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Organic Chemistry: You are What You Eat

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Title: Organic Chemistry: You are What You Eat


1
Organic Chemistry You are What You Eat
2
Organic vs. Inorganic
  • View the organic molecules and compare them to
    the inorganic molecules. What qualifies them as
    organic?
  • Inorganic
  • CO2
  • H2O
  • NH3
  • H3PO4
  • NaCl
  • AgNO3
  • HCl
  • Organic

3
Intro to Orgo
  • Organic Chem the study of C based compounds
    (must have both C H)
  • Why Carbon?
  • Its versatile!
  • 4 valence electrons (4 covalent bonds)
  • Form simple or complex compounds
  • C chains form backbone of most biological
    molecules (straight, bent, double bond, rings)

4
Skeletal Structures
CH3-CH2-CH-CH3 OH
  • In a skeletal diagram of this sort there is a
    carbon atom at each junction between bonds in a
    chain and at the end of each bond (unless there
    is something else there already - like the -OH
    group in the example)
  • there are enough hydrogen atoms attached to each
    carbon to make the total number of bonds on that
    carbon up to 4.

5
Hydrocarbons
  • Hydrocarbons consist of ONLY
  • C H
  • Importance - Store Energy (Many of these are used
    as fuels)
  • Hydrophobic

6
Functional Groups
  • These are groups of atoms added to a hydrocarbon
    that make it behave a certain way.
  • These are important because some of them will
    help you to identify some of the macromolecules
    we will be discussing. Ex Proteins contain an
    amino group and an acid group (amino acids)

7
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8
Macromolecules
  • 4 classes
  • Carbohydrates
  • Lipids
  • Proteins
  • Nucleic Acids
  • Polymers long molecule made of building blocks
    called monomers
  • Polymerization making bonds between monomers

9
Polymerization
  • Building dimers or polymers
  • Dehydration (Remove Water) Synthesis (Build)
  • Monomer-OH monomer-H ? dimer H2O
  • Breaking down dimers or polymers
  • Hydro (Water) lysis (break)
  • Dimer H2O ? monomer-OH monomer-H
  • Dehydration Synthesis and Hydrolysis

10
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11
CARBOHYDRATES
  • Why do we eat carbohydrates?

12
Carbohydrates
  • Cells get most of their energy from carbs
  • Carbs are sugars, most end in -ose
  • Multiple of molecular formula CH2O
  • Monosaccharides (simple carbs)
  • Monomers simple sugars w/ 3-7 carbons
  • Ex. (C6H12O6) Glucose, Fructose, Galactose

13
Monosaccharides
14
Carbohydrates (contd)
  • Disaccharide formed by 2 monosaccharides
  • Ex.
  • glucose glucose ? maltose H2O
  • glucose fructose ? sucrose H2O
  • glucose galactose ? lactose H2O

15
Carbohydrates (contd)
  • Polysaccharides (Complex Carbs) 100s 1,000s
    of monosaccharides
  • Storage polysaccharides
  • Starch
  • monomer-glucose (helical)
  • Produced by plants
  • Glycogen
  • Monomer glucose (branched)
  • Vertebrates temporarily store glycogen in liver
    muscle
  • Structural polysaccharides
  • Cellulose plant cell walls
  • Monomer glucose (linear)
  • Chitin
  • Arthropod exoskeletons
  • Fungi cell walls

16
  • Carbs Video

17
Homework
  • Write down what you eat for dinner tomorrow and
    investigate the carb content of each of item.
    (If you have the product label, you can use
    that). How much is simple carbs (sugars), and
    how much is complex carbs (fiber, starch)?
  • Investigate a diet like South Beach or Atkins.
    What do they suggest? Do you think that its a
    good idea?

18
Lipids
  • Hydrophobic not soluble in water
  • Store energy efficiently (2x more than carbs!)
  • Types
  • Fats oils
  • Phospholipids
  • Steroids
  • Waxes

19
LIPIDS
  • Why do we need lipids in our diet?

20
Fats Oils
  • Many lipids made up of glycerol C3H5(OH)3 and
    fatty acid chains
  • Function
  • store energy
  • Insulate
  • Protective cushion around organs

21
Saturated Fats
  • Contain no C double bonds, straight
  • Have as many Hs as possible
  • Solid at room temperature
  • Most animal fat
  • Ex. Butter, lard, adipose

22
Unsaturated Fats (Oils)
  • One or more (polyunsaturated) C double bond, bent
    or kinked
  • Liquid at room temperature
  • Most plants and fish fat
  • Ex. Olive oil, cod liver oil, corn oil

23
Phospholipids
  • Phosphate head hydrophilic
  • Fatty Acid tails - hydrophobic
  • In water, phospholipids form a bilayer
  • Phospholipid bilayer is major component of cell
    membrane

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25
Steroids
  • 4 fused carbon rings w/various functional groups
  • Ex. Cholesterol component of cell membrane,
    and many hormones

26
NUCLEIC ACIDS
  • Why do we eat nucleic acids (Yes we DO eat
    nucleic acids)
  • They are found in almost all foods, because
    nucleic acids are in all cells
  • They are broken down, and the components are used
    to make more of our own DNA and RNA

27
Nucleic Acids
  • 2 types
  • DNA (deoxyribonucleic acid)
  • Found in nucleus of eukarya
  • Double stranded helix
  • Provides directions for its own replication
  • Also directs RNA synthesis
  • Through RNA controls 10 structure of proteins
  • RNA (ribonucleic acid)
  • Single stranded, variety of shapes
  • Transfers information from nucleus to cytoplasm
    (where proteins are made)
  • DNA? RNA? Proteins

28
Structure of Nucleic Acids
  • Monomers nucleotides composed of 3 parts
  • Pentose (ribose or deoxyribose)
  • Phosphate group
  • Nitrogenous bases
  • Cytosine (C) - Guanine (G)
  • Thymine (T).DNA only - Adenine (A)
  • Uracil (U) RNA only- Adenine (A)

29
Bonding of Nucleotides
30
Another molecule of biological importanceATP
  • Adenosine Triphosphate (ATP) primary energy
    transferring molecule in the cell
  • ATP ? ADP Pi Energy

31
PROTEINS
  • Why is it important to have a good amount of
    protein in our diets?

32
Proteins
  • Various functions enzymes, structural support,
    storage, transport, cellular communication,
    movement, defense, build muscles
  • Monomer amino acid
  • Cells use 20 different a.a. to build thousands of
    different proteins
  • a.a. link to form polymers (by dehydration
    synthesis) polypeptides

33
Structure of Proteins
  • 10 Structure
  • - Sequence of a.a. (length vary)
  • - Determined by genes
  • 20 Structure
  • How polypeptide folds or coils
  • a Helix
  • ß pleats
  • 30 Structure - 3D (fold onto itself)
  • H bonds
  • Hydrophobic interaction
  • Disulfide bridges
  • 40 Structure bonds to other polypeptides
  • 2 or more polypeptide chains bonded together

34
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35
Protein Conformation
  • Structure of a protein is directly related to its
    function
  • Protein conformation is determined when it is
    synthesized, and maintained by chemical
    interactions
  • Protein conformation also depends on
    environmental factors pH, salt concentration,
    tempetc
  • Protein can be denatured unravel and lose
    conformation, therefore biologically inactive
    when conditions change again, protein can be
    renatured (restored to normal)

36
Metabolism
  • Metabolism Total of all chemical reactions that
    take place within an organism
  • Metabolic/ biochemical pathway series of
    chemical reactions, catalyzed by enzymes in which
    the product of one reaction becomes the reactant
    of the next reaction
  • Catabolic pathways break down complex molecules
    into simpler molecules (E released)
  • Anabolic pathways build complicated molecules
    from simpler molecules (E consumed)

37
Energy
  • Energy the capacity to change, to do work
    comes in many forms
  • Types
  • Kinetic Energy energy in motion
  • Potential Energy stored energy

38
Thermodynamics
  • Thermodynamics study of energy transformations
  • 1st Law of Thermodynamics Energy cannot be
    created or destroyed, only converted from one
    form to another
  • 2nd law of Thermodynamics Every energy
    transformation increases entropy
    (disorder/randomness) in the universe

39
Chemical Reactions Absorb or Release Energy
  • Exergonic reaction releases free energy, .
    products contain less energy than reactants (ex.
    cell respiration)
  • Ea Activation Energy is the E required to start
    the reaction (break bonds)
  • Catabolic Pathways

40
Chemical Reactions Absorb or Release Energy
  • Endergonic Reaction Absorbs free energy .
    products contain more energy than the reactants
    (i.e. photosynthesis)
  • Anabolic Pathways

41
Catalyst
  • Catalyst reduces the activation energy to speed
    up the chemical reaction
  • Enzyme catalytic protein
  • Specific substrate binds to active site on
    enzymecalled induced fit
  • Enzyme reduces Ea
  • Reaction occurs, products are formed
  • Enzyme can be reused

42
Enzyme-Substrate Complex
43
Effect of Enzymes on Reaction Rate
44
External Factors can Effect Enzyme Activity
  • Factors that effect enzyme shape will effect its
    function (i.e. temperature, pH) Why?
  • Different enzymes have different optimal
    conditions

45
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