Small units which are the components of larger molecules
Polymers
Molecules made from many monomers joined together
Monomer joining
1. Condensation reaction
2. Water molecule eliminated
Polymer breaking down
1. Hydrolysis
2. Water added to break chemical bond
Carbohydrates
Molecules consisting only of carbon, hydrogen and oxygen, long chains of sugar units called saccharides
Monosaccharide
Single sugar unit
Disaccharide
Two monosaccharides joined together
Polysaccharide
Many monosaccharides joined together
Glycosidic bond
Bond formed between monosaccharides in a condensation reaction
Glucose
Six carbon atoms in each molecule
Main substrate for respiration
Has alpha and beta isomers
Common monosaccharides
Glucose
Galactose
Fructose
Disaccharide formation
1. Condensation reaction of two monosaccharides
2. Water molecule produced
Polysaccharides
Formed from many glucose units joined together
Polysaccharides
Glycogen
Starch
Cellulose
Glycogen
Main energy storage molecule in animals
Formed from alpha glucose
Has many side branches
Compact molecule to maximise energy storage
Insoluble so doesn't affect water potential
Starch
Energy storage in plants
Mixture of amylose (unbranched) and amylopectin (branched)
Compact to store a lot of energy
Insoluble so doesn't affect water potential
Easily hydrolysed to release glucose
Cellulose
Component of plant cell walls
Made of long, unbranched chains of beta glucose
Microfibrils form strong threads
Provides structural support and prevents cell bursting
Benedict's test for reducing sugars
1. Add sample to Benedict's reagent
2. Heat in water bath
3. Red precipitate indicates reducing sugar
Benedict's test for non-reducing sugars
1. Add sample to Benedict's reagent, no colour change
2. Hydrolyse with dilute HCl
3. Neutralise with NaHCO3
4. Retest with Benedict's reagent, colour change indicates non-reducing sugar
Iodine test for starch
Solution turns blue/black if starch is present
Lipids
Biological molecules made of carbon, hydrogen and oxygen, only soluble in organic solvents
Triglycerides
Lipids made of one glycerol and three fatty acids joined by ester bonds
Saturated lipids
No carbon-carbon double bonds
Unsaturated lipids
Contain carbon-carbon double bonds, can bend and are liquid at room temperature
Triglyceride properties
High energy density
Low mass to energy ratio
Insoluble in water so don't affect water potential
Release water when oxidised
Phospholipids
One fatty acid replaced by phosphate-containing group, form bilayers in water
Phospholipid properties
Polar structure allows bilayer formation
Hydrophilic heads at cell surface
Can form glycolipids for cell recognition
Emulsion test for lipids
1. Add sample to ethanol, then water
2. Cloudy-white colour indicates presence of lipid
Amino acids
Monomers that make up proteins, contain amino, carboxyl and variable R groups
Peptide bond
Bond formed between amino acids in a condensation reaction, releases water
Dipeptide
Two amino acids joined
Polypeptide
Three or more amino acids joined
Protein structure
Primary - order and number of amino acids
Secondary - alpha helix or beta pleated sheet
Tertiary - 3D shape, maintained by disulfide bridges and ionic bonds
Primary structure of a protein
The order and number of amino acids in a protein. This primary structure contains the initial sequence of amino acids and will therefore determine the proteins function in the end.
Secondary structure of a protein
The shape that the chain of amino acids makes – either alpha helix or beta pleated sheet. The hydrogen in the -NH has a slight positive charge whilst the oxygen in the -C=O has a slight negative charge. As a result weak hydrogen bonds can form leading to alpha helices or beta pleated sheets.
Tertiary structure of proteins
The 3D shape of the protein and is formed from further twisting and folding. A number of different bonds maintain the structure, these are: Disulfide bridges, Ionic bonds, Hydrogen bonds.
Proteins
Can be globular or fibrous. Globular proteins such as enzymes are compact whereas fibrous proteins such as keratin are long and thus can be used to form fibres.
Biuret Test
1. Place the sample to be tested in a test tube and add an equal volume of sodium hydroxide at room temperature
2. Add a few drops of very dilute (0.05%) copper (II) sulfate soliton and mix gently
3. A purple colouration indicates the presence of a peptide bond and hence a protein. A negative result would mean the solution remains blue.
Enzymes
Increase rate of reaction by lowering the activation energy of the reaction they catalyse. They are 3D tertiary structured globular proteins whose shape is determined by the primary sequence of amino acids.
Active site
An area of the enzyme that is made up of only a few amino acids and forms a small depression in the overall enzyme. The molecule that the enzyme acts upon is called the substrate.