Fall 24 Exam 1 Review PDF

Summary

This document is a review for a unit 1 test in a biology class. The test is scheduled for Tuesday, September 24th, 2024, and covers topics such as chemical bonds, water, carbon, and isomers. The review includes relevant questions and answers.

Full Transcript

Review Session
recording will be
uploaded to Canvas
under “Zoom” tab!

Unit 1 Test
Review
Sunday,
September 22nd, 2024
Test Information
Exam Date: Tuesday, September 24th
○ In person
This is one of your 3 midterms
○ Worth 12% your total grade
Exam will be a Canvas Quiz
○ Combination of 18 MC (1.5 pts each, 27 total) and 3 FRQs (33 pts total) - total of 60 pts
Proctoring via Respondus
○ Make sure Respondus is running by taking the practice exam
60 minute exam from 9:30am to 10:30am (do NOT arrive late)!
Check Canvas announcements for further detailed instructions
 Week 2
Chemical Bonds,
Water, Carbon and
Isomers
Terminology and Bonds
Element: one type of atom (ex. Na)
Compound: more than one type of atom (ex. NaCl)

Covalent Bonds: a sharing of two valence electrons from
two non-metals (ex. CH4 - methane)
○ Non-polar: equal sharing of electron pair(s)
C-H bond is considered non polar.
○ Polar: unequal sharing due to significant differences
of electronegativity
EN: attraction of a given atom for electrons.
Ionic: complete transfer of electrons to make ions
(ex. NaCl - table salt - Na+ and Cl-)
○ Based on charge
○ Cation (+) and anion (-)
Intermolecular Forces (AKA, weak bonds)
Weak bonds are really important too!
Interactions between different molecules, holding them together.
○ Van der Waals: due to transient dipoles between molecules
Little attractions based on instantaneous changes in local partial charges
Remember the gecko example
○ Hydrogen Bonds: occur when H covalently bound to F, O, or N
interacts with F, O, or N covalently bound to H on another
molecule.
Super important for water, DNA, and much more.

Q: What characteristic of F, O, and N makes them able to participate in hydrogen
bonding? Why can’t carbon, for example, participate in hydrogen bonds?

A: F, O, and N are considerably electronegative. When bound to H, they are
partially negative, attracting a partially positive H from another molecule.
Carbon is not electronegative enough.
Bond Summary
Water’s Emergent Properties
Water’s ability to hydrogen bond allows for life to exist
Cohesion: Water to water.
○ Helps transport water upward/against gravity
○ Surface tension
Adhesion: Water to substance/surface.
○ Water can move up plant roots by adhering to cell walls
High specific heat: Resists change in temp
○ Ocean takes up heat slower than sand/air.
Evaporative cooling: Evaporation causes surface to cool
○ Due to water’s high heat of vaporization
Expansion upon freezing: As temp decreases, number of H bonds increases
○ Ice floats on water and we get to have marine life
Great solvent: δ- and δ+ allow water to surround many ionic or polar covalent
molecules.
○ Note: nonpolar doesn’t dissolve in water
○ Terminology: put your solute into a solvent, which makes a solution
Dissociation of Water
Water dissociates to form hydroxide (OH-) and
hydronium (H3O+) ions by transferring an H+ to
another water molecule.
○ Water is continually dissociating and reforming
Adding an acid to a solution increases [H+]; adding
a base decreases [H+]. (opposite for pH)
Buffer: helps reduce changes in pH
○ Acid-base pair that combines reversibly with H+. Q: Knowing that pH = –log[H+], what will
Usually weak acid and its conjugate base happen to the pH of a solution if you
○ Shift equilibrium to either products or reactants to increase the concentration of H+ by a
counteract pH change. factor of 1000?
○ Blood buffer system: ~7.4
A: The pH will decrease by 3. pH is logarithmic, meaning
that one integer increase is equal to a tenfold change in
concentration.
Carbon: The Element of Life
Can easily bond with oxygen
○ Important for energy storage and chemical reactions in our bodies
Can form 4 bonds with any combination of single, double, or triple bonds.
○ Each bond = 1 pair of electrons
Different lengths, branching, double bond positions, and rings
○ Rings are usually 5-6 carbons and non-polar.

Q: Where have we seen rings with carbon so far?
A: Nucleotides, sugars, etc

Q: Where have we seen hydrocarbon chains so far?
A: Fatty acids, phospholipids, etc
Hydrocarbons
Hydrocarbons: organic molecules made up of only C and H
○ Many organic molecules have hydrocarbon components, such as fats/lipids
○ Can store and release a large amount of energy
Carbon burns with oxygen to give CO₂ and energy release

Q: Why are fatty acid tails in
Solid at phospholipids hydrophobic?
room temp
A: Because carbon isn’t super
electronegative (electrons
evenly distributed), there are
Liquid at no charges in a hydrocarbon
room temp to which water molecules can
adhere.
 Isomers: same molecular formula, different structures
and properties

Same covalent
Different covalent bonds, but different
bonds spatial
arrangement of
How are these atoms.
atoms connected?
How are these
aka enantiomers bonds arranged?
Geometric Isomers
Cis/trans: same covalent
bonds, but different spatial
arrangement

You cannot interconvert the
compounds by rotation
because of the double bond.
Enantiomers Mirror images of each other

The key to enantiomers: chiral centers!
A carbon bound to four different substituents.

Q: Biologically, why do we care about
enantiomers?

A: The specific arrangement of a molecule can have big consequences for its emergent
properties. Our bodies are sensitive to even the subtlest changes.
Functional Groups
 Week 3

Monomers and
Macromolecules
Functional Groups, Bonds, Polarity
Properties of
organic molecules
depend on the
carbon skeleton and
the functional group
attached to it
Polarity has huge
ramifications for
biological systems
THINK PROTEINS
2
Lipids
NOT actually a polymer b/c it’s not made up of monomer subunits, but
rather smaller units made up of different kinds (fatty acids and glycerol)
More Lipids
3 types: fats, phospholipids, sterols
○ Fats: ester linkage bonds hydroxyl
group of glycerol to the carboxyl group
of the fatty acids (3 fatty acids:1
glycerol)
○ Phospholipid: 2 fatty acids and
phosphate head bound to a glycerol
○ Steroids: 4-carbon ring lipids; NO fatty
acids
Cholesterol: a precursor from
which other steroids are
synthesized
More Lipids
Saturated vs: unsaturated fats:
○ Saturated: SOLID at room temp, linear structure
○ Unsaturated: LIQUID at room temp, cis bonds cause
kinks in fatty acids
Phospholipid bilayer:
○ Form due to water’s polarity
○ Hydrophobic tails INSIDE
○ Hydrophilic heads OUTSIDE
Membrane fluidity:
○ Amphipathic nature of phospholipids crate spontaneous
bilayers
○ Fluidity affected by temperature, lipid packing, saturation
of fatty acids, and cholesterol
Proteins
20 amino acids differing in R groups (side chains) are found in peptides and
proteins
Peptide bond: form from dehydration, joining 2 amino acids together
Makes up >50% of cell’s dry mass
Which two functional groups make up an amino acid?
More Proteins
4 levels of structure:
○ Primary: unique sequence of amino acids
○ Secondary: coils and folds in the polypeptide
○ Tertiary: determined by interactions among various
side chains (R-groups)
○ Quaternary: results when a protein consists of
multiple polypeptide chains
Shape/structure determine function
○ Affected by pH, salt concentration, temperature, or
other environmental factors, causing protein to
denature
○ What would be an ideal pH for enzymes found in our
stomach?
Nucleic Acids
Polymers of nucleotides joined by covalent bonds
○ Phosphodiester linkages join nucleotides through dehydration
Nucleic acids store, transmit, and help express
hereditary information
Central dogma of biology: DNA → RNA → protein
○ 1. DNA stores information
○ 2. RNA uses information to make proteins
○ 3. Proteins do the work in the cell
More Nucleic Acids
Adenine Thymine Cytosine Guanine

Binds with: T A G C

Purine or Purine (2 Pyrimidine (1 Pyrimidine (1 Purine (2
pyrimidine: carbon rings) carbon ring) carbon ring) carbon rings)

# of TOTAL 2 (A & T bond 3 (G & C bond
hydrogen together) together)
bonds when
bonded w/
respective
nucleotide:
More Nucleic Acids
RNA vs. DNA:

DNA RNA
Double-stranded helix Single-stranded

THYMINE, adenine, URACIL, adenine, guanine,
guanine, cytosine cytosine

Read from 5’ → 3’ Read from 5’ → 3’ direction
direction

Bases attached to Bases attached to ribose
deoxyribose sugar sugar

Serves as a template for Molecule can fold back on
both DNA and RNA itself to adopt 3D shape
More Nucleic Acids
3 main types of RNA:
○ Messenger RNA (mRNA): encodes amino acid
sequence of a polypeptide
○ Ribosomal RNA (rRNA): ribosomes-organelles that
translate mRNA
○ Transfer RNA (tRNA): brings amino acids to ribosomes
during translation
DNA reverse complementation:
What would be the reverse complementation
RNA strand of DNA strand 5’TCACGGTAC3’?
Summary
Summary
 Week 4
Prokaryotes and
Eukaryotes, Origin of
Life, and Cell Structures
and Function
Geological Record
Sedimentary rocks deposited into layers
called strata
Fossil record: major boundaries between
eras correspond to major extinction
events in fossil records
○ Biased in favor of species that
Exist for a long time
Were abundant and widespread
Had hard parts such as shells or skeletons
Origin of Life
Abiotic synthesis of small organic molecules
○ What Miller-Urey experiment proved
Molecules → Macromolecules
○ RNA monomers have been produced spontaneously from
simple molecules
Molecules packaged into “Protocells”
○ Vesicles formed from lipids - experience growth,
reproduction, and metabolism
Origin of self replicating molecules (RNA)
○ Single strand → bending → ability to self replicate
○ RNA’s catalytic ability - Ribozymes
O2 Accumulation
Cyanobacteria: photosynthesis -> released O2
Oxygen revolution: significant rise in O2 levels
(2.4 billion year ago)
Great opportunity and great problem to early
prokaryotes
○ Opportunity: using oxygen for aerobic respiration -> more
usable energy
○ Problem: oxygen and side products react with bonds,
inhibit enzymes, damage cells -> wiped out many
prokaryotic groups
Affected development of life at all levels
Prokaryotes → Colonization of land
1. Prokaryotes: 4. Multicellular eukaryotes:
Cyanobacteria Multicellularity & specialization

2. Atmospheric oxygen: 5. Animals:
oxygen revolution Cambrian Explosion

3. Single-celled eukaryotes: 6. Colonization of land:
endosymbiosis Plants and fungi began
Prokaryotes vs. Eukaryotes
Eukaryotes Prokaryotes

- nuclear
membrane - no nucleus
- more than 1 - single circular
- cytosol
chromosome chromosome
- chromosome
- membrane- - no
- ribosomes
bound organelles membrane-bound
- plasma
- generally larger organelles
membrane
- *unicellular
Prokaryotes
Biofilm formation: thick layer of prokaryotes that
have aggregated to form a colony
Lack compartmentalization
Reproduce by binary fission
Categorized by energy/carbon sources
Surface Characteristics
Fimbriae: stick to a substrate, surface, or other individuals
Pili: allow exchange of DNA
Flagella: motility - move toward or away from a stimulus
Cilia: microtubule-based hair-like organelles that extend from the surface of
almost all cell types of the human body - also used for motility
Eukaryotes
Free vs. Bound Ribosomes
Free Ribosomes: Bound Ribosomes:

Cytosol Outside of the ER or nuclear envelope
Synthesize proteins mostly for use within Synthesize proteins for export (secretion)
the cell from the cell
 Review Session
recording will be
Questions? uploaded to
Canvas under
“Zoom” tab!