Large Molecules

• Monomer (-OH) + Monomer (-H) → Polymer + H2O(l)
  • Condensation: monomers (e.g. amino acids) join to form polymers (e.g. proteins)
  • Glycosidic bond forms when two carbohydrate monomers join together
  • Hydrolysis: break down of a polymer; reverse reaction
• Polymers are also called macromolecules (e.g. starch, proteins, triglyceride)

Carbohydrates

• Organic molecules in which C, H and O bind together in the ratio Cx(H2O)y
• Serve as an energy source important for the brain and cellular respiration
• Plants produce carbohydrates by using energy from sunlight
  • 6CO2 + 6H2O + energy (from sunlight) → C6H12O6(carbohydrate) + 6O2
• Animals eat plant materials to obtain the produced carbohydrates
• They can then be used in animal metabolism to release energy
  • C6H12O6 + 6O2 → 6CO2 + 6H2O + energy

Monosaccharides

Disaccharides (two sugar residues)

Polysaccharides (many sugar residues)

Starch

• Consists of amylopectin and amylose (both are made of α-glucose)
  • Amylopectin is branched via 1,6-glycosidic bonds
  • Amylose forms a stiff helical structure via 1,4-glycosidic bonds
  • Both are compact molecules → starch can be stored in small space
• The ends are easily broken down to glucose for respiration
• Does not affect water potential as it is insoluble
• Readily hydrolysed by the enzyme amylase found in the gut and saliva
• Major carbohydrate used in plants
  • Found as granules (chloroplast)
  • Each granule contains amylopectin combined by a larger amount of amylose
• Commonly used sources are corn (maize), wheat, potato, rice

Glycogen

• Branched, storage, polymer of glucose linked via glycosidic bonds
• Found in skeletal muscle and in the liver
• Chains are linked by alpha-1,4-linkage, branches are linked by alpha-1,6-linkages
• Glycogen is broken down to glucose by glycogenolysis (glycogen phosphorylase)
• Major site of daily glucose consumption (75%) is the brain via aerobic pathways
• Most of the remainder is utilized by erythrocytes, skeletal muscle, and heart muscle
• Glucose is obtained from diets or from amino acids and lactate via gluconeogenesis
• Storage of glycogen in liver are considered to be main buffer of blood glucose levels

Cellulose

• Polysaccharide consisting of long beta-glucose chains
• Linked together by hydrogen bonds to form microfibrils
• Structural function is a important component of plant cell walls
• Its tensile strength helps plant cells in osmosis //cell does not burst in dilute solutions

Proteins

Structure

• Proteins are polymers of amino acids
  • Proteins are made up by different combinations of 20 amino acids
  • They have a general structure:
  • The difference between different amino acids is found in the R-group
  • When two amino acids join together, they release -H and -OH groups highlighted in red below
  • Peptide bond is formed between alpha-carbon and nitrogen
  • Condensation reaction
• Primary structure of a protein
  • Sequence of amino acids
  • Joined together by covalent peptide bonds
• Secondary structure
  • Hydrogen bonds between amino acids
  • Made of a combination of alpha-helices and beta-pleated sheets
  • Proportion of α-helix and β-sheet depends on sequence (primary structure)
• Tertiary structure
  • Complex globular shape
  • Folding and twisting of polypeptides (H-bond)
  • Polypeptides contain many peptide bonds
• Quaternary structure
  • Several polypeptide chains //several tertiary structures combined
  • Haemoglobin has 4 polypeptide chains
  • Collagen has 3 polypeptide chains, twisted around each other
  • Globular proteins are soluble and has folded chains
  • Fibrous proteins are insoluble and long, thin, twisted chains
• Same amino acid sequence → same shape always

Bonds Found in Proteins

• Hydrogen bonds
  • Between R-groups are easily broken, but are numerous
  • The more bonds, the stronger the structure
• Disulphide bonds
  • Between sulphur-containing amino acid cystine
  • Strong bonds found in skin and hair
• Denaturation
  • Destruction of tertiary structure, can be done by heat
  • Protein structure is lost and cannot reform → dysfunctional

Absorption and Function

• Absorption of proteins in the digestive tract
  • Proteins are taken in as food
  • They are broken down in the digestive tract into their individual amino acids
  • Amino acids are recombined in the body to form different proteins
  • Good food sources include beans, milk, cheese, fish, meat
• Several substances are composed of proteins with distinct functions
  • Keratin, collagen are main components in hair, muscles, tendons, skin
  • Enzyme amylase digests starch
  • Haemoglobin transports O2 in the blood stream
  • Insulin regulates glucose storage

Lipids

• Easily dissolved in organic solvents but not in water
• Triglycerides (fats and oils)
  • Serves as an energy reserve in plant and animal cells
  • Consists of 3 fatty acids linked by ester bonds to glycerol
  • Excess energy available from food/photosynthesis is stored as triglycerides
  • Can be broken down later to yield energy when needed
  • Fats and oils contain twice as many energy stored per unit of weight as carbohydrates
  • Triglycerides (TG) are also called triacylglycerides (TAG)
• Saturated fatty acids
  • -COOH group without double bonds in the carbohydrate chain
  • May cause blockage of arteries which can lead to strokes and heart attacks
  • High melting point / solid at room temperature (fats) / typical animal fats
• Unsaturated fatty acids
  • -COOH group with double bonds in the carbohydrate chain
  • Low melting point / liquid at room temperature (oils)
  • Found in plants
• Phospholipids
  • Formed by replacing one fatty acids in a triglyceride with a phosphate group
  • Phosphate is polar / hydrophilic / does mix with H2O
  • Fatty acid tails remain non-polar / hydrophobic / insoluble, does not mix with H2O
  • Form a ball called a micelle when placed in a polar solution (e.g. water)