Biochemistry
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Cards (82)
- PolarA molecule is polar when it has an unequal distribution of charge. This unequal distribution creates full or partial negative and positive charges.
- HydrophilicPolar molecules are hydrophilic, attract water (water loving)
- HydrophobicNon-polar molecules are hydrophobic, repel water (water hating)
- MonomersMay also have distinct functions: Energy source, energy carrier (building blocks)
- Components of carbohydrates
- Carbon
- Hydrogen
- Oxygen (water)
- MonosaccharidesSimple sugars, the building blocks of carbohydrates
- Molecular formula of carbohydratesn x CH2O, where n = 3, 4, 5 or 6
- Functional groups of carbohydratesCarbonyl and Hydroxyl
- Properties of carbohydrates
- Hydrophilic, polar, water soluble
- Aldoses and ketosesMonosaccharides are classed as aldoses or ketoses depending on whether they contain an aldehyde or a ketone group
- Ring formation of monosaccharidesIn aqueous solution, 5 and 6 carbon sugars spontaneously form ring structures, the carbonyl (aldehyde or keto) group reacts with a hydroxyl group
- Optical isomersMonosaccharides can occur as optical isomers or enantiomers (D- or L- isomers) - mirror image forms
- Most naturally occurring sugars are D- isomers
- α- and β- forms of glucoseWhen glucose is in the ring structure, the hydroxyl attached to carbon 1 (aldehyde) has two possible positions (α- and β-), which interconvert rapidly in solution
- Complex carbohydrate formationFormed by glycosidic bond between monosaccharides. The α- or β- configuration is 'locked' when the bond is formed.
- DisaccharidesTwo monosaccharides linked by a glycosidic bond
- PolysaccharidesPolymers of glucose acting as energy stores (starch- plants (amylose and amylopectin), glycogen- animals)
- Structure of glycogen
- Glycogen has a similar chemical structure to amylopectin, but with more branches. Chains- α-1,4 glycosidic bonds, Branches- α-1.6 glycosidic bonds
- Sugars can be modifying and linked to lipids or proteins. Complex oligosaccharides (a few saccharides) can form recognition molecules on cell surfaces e.g., blood group determinants.
- LipidsMolecules in cells that are water-insoluble (hydrophobic) but soluble in organic solvents, including triacylglycerols, glycerophospholipids, steroids and cholesterol
- Fatty acidsThe monomeric building blocks of triacylglycerols and glycerophospholipids. The length and structural formula (saturated/ unsaturated) of the fatty acid carbon chain determines its physical properties (shape, melting point- longer + saturated = higher melting point)
- TriacylglycerolsFormed by ester linkages between fatty acids and glycerol. Important energy storage molecules, hydrophobic (insoluble) so stored as fat droplets within cells.
- GlycerophospholipidsAlso based on glycerol, but one fatty acid is replaced by a phosphate group. The phosphate group is also linked to a hydrophilic 'head group.' They are amphipathic (hydrophilic head and hydrophobic tails) and form the cell membrane.
- Steroids and CholesterolThe steroid template (fused alkyl rings) is the basis for steroid hormones and the sterol lipid, cholesterol.
- Functions of cholesterol
- Necessary component of animal cell membrane, rigid structure inserts between glycerophospholipids – modulates membrane fluidity at both ends of the temperature scale
- Nucleic acidsRibonucleic acid and deoxyribonucleic acid (RNA / DNA), act as information molecules for the cell
- NucleotidesBuilding blocks of RNA and DNA, consisting of a pentose sugar, nitrogenous base, and phosphate
- Pentose sugarsRibose in RNA and Deoxyribose in DNA
- Nitrogenous bases
- A, C, G, T found in DNA
- A, C, G, U found in RNA
- Formation of nucleic acidsNucleotides join together to form nucleic acids, joined by phosphodiester bonds. The base-pair sequence of DNA forms the genetic code.
- Nucleotides also have other functions: ATP, which carries chemical energy in its phosphoanhydride bonds
- Proteins
- Carry out the mechanical, structural and transport functions of the body, and play a crucial role as enzymes (biological catalysts). Different proteins display a wide variety of shapes and sizes, determined by the information in the DNA sequence of the gene.
- Protein foldingProteins fold up spontaneously from linear chains of amino acids
- Amino acidsBuilding blocks of proteins, 20 amino acids, water soluble and electrically charged at physiological pH, each differing in the properties of its side group (R group)
- Peptide bond formationIn polypeptides, amino acids are linked by peptide bonds. Side chains (R groups) are not involving in peptide bonding. Interactions of side chains determine how proteins fold
- pH is the measure of free hydrogen ions (H+) in a solution, ranging from 0-14 and determining a solution's acidity or alkalinity. The higher the H+, the lower the pH (more acidic).
- AcidA H+ ion (proton) donor
- BaseA H+ ion (proton) acceptor
- Strong acids and bases
- Strong acids completely dissociate in a solution, strong bases readily accept H+ from an acid
- Weak acids and bases
- Weak acids only dissociate partially and are a poor source of hydrogen ions, weak bases are poor H+ acceptors and only partially dissociate