Section 1

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    Nate

    Cards (68)

    • Monomers are smaller units which can create larger molecules and the polymers are made from lots of monomers which are bonded together
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    • Examples of monomers
      • Glucose
      • Amino acids
      • Nucleotides
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    • Examples of polymers
      • Starch
      • Cellulose
      • Glycogen
      • Proteins
      • DNA
      • RNA
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    • Condensation reaction to create polymers

      1. Joining two molecules together
      2. Creating a chemical bond
      3. Removing water
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    • Hydrolysis reaction to break apart polymers

      1. Breaking a chemical bond between two molecules
      2. Involves the use of water
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    • Monosaccharides
      • Glucose
      • Fructose
      • Galactose
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    • Disaccharides
      • Sucrose
      • Maltose
      • Lactose
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    • Polysaccharides
      • Starch
      • Cellulose
      • Glycogen
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    • Alpha glucose

      Hydrogen atom on top, hydroxyl group on bottom of carbon 1
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    • Beta glucose

      Hydroxyl group on top, hydrogen atom on bottom of carbon 1
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    • Glycosidic bond

      Chemical bond that forms between two monosaccharides to create a disaccharide
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    • Maltose is made from glucose + glucose, lactose is made from glucose + galactose, sucrose is made from glucose + fructose
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    • Starch
      • Stored in plants to provide chemical energy
      • Made from alpha glucose
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    • Cellulose
      • Provides structural strength in plant cell walls
      • Made from beta glucose
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    • Glycogen
      • Stored in animals to provide chemical energy
      • Made from alpha glucose
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    • Starch and glycogen have 1-4 and 1-6 glycosidic bonds, cellulose has only 1-4 glycosidic bonds</b>
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    • Amylose
      Unbranched polymer of starch
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    • Amylopectin
      Branched polymer of starch
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    • Carbohydrates are large and insoluble, so they don't affect water potential or osmosis
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    • Cellulose
      • Long straight chains held together by hydrogen bonds, providing structural strength
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    • Glycogen
      • More branched than starch, can be more readily hydrolyzed to glucose
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    • Lipids
      • Triglycerides
      • Phospholipids
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    • Condensation reaction to form triglycerides

      Three fatty acids join to glycerol, three water molecules removed
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    • Ester bond

      Bond that forms between fatty acids and glycerol in triglycerides
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    • Saturated fatty acid

      No double bonds between carbon atoms, fully saturated with hydrogen
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    • Unsaturated fatty acid

      At least one double bond between carbon atoms
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    • Triglycerides
      • High ratio of energy-storing carbon-hydrogen bonds
      • Can act as metabolic water source when oxidized
      • Do not affect water potential or osmosis
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    • Phospholipids
      • Hydrophilic head, hydrophobic tails
      • Form a bilayer in cells
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    • Amino acids
      • Central carbon
      • Hydrogen
      • R group
      • Amine group
      • Carboxyl group
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    • Condensation reaction to form dipeptide
      Two amino acids join, water removed, peptide bond forms
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    • Condensation reactions to form polypeptide
      Multiple amino acids join, multiple peptide bonds form
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    • Primary structure

      Order or sequence of amino acids in a polypeptide chain
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    • Secondary structure

      Folding or twisting of polypeptide chain, held by hydrogen bonds
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    • Tertiary structure

      Further folding of polypeptide chain, held by ionic, hydrogen and disulfide bonds
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    • Quaternary structure

      Protein made up of more than one polypeptide chain
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    • Enzymes
      • Proteins in tertiary structure
      • Catalyze reactions by lowering activation energy
      • Each enzyme is specific to one reaction due to unique active site shape
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    • Induced fit model

      Enzyme active site slightly changes shape to mold around substrate, putting strain on bonds to lower activation energy
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    • Active site
      Complementary in shape to a particular substrate
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    • Lock and key model

      Enzyme's active site is complementary in shape to the substrate
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    • Induced fit model

      1. Substrate binds
      2. Enzyme's active site slightly changes shape to mould around substrate
      3. Puts strain and tension on bonds
      4. Lowers activation energy
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