biological molecules

Created by

Aaishah Takolia

Cards (64)

Monomers are smaller units which can create larger molecules and the polymers are made from lots of monomers which are bonded together
Examples of monomers and polymers
Glucose (monomer)
Amino acids (monomers)
Nucleotides (monomers)
Starch (polymer)
Cellulose (polymer)
Glycogen (polymer)
Proteins (polymer)
DNA/RNA (polymer)
Condensation reaction to create polymers 
1. Joining two molecules together
2. Creating a chemical bond
3. Removing water
Hydrolysis reaction to break apart polymers
1. Breaking a chemical bond between two molecules
2. Involves the use of water
Monosaccharide 
One sugar unit
Disaccharide 
Two sugar units joined together
Polysaccharide 
Many sugar units joined together
Monosaccharides 
Glucose
Fructose
Galactose
Disaccharides 
Sucrose
Maltose
Lactose
Polysaccharides 
Starch
Cellulose
Glycogen
Alpha glucose 
Hydrogen atom on top, hydroxyl group on bottom of carbon 1
Beta glucose 
Hydroxyl group on top, hydrogen atom on bottom of carbon 1
Glycosidic bond 
Chemical bond that forms between two monosaccharides to create a disaccharide
Maltose is made from glucose + glucose, lactose is made from glucose + galactose, sucrose is made from glucose + fructose
Starch 
Stored in plants, provides chemical energy
Cellulose 
Structural strength in plant cell walls
Glycogen
Stored in animals, mainly in liver and muscle cells
Starch and glycogen are made from alpha glucose, cellulose is made from beta glucose
Starch has 1-4 and 1-6 glycosidic bonds, cellulose has only 1-4 bonds, glycogen has both 1-4 and 1-6 bonds
Amylose 
Unbranched starch polymer
Amylopectin 
Branched starch polymer
Carbohydrates are large and insoluble, so they don't affect water potential or osmosis
Cellulose structure 
Long straight chains that line up in parallel and are held together by hydrogen bonds, providing structural strength
Glycogen
More branched than starch, can be more readily hydrolyzed back into glucose
Triglycerides 
Lipid with 3 fatty acid chains attached to a glycerol molecule
Phospholipids
Lipid with 2 fatty acid chains and a phosphate group attached to a glycerol molecule
Triglyceride formation 
3 condensation reactions, 3 ester bonds formed, 3 water molecules removed
Saturated fatty acids 
No double bonds between carbon atoms, fully saturated with hydrogen
Unsaturated fatty acids 
At least one double bond between carbon atoms
Triglycerides 
High ratio of energy-storing carbon-hydrogen bonds, can act as metabolic water source, do not affect water potential
Phospholipids 
Hydrophilic head, hydrophobic tails, can form bilayer in water
Amino acid 
Monomer that makes up proteins, has central carbon, hydrogen, amine group, carboxyl group, and variable R group
Dipeptide formation 
Condensation reaction, peptide bond formed, water removed
Polypeptide formation 
Multiple amino acids joined by peptide bonds
Primary structure
Order or sequence of amino acids in a polypeptide chain
Secondary structure
Folding or twisting of the polypeptide chain, held by hydrogen bonds
Tertiary structure 
Further folding of the polypeptide chain, held by ionic, hydrogen, and disulfide bonds
Quaternary structure 
Protein made up of more than one polypeptide chain
Enzymes 
Proteins in tertiary structure that catalyze reactions by lowering activation energy
Each enzyme is specific to one reaction due to the unique shape of the active site
Induced fit model 
Enzyme active site slightly changes shape to mold around the substrate, putting strain on bonds to lower activation energy