SBI4U - Unit One - Biochemistry Notes _ Knowt - everything except enzymes.pdf

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SBI4U - Unit One - Biochemistry
Bonding

Ionic Bonds

dissociate easily in water
one or more electrons transferred between atoms with an electronegativity of greater than
1.7
results in cation and anion
soluble

Covalent Bonds

share electrons between atoms
three types:
polar
unequal sharing of e- pairs
EN between 0.41 and 1.7
eg. H2O
nonpolar
equal sharing of e-
electronegativity of less than 0.4
eg. H2, O2, N2, CO2, CH4
amphiphilic
some larger molecules have parts that are polar and parts that are
nonpolar
eg. fatty acids
Note - like dissolves like, so polar dissolves polar, nonpolar dissolves nonpolar

Electronegativity

determines the strength of the bond
F (fluorine) has the highest EN (highest “pull” of e-)
has to do with the distance between valence e- and nucleus
even though e- are being shared, one element may have a stronger “pull”
can lead to the formation of polar molecules
 the shape of molecules is related to their polarity

Intermolecular Forces (aka van der Waals Forces)

Hydrogen bonds
attractive force between a partially positively charged hydrogen atom and a
partially negative charge in another molecule
eg. forces between water molecules
Other van der Waals Forces
weak, momentary attractions of one molecule to the nuclei of another molecule
eg. London dispersion forces, dipole-dipole forces

Chemical Reactions

Dehydration Reaction (aka Condensation)

Removal of an OH and H to join smaller molecules and make H2O
eg. occurs naturally in plants, including sugarcane and sugar beets, from which
we refine the sugar into pure table sugar

Hydrolysis Reaction

Adding water as OH and H splitting a larger molecule
eg. happens in digestion in your stomach under the influence of the enzyme
lactase

Neutralization Reaction

Between acids and bases to form water and salt
eg. digestion - pancreas releases sodium bicarbonate and it is added to the
small intestine to increase pH

Redox Reaction

Electrons are lost from one atom and gained by another
eg. Aerobic Cellular Respiration: burning of fuel/glucose to produce energy
LEO - Lose Electrons Oxidation
GER - Gains Electrons Reduction

Water

Polar Covalent Bonds
 Oxygen has a higher EN than hydrogen

Hydrogen Bonds

Electrons spend more time near the O than the H

Cohesion
 Water molecules are attracted to other water molecules

Adhesion

Water molecules attach to other polar molecules

Capillary Action

Adhesion and Cohesion working together
Climbs inside tubules up to 90m

Surface Tension

Water molecules bond with their neighbours beside and below them
BUT there are more bonds at the surface

Lower Density Solid

Water expands when freezing and becomes less dense
This is why ice floats
Life persists when lakes freeze over because the ice stays on top

Spring/Autumn Turnover
 The turnover and shifting of water throughout a body of water
Warm water stays on top, cold water sinks
Oxygenates the deep water and releases sulfurous gases

High Heat of Vaporization

Intenseheat and exercise may generate 1L of sweat per hour and 600 calories burned per
litre of sweat evaporated
When sweat evaporates, it pulls the heat with it, cooling us down

High Heat Capacity

Large amounts of heat are required to raise the temperature of water
This is one of many reasons why rising ocean temperatures are so dangerous and
concerning

Universal Solvent

Ionic and Polar substances dissolve in water

Properties Summary: (WILL BE ON THE TEST)

Low density solid
Universal solvent
High heat capacity
Heat of vaporization
Adhesion/cohesion
Capillarity
Surface tension

The Carbon Chemistry of Life

Carbon Chains

Carbon atoms are the backbone of biochemistry
Carbon atoms form the basis of the most complex molecules due to their ability to make 4
bonds, allowing for single, double, and triple bonds (as well as combinations of these
bonds)

Functional Groups
 Commonly found in large molecules
React in predictable ways
Include amino (NH2), carboxyl (COOH), carbonyl (CO), hydroxyl (OH), peptide (CHON),
phosphate (PO4)

Macromolecules

Carbohydrates
Lipids
Nucleic Acids
Proteins

Carbohydrates

CHO - made up of carbon, hydrogen, and oxygen
Monosaccharide - Disaccharide - Polysaccharide

Monosaccharides

CHO 1:2:1
Soluble (polar alcohols - OH)
eg. glucose (C6H12O6), fructose
Energy is readily available and easily transported

Disaccharides

Condensation (aka dehydration) reaction occurs when two monosaccharides combine,
creating a disaccharide and H2O
Hydrolysis uses H2O to break disaccharides back down into monosaccharides
Glycosidic bond
 Transportable energy in plants and animals
eg. sucrose, maltose, lactose

Polysaccharides

Enzymes that digest α linkages can’t hydrolyze β linkages
The cellulose passes through the digestive tract as “insoluble fibre”
Many herbivores, from cows to termites, have symbiotic relationships with microbes that
have enzymes to digest cellulose

Polysaccharides - structural

β-linkages have alternating orientation of monosaccharides
examples:
cellulose: long fibrous strings for structural support in plant cell walls
chitin, embedded in proteins, forms arthropod exoskeletons and is used to
make strong and flexible surgial thread

Polysaccharides - storage

α gycosidic linkages have uniform orientation of monosaccharides
glycogen - glucose
eg. organelles called leukoplasts store energy in plant roots as starch (amylose,
amylopectin)

Summary - Carbohydrates

Functions: energy transport and storage, structural support
Structure: monosaccharides - polysaccharides
eg. glucose, lactose, starch, glycose, cellulose
Functional groups: hydroxyl, carbonyls (aldehydes and ketones) (CARBONYLS ONLY
SOMETIMES)
Gycosidic bonds

Lipids

CHO(P)
No monomers and no polymerization
Nonpolar (hydrophobic)

Monoglycerides - Diglycerides - Triglycerides
 Glycerol
Fatty acid(s)
Ester bond
Essential unsaturated fatty acids are not synthesized in the human body and must be
supplied in the diet
eg. Omega-3 fatty acids
Omega-3 fatty acids have one of their carbon-carbon double bonds
at the 3rd carbon atom at the end of their carbon chain

Fat Functions

Store energy
Insulate
Cushioning
Nerve impulse transmission

Phospholipids

Form cell membranes
Amphiphilic
polar head (hydrophilic)
nonpolar tail (hydrophobic)

Other Fats

Messengers (hormones)
blood pressure
sexual characteristics
growth
Protection
waxy layer on leaves and fruit prevents invaders from entering tissue,
dehydration

Summary - Lipids

Functions - energy storage, membranes, messengers
Structure - straight chains (fatty acids) and rings
eg. testosterone, cholesterol, beeswax
Functional groups - carboxyl, hydroxyl
Ester bonds
Nucleic Acids

CHONP
DNA - deoxyribonucleic acid
RNA - ribonucleic acid

Nucleodies - monomers

Bonding

Covalent bonds
Phosphodiester bonds
H- bonds

Proteins

CHON(S)
Amino acids (monomers) - dipeptide - polypeptide

Amino Acids

R group
1-20
eg. glycine, alanine
Polar, nonpolar, electrically charged
Dipeptides

Polymerization (anabolic)
Condensation (catabolic)
Breaking apart (hydrolysis)

Protein Functions
 Enzymes - catalyze reactions
eg. lactase
Antibodies - fight invaders
eg. viruses
Hormones - chemical messengers
eg. insulin
Hemoglobin - transports O2 in RBC
Movement - actin, myosin, etc.
muscles, cilia, flagella
Support - collagen, elastin, keratin
tendons, ligaments, hair, horns, nails, feathers, quills
Nutrient Storage - albumin, amandin
amino acids for developing plant/animal embryos

Protein Organization

Primary
sequence of amino acids coded by DNA (peptide bonds)
Secondary
α helix and β sheet (H- between polar R’s)
Tertiary
3D shape is globular or fibrous (various bonds)
Quaternary
2 or more polypeptides join (becomes a functional protein)

Proteins Denature

Nonfunctional
Bonding in the tertiary structure is disturbed
Caused by:
Temperature
pH
Salt concentration

Summary - Proteins

Functions - transport, movement, messengers
Structure - 20 different amino acids - polypeptides
eg. enzymes, hemoglobin, anitbodies, hormones
Functional groups - amine, carboxyl
Bonds - peptide
EVERYTHING ABOVE THIS POINT IS ON THE UNIT ONE QUIZ

Cell Membranes

Types of Cells

can be prokaryotic
eg. bacteria cells
can be eukaryotic
eg. plant and animal cells

Eukaryotic Cells

organelles are the cell parts
the amount of each type of organelle varies by cell type
eg. muscle cells contain many mitochondria
eg. white blood cells contain many lysosomes
eg. pancreatic cells that make insulin contain a lot of rough ER

The Cell Membrane

Functions

maintain cell shape
allows some things to enter/exit (semi-/selectively permeable)
commication with other cells
show cell identity

Fluid Mosaic Model

flexible
made of many different parts
phospholipid bilayer with protein embedded throughout
molecules are attracted to each other but float freely

Phospholipids

form a bilayer spontaneously
hydrophilic heads associate with water inside and outside of the cell
nonpolar tails form hydrophobic inner layer
Carbohydrates (part 2!!!)

markers that identify the cell
glycoproteins
“person specific” so the immune system can recognize “invaders”
eg. sometimes transplants are rejected because of these markers
glycolipids
“tissue specific” so cells stop multiplying and stay put
eg. metastasized tumors ignore these markers

Cholesterol

contributes to the fluidity of the membrane
reduces membrane fluidity at moderate temperatures, but at low temperatures hinders
solidification

Globular Proteins

receptors for communication
transport substances in and out
speed up reactions
anchors cells and their parts
two types
integral
embedded in protein
peripheral
attached to surface

Fibrous Proteins

form a cytoskeleton to maintain cell shape
shape is closely tied to function

Passive Transport

small particles diffuse across a membrane from high concentration to low concentration
until an equilibrium is reached

Osmosis

the diffusion of water across a membrane
Simple Diffusion

movement of molecules from an area of [high] to [low] across a membrane
small molecules (O2, CO2)
nonpolar molecules only (steroids, amino acids)

Facilitated Diffusion

requires a specific protein channel
moves down concentration gradient
requires no energy
large, polar molecules (glucose, fatty acids, amino acids)
ions require channel proteins (K+, Cl-, Na+, H+)

Solutions

solvent - substance that dissolves the solute (eg. water)
solute - substance that dissolves in the solvent

Hypotonic

lower concentration of solute than inside the cell
in animal cells, this is dangerous - the cell may burst
in plant cells, the cell membrane pushes against the cell wall
Turgor pressure increases = turgid (firm, healthy)

Hypertonic

higher concentration of solute than inside the cell
in animal cells, the cell shrinks and becomes flaccid
in plant cells, the cell membrane tears away from the cell wall
Plasmolysis - rupture of the membrane occurs, killing the cell

Isotonic

equal concentration of solute inside and outside of the cell
EQUILIBRIUM

Active Transport
 the movement of particles from an area of low concentration to an area of high
concentration (against the concentration gradient)
uses ATP (cell energy)
eg. a toxic substance outside of the cell will actively be pumped out
eg. micronutrients need to be brought into the cell no matter how low the
concentration is

Carrier Proteins

certain membrane proteins use ATP (cell energy) to change their shape, allowing particles
to be taken in or out against natural diffusion

Endocytosis

the cell membrane folds around a substance, bringing it into the cell
this folded membrane becomes a vacuole
two types
phagocytosis
cell “eating” - taking in solids
pinocytosis
cell “drinking” - taking in liquids
receptor-mediated endocytosis
substances attach to membrane receptors
this causes the membrane to fold inward creating a coated vessicle
eg. LDL (cholesterol) uptake, glucagon, prolactin, insulin, GH, LH
these are all hormones

Exocytosis

vacuoles containing wastes, to be removed or cell products (eg. proteins) for export
the vacuole approaches the cell membrane, fuses with it, expelling the contents