ligands: signals (molecule)

  • binding starts with a signal transduction

  • Very specific (think of enzymes): the correct cells get the signal;

    • Cells that don’t have the right receptors won’t do a thing. This prevents unnecessary activation

  • Water soluble ligands are external while hydrophobic (fears water) ligans are intracellular (in and out of the cell)

1. Reception by Target cell

   • G-protein-coupled receptors (GPCRs): Active G-proteins, triggering a single pathway

     • Signal received, g-protein then activated an enzyme which starts the reaction.

   • Receptor tyrosine kinase (RTKs): Triggers multiple pathways; can lead to mutations like cancer

     • One signal can trigger many pathways at once. Harder to regulate leading to cancer.

   • Ligand-gated ion channels: Opens due to ligand binding and allows ions to pass.

   • Intracellular receptors: Used by steroid hormones, it directly affects gene expression

2. Transduction - After signal is recieved

   • Transduction: interactions between protein kinase and ATP which increase the signal received by ligand binding. → Signal is multiplied

     • Amplification happens when a single kinase activates many kinase in the next level of the cascade reaction → one kinase activates many kinases

       • Many ligands allows for places for control and regulation

     • Signals are always transduced (translated) into a different form until a new/another signal is sent to prevent the phosphorylation of ATP

       • Kinases stimulate pathways

       • Phosphatase shut off pathways → takes away the phosphate

   • Dephosporylation: Happens when phosphate enzymes remove the phosphates from the protein.

   • Secondary messengers: Small, non-polar, water-soluble molecules or ions that pass a signal; spread with diffusion

     • Cyclic-AMP: Responsible for activating the protein kinase cascade. Often works with adenylyl cyclase

     • Calcium ions: Common messenger and relays signals in G-protein and Tyosine Kinase Receptor pathways.

3. Cellular Response

   • Response: Cell respond when the cascade is reached

     • Gene Expression: gene information is used to make proteins through translation and transcription

Big girl AP questions

• RTKs: Activates multiple pathways at the same time then amplifying the signal

  • Mutations when constant RTK activation leads to uncontrolled cell division. (cancer)

• GPCR: happens when a ligands binds to a reception then causing confrontational change that activates a G-protein by exchanging GDP for GTP.

  • Like ADP to ATP

  • G-protein then activates enzymes or second messengers like cAMP

• Steriod hormones: Pass thorough the plasma membrane and bind to intracellular receptors. The hormone-recptor complex acts as a transcript or factor, directly regulating gene expression.

Homie-ostasis: your normal

Homeostasis: maintained through feedback

• Negative feedback: Maintains stability (want to stop the stimulus)

  • Regulating body temp, insulin response

  • Response stops stimuli

• Positive feedback: Amplifies a response until it is complete (

  • Labor contractions, blood clotting

Big girl AP questions

• Blood sugar regulation: WHen blood glucose is high, the pancreas released insulin, causing the cells to absorb glucose. When blood glucose is low, glucagon is released to break down glycogen into glucose

• Labor Contractions: oxytocin is released, causing stronger contractions, stimulates more oxytocin and releases until childbirth occurs.

• Thermoregulation (in mammals): When body temperature rises, sweating and vasodilation dissipate heat. When temperature drops, shivering and vasoconstriction conserve heat.

My toe, sis

Purpose of cell Division:

• Unicellular: to reproduce

• Multi-Cellular: growth, repair, replace dying/ dead cells

• Parent and daughter cells are identical: DNA organelles, etc.

• DNA in Cell Division:

  • Chromatin: Coiled DNA

  • Chromosomes: DNA that is wrapped tightly

  • Sister Chromatids: A chromosome that duplicated

Interphase: Cells are often in this phase the longest

• NO division happens

• 3 phases of interphase: G1, S, G@

  • G0 phase: Optional part when cells exit the cell cycle and no longer divide

  • G1: Cells grow after the are “born” or created

  • S: DNA replicates prior to cell division

    • This happens before cell division so each daughter cell has a full set of DNA

  • G2: Cell finished growth: prepared to divide by making organelles, proteins, and membranes

• G1 checkpoint: Checks for DNA damage before it replicates. Makes sure there is efficient space and nutrients for division

• G2 Checkpoint: Makes sure DNA has been fully copied and there isn’t damage to the DNA

• M checkpoint: Makes sure there are proper chromosome alignment before division. Makes sure all chromosomes are attached properly to the spindles (little hairs that pull chromosomes apart)

Mitosis: cell division of somatic cells that makes identical daughter cells

• Prophase: Chromosomes become visible, unclean envelope dissolves, centrosomes form and spinde fibers attach to the chhromsome

• Metaphase: Chromosmes line up in the middle of the cell; centrosomes move to opposit side of the cell

• Anaphase sister chromatids are lulled to opposite sides of the cell by the spindles

• Telophase: centrosomes dissemble, nucli reform, chromosomes start to uncoil back into chromatin

• Cytokinesis in animal cells: cleavage furrow. Where the breakage of the cells happen

  • Cytokinesis in plant cells: cell plate which become a cell wall that separates the resulting daughter cells

Role of cyclins

• Cyclins: Proteins with concentrations that rise and fall throughout the cell cycle, acting as regulatory sununits that control CDK activity

• CDKs: Enzymes that add phosphate grougs to other proteins, activating or deactivating them to control cell cycle events

How they work together

• Activation: A specific cyclin pairs with a specific CDK

• Phosphorylation: Activated compels the prophylaxes key target proteins

• Progression: Phosphorylation triggers specific cellular events, pushing the cells into the next ohase

Cylcial Nature: Cyclins are degraded after their job is done. Inactivating the CDK and allowing the cycle to progress to the next stage, ensuring events happen in the correct order

Regulating Cell Cycle

Cancer: results from unregulated cell division due to mutations in proto-oncogenes or tumor suppressor genes

Examples:

• p53 gene: Suppresses tumors; if mutated, cells evade apoptosis

• Ras gene: Mutations can lead to constant cell division

Big girl AP questions

• Tumor - suppressor gene Mutations: prevents apoptosis, allows damaged cells to accumulate mutations that contribute to tumor growth

• Oncogenes: mutated proto-oncogenes that cause unregulated division

  • Common example is the RAs protein, when mutated, it remain constantly active, driving continuous cell divison

• Chemotherapy: targets rapidly dividing cells by disrupting the spindles formation affecting the cancerous and (some) healthy cell

What is the Chi-Square

Big Idean: Data with variation. This helps to decide the differences between what is observed and what we expect are due to change or a real biological effect

Key question: Are the observed result significantly different from the expected results?

What is a Chi-square: Statically test that compares:

• Observed values: What actually happened in the experiment

• Expected values: What we predicted before collecting data

Important notes:

Larger value: greater difference between observed and expected

Smaller value: observed data closely matches expected data

Chi-square DOES NOT tell you why results differ, only whether they differ significantly

How to solve a Chi Squared Problem: LAST SLIDE

1. State the null hypothesis

   1. No significant difference

2. Calculate

Unit 5 🟢

Meiosis

• prophase 1

• Metaphase 1

• Anaphase 1

• Telophase & Cytokinesis

• Prophase 2

• Metaphase 2

• Anaphase 2

• Telophase & Cytokinesis

Takeaways

The separation of homologous chromosomes in meiosis 1 makes sure that each gamete gets a haploid (1n) of chromosomes

• Each has both maternal and paternal chromosome

Causes of

Mendelian Genetics

Came up with modern genetics and really important laws while playing with pea plants. Work was accepted in the 20th century (1900s)

• All genetic information is stored in DNA or RNA

  • All cells have the same sets of DNA, certain genes are activated or deactivated

• Nuclear DNA and Mitochondrial DNA

  • Nuclear DNA comes from mom and dad, mitochondrial DNA comes from just mom

• RNA is used to create proteins with ribosomes

• All DNA has the same nucleotides (A,T,G,C)

  • Means we come from the same ancestor

Vocab

• Allele: A version of gene that can be dominated or recessive

  • W/ mendelian genetics, all genes have two alleles (Aa)

• Autosomal: On a chromosome that isn’t on a sex chromosome

• Diploid: A cells that has two complete sets of chromosomes. One from each parent (2n)

• Haploid:

• Phenotype: Physical appearance of an organism (PHenotype, PHysical)

  • Mom has brown eyes I have brown eyes

• Genotype: the alleles that make up the trait (GEnotype, GEnes)

  • AA, Aa, aa

• Dominant: Produces more proteins to overtake another trait

  • Aa - The big A takes over

• Recessive: A trait that doesn’t produce enough proteins or product that is overpowered by dominant traits

  • Can take over if it is aa

• Homozygous Recessive: An organism that had two recessive alleles. The organism will have the recessive phenotype. The weak one is doubled

  • aa, bb, gg

• Homozygous Dominant: An organism that has two dominant alleles. The dominate phenotype

  • AA, BB, GG

• Heterozgous: An organism that has one dominant and one recessive allele. It will have the dominant phenotype

  • Aa, Bb, Gg

  ---

  Applying Vocab: Punnet Square

  • Yellow Pea: YY

  • Green Pea: yy

  • 50% for a green baby and 50% for a yellow baby

  Laws of probability

  • Yellow and green baby (one of each)

    • P(A and B) - P(A) x P(B)

  • R- Cannot roll tonnge

  • r - Can roll tonnge

  • % for homo zygouous

  • % for heterozygoute

  
  

Punnett Square are called “monohybrid” crosses

Mono - One

Hybrid - Mix

Cross - Cross…

Dihybrid Crossess

• Yellow vs Green

• Round vs Wrinkled

• 9:3:3:1

  • 9 will be RY ( Round and yellow)

  • 3 will be Ry

  • 3 will be rY

  • 1 will by ry

Probability of green wrinkled

1/16

Probability of Yellow and round

9/16

Stuff isn’t that Simple: Sex Linked

R: Not color blind

r: color blind

• Probability of a son (XY) that is color blind

  • 50%

• Probability of a daughter (XX) that is color blind

  • 100%

Making Predictions

• Rules of probability can be used to predict the passage of single gene traits from parent to child

• Can be helpful in determine if traits are Mendelian or not

  • We can predict the pattern of inheritance form analyzing trait and geneome date

    • Is this trait recessive? Dominant? Sex-linked? Linked genes?

Unit 6🟢

Dna and RNA Structure

Genetic information is passed to the next generation thought the DNA (sometimes RNA) molecules

• Prokaryotes - Circular DNA Eukaryotes - Linear DNA

• They both can have plasmids: extrachromosomal circular molecules

DNa and RNA are nucleic acids

• Nucleic Acids: Made up of nucleotides

  • Phosphate group + nitrogenous bases (letters) + 5 carbon sugar

    • Ribose in RNA and deoxyribose in DNA

  • T in DNA, U in RNA

Purines and Pyrimidines

• Purines: 2 ringed nitrogenous bases

  • A and G

• Pyrimidines: single ring nitrogenous bases

  • T (U) and C

DNA Replication

The replication process ensures the continuity of heredity information

• happens in mitosis and meiosis (S phase)

• New DNA is made from the 5’ to 3’ direction

• DNA replication is semi-conservatives

  • Uses a DNA strand as a template for a new strand of complementary DNA

• Replication happens in the nucleus for eukaryotes and in the cytoplasm for prokaryotes

Replication steps

1. Helicase - Unwinds the DNA’s double helix so replication origins are recognized and replication can start

2. Topoisomerase relieves tension as DNA unwinds

   1. THis is called the replication fork (looks like a Y)

3. RNA primers - placed on DNA molecules by primase so DNA polymerase can start

   1. w/o the primer DNA polymerase can't work or start

4. DNA polymerase - binds to the template strand and adds complementary nucleotides

   1. Leading strand - grows continually form 5’ to 3’ direction toward the replication fork

   2. Lagging strand - grows discontinuously away from the replication fork

      1. SHort fragments made are called Okazaki Fragments

5. After lagging strand is made in fragments, DNA ligase closes the gaps between the fragments.

DNA replication Vocab

• Helicases: enzymes unwind the DNA strands

• Single Strand Binding Proteins: Bind to the unpaired DNA strands keeping them from repairing

• Topoisomerase: help reduce the twisting and tangling while the DNA strand is being unwound

• Primer: short stretch of RNA placed on the unwound parental DNA strands that acts as a template strand

  • Synthesized by primase

• DNA Ligase: joins the sugar phosphate backbones of all the Okazaki fragments into a continuous DNA strand

• DNA pol III: primary enzyme that works to synthesize the new strand

• DNA pol I: removes primers and replaces them with the proper nucleotides

• Nuclease: DNA cutting enzyme that cuts out the damaged parts of the strand and fills the space with nucleotides using the undamaged strand as a template

• Telomerase: enzyme that helps keep the length of chromosomes; aids in replacing the DNA shortening that happens during duplication

• Histones: responsible for DNA packing in chromatin

Transcription

Happens on ribosomes in the nucleus in eukaryotes and cytoplasm in prokaryotes

• Sequence of bases and the structures of the molecule determines the RNa function

  • Messenger RNA (mRNA): carries information from DNA in the nucleus to the ribosome in the cytoplasm

  • Transfer RNA (tRNA)L binds to the specific amino acids and has anticodon sequences that base pair with codons on mRNA

    • tRNA is recruited to the ribosome during translation to generate the primary peptide sequence.

  • Ribosomal RNA (rRNA): functional building blocks of ribosomes

Transcription Steps

1. RNA polymerase: Binds to what is known as promoter DNA

   1. DNA is a sequence that signals to start the genetic information for a particular gene

2. RNA polymerase unwinds and separates the DNA by creating a structure known as the transcription bubble. The bubble breaks the hydrogen bonds between nucleotides.

3. RNA polymerase adds RNA nucleotide to its “copy” by matching nucleotides to those on the antisense strand, missense strands, coding strand

4. Hydrogen bonds between RNA and DNA breaks, frees the new strand (mRNA) from helix

5. For cells w/o nuclei, RNA may undergo more steps before moving out of the nucleus. Steps may inclus splicing (editing of the sequence) , capping (attaching additional nucleotides to ends of the strand), or polyadenylation (addition of a tail of adenine bases).

6. The RNA (MRNA) strand is moved out of the nucleus via specialized pores in the nucleus.

RNA polymerase synthesizes new mRNA in the 5’-3’ direction by reading the template DNA in the 3’-5’ direction

Transcription: mRNA Procession

After mRNA is created:

• A poly-A tail (A-A-A-A-A) is added to the end of the 3’ strand of the pre-mRNA

  • Makes the mRNA more stable and last longer

• A GTP cap is added on the end of the ‘ end of the pre-mRNA

  • helps ribosome recongnize the mRNA

• Introns are removed and exons are keeps by spliceosomes

  • Different versions of the genes can be made by removing/keeping different introns and exons

    • Called alternative splicing

Translation

Translation of mRNA happens on the ribosome that are located int he cytoplasm for both the prokaryotes and eukaryotes

• Can happen on the ribosome on the rough ER on eukaryotes

• In Prokaryote, transcription and translation happen at the same time

Translation Steps:

• Initiation: rRNA in the ribosome interactions with the mRNA at the start codon (AUG)

• Elongation: nucleotides on the mRNA is ready in triplets called codons

  • Each odcon encode for a specific amino acid

  • Different codons can code for the same amino acids

  • All living organisms use the same genetic code → shows evidence for common ancestry

  • tRNA brings in amino acids to the place specified by the codon on the mRNA

  • The amino acid being transferred to the growing polypeptide chain

• Termination: elongation continues until the stop codon is reached (UAG, UAA, UGA) and a release factor releases all molecule from the process

Translation: A special Case

• Retrovirus are a unique case in that they don’t follow “central dogma”

  • Instead of DNA → mRNA → Protein, retroviruses form from RNA → DNA

• The reverse transcription is done by the enzyme reverse transcriptase

• Virus RNA goes into host organism, copies RNA genome into DNA

  • DNA integrates into the host organism then viral proteins are made but the host organism

Regulation of Gene Expression

• Regulatory sequences: stretches of DNA that interacts with regulatory protein that control transcription

  • Some genes are inducible what other are constitutively expressed

• Epigenetics: Changes that can affect gene expression with reversible modification of DNA or Histones

  • Histones: Proteins that DNA wraps around to package DNA into Nucleosomes

• Operon: Segment of DNA that has a series of structural genes and control elements that regulates transcription of the genes

  • Promoter: Where RNA polymerase binds to begin transription

  • Operator: Where a repressor protein binds to prevent the initial binding of RNA polymerase to the promoter

• Repressabe Operon: An operon that is on but can be turned off

  • Ex - Trp-operon, or the operton for the production of tryptophan

  • Operon is constantly “on”, the represson protein is unable to bind to operator and the RNA polymerase is able to synthesize mRNA leading to the creation of proteins that make tryptophan

  • Extra tryptophan helps the binding of the operon repressor protein to the operator region

• Inducible Operon: An operon that is off but can be turned on. Attached to the operator region and RNA polymerase can’t bind to make mRNA

  • Ex: Lac Operon

    • Prevents lactose in environment, is converted to allolactose. This allolactose (in a sufficient amount), binds to the repressor protein, causing a change that doesn’t allow the repressor to bind to the operator. Now the RNA polymerase can bind and produce enzymes that break down lactose for the cell.

• Differentiation: Unspecialized stem cells become mature, specialized cells with distinct structures and functions. Drevign by selective gene expression ( when specific genes are being turned off and on)

  • Different activations of transcription factors “activation” different genes in different cells

Gene Expression and Cell Specialization

RNA polymerase and transcription factors bind to promoter or enhancer DNA sequences to start transcription

• Sequences can be upstream or downstream of the target gene

• Negative regulatory molecule inhibit gene expression by binding t DNA and blocking transcription

• Results in differential gene expression and influences products and cell function

• Organisms must be able to turn on and off certain genes in response to external stimuli for the environment. If not they might waste resources

  • DNA methylation addition of the methyl groups (CH3) to the DNA

    • Cause gege expression to stop

  • Histone acetylation: attachment of acetyl groups (COCH3)

    • Cause gene expression to increase and lossens the compactness of DNA

• Methylation and acetylation can be inherited and reverse

• Post transcriptional modifications can degrade protein and use amino acids later

Mutations

A mutation is an alteration in a DNA sequence that can cause changes in the type or amount of the protein produced and the consequent phenotype

Mutation are random or occur as a result of environmental causes.

If a severity is determined on the environmental context

mutations are the primary source of genetic information

• Mutations can be beneficial, harmful, or neutral based on the effect or lack of effect on the resulting nucleic acid or protein and phenotypes that are produced from the change

Types of mutations

• Point mutations: One nucleotide is substituted for a different ncleiotice

  • AKA - substitution

• Frameshift Mutation: One or more nucleotides are inserted or deleted

  • Insertion or deletion mutation

  • Causes the codons to change

• Nonsense Mutation: when a point mutation causes a premature stop

• Silent Mutation: When the change in the nucleotide sequence has no effect on the amino acid sequence

Bacterial Changes

• Transformation: Bacteria takes foreign genetic material(plasmids) from their environment then altering their genotype

• Transduction: Viral transmission of genetic information

• Conjugation: cell to cell transfer of genetic information

• Transport: movement of DNA segments within and between DNA molecules.

Genetic Variation

• All previously mention processes increase genetic variation

• Reproductive processes that increase genetic variation are evolutionarily conversed and are shared by various organisms

  • Random assortment

  • Crossinf over

  • Random fertilization

Biotechnology

Biotech - Genetic engineering techniques can be used to analyze and manipulate DNA and RNA

• Gel electrophoresis: process that seperates DNA fragments by size

• Polymerase Chain Reaction: DNA fragments are amplified by denaturing (unzipping) DNA< annealing (sticking) rimers to the irginial strand, and extending the new molecule

• DNA sequencing: Determins the order of the nucleotides in a DNA molecule

  • Results in DNA fingerprins that allows us to compare DNA sequences from different samples

Unit 7🟢

Evolution: Change at the Population Level, not Individual

Evolution: Change in the genetic makeup/alleles frequencies in the population’s gene pool

• Individuals are born with a genotype and generally keep it for life, population evolve across generations

  • Genotype (the genes, what is inherited by the parents)

  • Alleles- AA, Aa, aa

An individual can’t evolve because evolution requires changes in allele frequencies across generations

• Individuals can acclimates (____): a short-term physiological (physical change) adjustment

  • Produce more red blood cells at high altitude

  • Develop: changing phenotype as the grow

  • The changes do non alter the DNA passed to offspring

  • Natural selection acts on individuals’ phenotype but evolution is measured as genetic change in the population

Natural Selection: Genetic Variation

Genetic Variability: The differences among individuals in a population

Natural Selection can only occur if some individuals already has some heritable variants (traits that can be passed down) that increase evolutionary fitness in that environment

• More genetic variation a population has the more it will be the gene that will save the population when the conditions change.

• Natural selection cannot make useful traits on demand, it sorts existing heritable variation. Variation must exist first.

Sources of Gentic Varation

• Mutations: random changes in DNA sequences that create new alleles

  • Most mutations are bad or neutral but there will be an occasional benefit.

• Recombination in Sexual reproduction: Prduces new combination of existing alleles

  • Crossing over in meiosis (prophase I)

  • Independent assortment of homologous chromosomes

  • Random fertilization

Many traits depend on both gene and environment: genes provide potential and the environmenat influences expression

• Selection acts on phenotypes but only heritable (genetically influenced) phenotypic differences can cause evolutionary change.

• Typical qustion

  • Show changes in an individual

  • Show what traits can respond to natural selection

  • Explain how mutations and recombination generate variation

• DON’T SAY

  • Saying organisms “mutate because they need to.” Instead, mutations arise randomly; selection changes frequencies.

  • Treating acclimation as evolution.

  • Forgetting that selection acts on phenotype but evolution is measured genetically.

Darwin’s Logic, Machanisms, and Patterns

Darwin’s reasoning can be summarized as a set of observations and inferences - if true.. XYZ will happen:

• Each species produces more offspring that can survive

• Offsprink compete with one another for limited resources

• Organisms in every population vary

• Individuals with favorable heritable trait are more likely to be passed to subsequent generations

A reliable way to analyze selection scenarios is to check four conditions:

1. Variation: individuals different in a trait

2. Heritablility: Some of that variation is genetic and can be passed to offspring

3. Overproduction/competition: more offspring are produced that can survive; limited resources

4. Differential reproductive success:; individuals with certain traits leave more viable. .fertile offspring

Evolutionary Fitness: reproductive success (alive babies)

• Amount of babies that can make more babies

• Fitness is dependent on the environment and can change when biotic (living) and abiotic (non-living) factors

  • Different genetic variations can be selected for in different generations

Fitness in not just strength or longevity. A trait can reduce survival yet still be favored if it increases reproduction

Diffferential Selection: Favors one etream phenotype shifting the population mean

• peppered moths changing color during industrial revolution’s pollution

• Increased beak depth during drought if harer seeds domuinate

Stabulizinf Selection: Favors intermediate phenotypes and reduces variation

• Human birth weight (small and big babies didn’t live long)

Disruptive Selection: Favors both extreams over intermediates, potentially increasing variation and sometimes contributing to specuation. It doesn’t automatically produce speciation, it requires reduced gene flow and the evolution of reproductive isolation

• Birds with small or large beaks get most food but the food is usually small or large

Types of Selection

Selectual Selection: types that improve mating success

• Intrasexual selection*:* competition within one sex (often male-male competition)

• Intersexual selection: mate choice (often female choice)

  • ADD EXAMPLES

Typical Questions patters:

• Given data (survival rates), explains how natural selection changes allele frequencies

• Interpret trait distribution graphs and identify

• Distinguish survival advantage from reproductive advantage (fitness) and connect fitness to specific biotic/abiotic pressures.

• Explain why acquired-traits idea does not produce population-level allele-frequency change.

Common Mistakes:

• Distinguish survival advantage from reproductive advantage (fitness) and connect fitness to specific biotic/abiotic pressures.

• Explain why acquired-traits idea does not produce population-level allele-frequency change.

Artifical Selection: Human Driven Change

Artificial Selection: occurs when human intentionally choose what they traits they want

• It is evolution because allele frequencies change across generations, but the selecting agent is human preference rather than the natural environment

• Artificial selection often reduces genetic diversity, especially when breeders use a narrow subset of individuals repeatedly.

Typical question patterns:

• Compare natural selection and artificial selection (same logic, different selecting agent).

• Predict consequences of selective breeding on genetic variation.

• Identify whether a scenario is artificial selection or natural selection caused by humans.

Common mistakes:

• Labeling antibiotic resistance as artificial selection.

• Forgetting that selection requires heritable variation.

• Assuming artificially selected traits always increase fitness in nature.

Population genetics: Measuring Evolution

Population Genetics: connects Mendelian genetics to evolution by tracking how allele frequencies change over time

• Mendel’s law scale up to populations, allowing predictions about genotype frequencies when specific conditions are met

For a gene with two alleles, A and a:

• Allele frequency is the fraction of all alleles in the gene pool that are A versus a.

• Genotype frequency is the fraction of individuals that are AA, Aa, or aa

• Because diploid individuals carry two alleles, allele frequencies are often calculated by counting alleles

The Hardy-Weinberg Model: describes an ideal population in which allele frequencies do not change from generation to generation

• In AP Biology, HWE functions as a null hypothesis: if observed genotype frequencies match HWE expectations (given the assumptions), there is no evidence of evolution at that gene under those conditions.

• If observed frequencies differ, one or more assumptions are violated.

For a two-allele system with allele frequencies p (A) and q (a):

• p + q = 1

Expected genotype frequencies under HWE:

p2 + 2pq + q2 = 1

Where:

• p2: the expected frequency of AA (homozygous dominant)

• 2pq:the expected frequency of Aa (heterozygous)

q2 the expected frequency of aa (homozygous recessive)

HWE requires:

1. Very large population size (minimizes random sampling effects).

2. Random mating with respect to the gene.

3. No natural selection among genotypes.

4. No migration (gene flow).

5. No mutation (or mutation negligible over the timeframe).

What happens if these conditions are not met:

1. If the population is small, it is more susceptible to random environmental impacts and sampling effects; allele frequencies can change by chance (genetic drift).

2. If mutations occur, new alleles are introduced and genetic equilibrium is disturbed.

3. If immigration or emigration occurs, individuals entering or leaving bring or remove alleles.

4. If mating is non-random, individuals choose partners based on certain traits; genotype frequencies shift (often more homozygosity), even if allele frequencies may not immediately change.

5. If natural selection occurs, organisms better adapted to the environment survive and reproduce more, so their alleles become more common.

Typical question patterns:

• Given genotype counts, calculate allele frequencies and test HWE predictions.

• Given recessive phenotype frequency, calculate p, q, and carrier frequency.

• Interpret what a deviation from HWE suggests biologically and connect it to a violated assumption.

Common mistakes:

• Confusing allele frequencies with genotype frequencies.

• Using HWE equations without checking what the given value represents (allele vs genotype vs phenotype).

• Claiming “the population is evolving” without explaining which assumption is violated and how that changes allele frequencies.

Evolution: Mechanisms besides Natural Selection

Genetic drift (evolution by chance): random change in allele frequencies due to chance events, especially strong in small population

• Drif can reduce genetic variation anc cancause alleles to become fixed or lost/. Drist isn’t random, it is random sampling of which alleles gets passed on

• Two important genetic drift events are:

  • Bottleneck effect: A bottleneck occurs when population size is drastically reduced (disaster, overhunting, habitat loss). The survivors may not represent the original gene pool, so allele frequencies can shift sharply.

  • Founder effect: occurs when a small group colonizes a new area. The new population’s allele frequencies reflect the founders’ alleles, not necessarily the source population.

  In both cases, reduced variation can increase inbreeding and reduce a population’s ability to adapt to future environmental changes.

Gene flow(migration): the transfer of alleles between population and reduce differences between populations

• can increase genetic variation within a population and reduce differences between population

• Gene flow is not automatically beneficial: migrants can introduce alleles poorly suited to the local environment, reducing local adaptation.

Mutation (source of new alleles): introduces new alleles into a gene pool. Mutation rates per gene are usually low, so mutation alone often changes allele frequencies slowly in the short term, but it is essential over long timescales because it replenishes variation.

Nonrandom Mating:Nonrandom mating (inbreeding, assortative mating) changes genotype frequencies by increasing homozygosity, even if allele frequencies do not necessarily change. This is a key reason random mating is a Hardy-Weinberg assumption.

Evidence for Evolution:

Fossil evidence, paleontology, and transitional features:

• The fossil record documents that species have changed over time and that extinct organisms existed.

  • Although fossilization is rare and biased (hard parts fossilize more; some environments preserve better), the record reveals consistent sequences and transitional features.

• Transitional features link groups by showing intermediate characteristics.

  • “Transitional” does not mean “half-evolved” or inferior; it indicates traits that help reconstruct evolutionary change across lineages.

• Paleontology has also provided methods for dating fossils, including:

  • estimating the age of the rocks where a fossil is found,

  • measuring the rate of decay of isotopes (including carbon-14),

  • using geographical data.

Biogeography: the study of the distribution of flora (plants) and fauna (animals).

• Patterns such as related species appearing in widely separated regions can be explained by common ancestry combined with migration, continental drift, and isolation.

Embryology: the study of development.

• A classic comparative observation is that vertebrate embryos (fish, amphibians, reptiles, birds, mammals including humans) show fishlike features called gill slits (pharyngeal pouches). Similar developmental patterns are consistent with shared ancestry.

Comparative anatomy:  Morphological homologies focus on anatomical structures shared across species.

• Homologous structures: similar due to shared ancestry, even if they serve different functions (for example, forelimb bone patterns in mammals). Homology supports common ancestry.

• Analogous structures: similar due to similar selective pressures, not shared ancestry (convergent evolution). A classic example is wings of birds and insects.

• Vestigial structures: reduced remnants of features functional in ancestors. They support evolution because they make sense as historical leftovers rather than optimal design.

Molecular biology (DNA and protein comparisons)

• Often the most compelling because all organisms use DNA/RNA and a largely universal genetic code. Mutations accumulate over time, and closely related species generally share more sequence similarity.

Common ancestry means that some original life-form is an ancestor of all life, with lineages branching over time.

• Phylogenetic trees (often called cladograms in many classroom contexts) are used to study relationships among organisms and are built using fossil and/or molecular data.

Key interpretation rules:

• A node represents a common ancestor.

• Two taxa that share a more recent common ancestor are more closely related.

• Rotating branches around a node does not change relationships; only the branching pattern matters.

• Trees are not “ladders of progress,” and taxa at the tips are not “more evolved” than others.

Typical question patterns:

• Distinguish homologous vs. analogous traits in scenarios.

• Use molecular sequence comparisons to infer relatedness.

• Interpret phylogenetic trees/cladograms to determine most recent common ancestors.

• Identify which lines of evidence (fossils, biogeography, embryology, anatomy, molecular data) best support a claim.

Common mistakes:

• Equating “similar function” with homology.

• Reading phylogenies as a ranking of advancement.

• Assuming the fossil record must be complete to be valid evidence.

Speciation: How new species form

Speciation: the process by which populations evolve into distinct species.

• Biological Species Concept: species are groups of populations that can interbreed in nature and produce viable, fertile offspring, and are reproductively isolated from other such groups.

Speciation connects microevolution (allele-frequency change) to macroevolution (patterns above the species level) because accumulated genetic differences and reproductive barriers split lineages, increasing biodiversity.

Reproductive isolation: prevents gene flow between populations. Once gene flow is reduced or stopped, populations can diverge genetically through selection, drift, and mutation.

• Prezygotic barriers (before fertilization): prevent fertilization.

  • Habitat isolation

  • Temporal isolation

  • Behavioral isolation

  • Mechanical isolation

  • Gametic isolation

• Postzygotic barriers (after fertilization): relate to problems after fertilization, often involving hybrid survival or reproduction.

  • Reduced hybrid viability

  • Reduced hybrid fertility (a classic example is mules)

  • Hybrid breakdown

Allopatric Speciation: occurs when populations become separated by a geographic barrier (mountains, rivers, distance) so the two populations cannot interbreed. Gene flow drops, and divergence can occur via selection and drift until reproductive isolation evolves.

Sympatric speciation: occurs without a geographic barrier. Gene flow must be reduced through mechanisms such as strong selection, habitat differentiation, sexual selection, or chromosomal changes.

• In plants, polyploidy (extra chromosome sets) can create near-instant reproductive isolation because polyploid individuals may not produce fertile offspring with the original diploid population.

Typical question patterns:

• Identify prezygotic vs. postzygotic barriers in examples.

• Predict whether speciation is more likely allopatric or sympatric given a scenario.

• Explain how reduced gene flow leads to speciation and how reinforcement can strengthen barriers.

• Interpret punctuated equilibrium vs. gradual change in terms of stasis and rapid divergence.

Common mistakes:

• Treating speciation as individuals “deciding” not to mate (barriers evolve via genetic changes affecting traits like timing, behavior, or compatibility).

• Treating speciation in animals as a single sudden mutation (usually gradual accumulation; polyploidy is the major “instant” case and mostly in plants).

• Confusing “hybrid” with “new species” (hybrids can be sterile or unstable).

• Forgetting that gene flow counters divergence.

Continued Evolution:

Antibiotic resistance: In a bacterial population, some cells may already carry alleles that provide resistance (often arising from prior mutation). When antibiotics are applied, susceptible bacteria die or reproduce less, resistant bacteria survive and reproduce, and resistance alleles increase in frequency. The antibiotic does not “teach” bacteria to resist; it changes which bacteria leave descendants.

• Misuse (overuse or incomplete courses) accelerates resistance by repeatedly applying selective pressure while leaving survivors to repopulate.

Pesticide and herbicide resistance: The same selection logic applies to agricultural pests and weeds. Resistance can evolve quickly when population sizes are huge, generation times are short, and selection pressure is intense.

• Strategies such as rotating chemicals or maintaining refuges (areas without the pesticide) can slow resistance by keeping susceptible alleles in the gene pool, reducing the speed at which resistance fixes.

Evolution in response to climate change: As climates shift, selection pressures change. Populations may respond by evolving new trait distributions (if sufficient genetic variation exists), shifting geographic ranges (a non-evolutionary response that changes where populations persist), or declining if they cannot adapt fast enough.

• Rapid environmental change can also reduce population size, increasing drift and reducing variation, which makes adaptation harder.

Conservation genetics: Genetic diversity functions like a toolkit: more diversity increases the chance that some individuals carry alleles helpful under new stresses (disease outbreaks, temperature changes).

• Small, isolated populations face increased inbreeding (more homozygosity and expression of deleterious recessives), stronger drift (loss of alleles by chance), and reduced adaptive potential.

• Conservation plans often aim to maintain habitat connectivity to support gene flow, while also considering risks such as outbreeding depression in some contexts.

Typical question patterns:

• Explain antibiotic/pesticide resistance using natural selection steps.

• Use before-and-after data to infer which genotype has the highest fitness.

• Apply evolutionary reasoning to conservation scenarios (small populations, gene flow, inbreeding, drift).

Common mistakes:

• Claiming individuals “become resistant” during their lifetime.

• Ignoring that resistance alleles must exist (via mutation/standing variation) before selection can increase them.

• Confusing population decline (ecology) with allele-frequency change (evolution), though they can interact.

Orgins of Life on Earth

• Oparin-Haldane hypothesis (early atmosphere chemistry): Alexander Oparin and J. B. S. Haldane proposed that the primitive atmosphere contained mostly inorganic molecules and was rich in methane (CH4), ammonia (NH3), hydrogen (H2), and water (H2O), with almost no free oxygen (O2).

  • This reducing atmosphere was proposed to facilitate the formation of organic molecules.

• Miller-Urey experiment: Stanley Miller and Harold Urey simulated conditions thought to resemble primitive Earth by placing the proposed atmospheric gases into a flask and using electrical charges to mimic lightning. Organic compounds similar to amino acids appeared, supporting the idea that simple organic building blocks can form under plausible early-Earth conditions.

RNA-world hypothesis:

A common hypothesis is that the earliest life-forms were simple molecules of RNA. The RNA-world hypothesis suggests RNA could have served both as genetic material and as a catalyst (ribozymes), potentially preceding DNA and protein-based life.

Typical question patterns:

• Describe what the Miller-Urey experiment tested and what its results imply.

• Identify the gases proposed in the Oparin-Haldane model and the significance of low O2.

• Explain the logic of the RNA-world hypothesis (why RNA is plausible as an early biomolecule).

Common mistakes:

• Treating Miller-Urey as “proving” exactly how life began (it supports plausibility of abiotic synthesis under certain conditions).

Assuming early Earth had abundant O2 (the model emphasizes little free oxygen).

Unit 8