1. CHEM 2713
Biochemistry I
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2. Free energy changes
Enthalpy & entropy determine spontaneity of a reaction at a given temperature
Enthalpy (ΔH) – relative strengths of the bonds broken in reactants(s) vs. bonds formed in product(s)
Entropy (ΔS) – relative degree of disorder in reactant(s) vs. product(s)
Spontaneity favors strong bonds and high disorder in the product(s)
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3. Spontaneity does not mean certainty
Spontaneity does not relate whether the reaction is kinetically feasible!
ΔGo = -693 cal (2900 J)
Will your diamond turn to graphite?
Thermodynamics say yes, but kinetics say no!
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4. Spontaneity does not mean certainty
Conversion of diamond to graphite has a high activation barrier
ΔG = -693o cal (2900 J)
Diamond (sp3 bonds)
Graphite (sp2 bonds)
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5. Enzymes serve as biological catalysts
A catalyst lowers the activation barrier for a reaction, allowing a kinetically unfavorable reaction to proceed
Enzymes serve as biological catalysts
Biological reactions have activation barriers; this adds another element of control in biological systems
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6. ATP hydrolysis is highly exergonic
This property allows ATP to be used a storage form of energy
Phosphoanhydride bond is thermodynamically
unstable but kinetically stable.
Kinetic stability is essential for the role of ATP as an energy storage molecule
Otherwise, ATP would have a fleeting existence and would not be available when energy is required
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7. Central role of ATP in metabolism
ATP is the chemical intermediate that links energy-releasing to energy-requiring cellular processes
Its role in the cell is analogous to that of money in an economy
ATP is earned/produced in exergonic reactions and spent/consumed in endergonic ones
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8. Equations to review ΔGo = ΔHo – TΔSo ΔG = ΔGo + RT ln Q
ΔGo = -RT ln Keq
ln Keq = - ΔHo/R(1/T) + ΔSo/R
ΔGo’ = free energy change under biochemical standard conditions
Activity of pure water is 1, [H2O] = 1
pH is 7
Standard state refers to naturally occurring mixture (where the substance can undergo acid-base reactions)
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9. Chapter 2: Water
Most abundant substance in living systems (70% or more of the weight of most organisms)
All aspects of cell structure and function are adapted to the physical and chemical properties of water
Attractive forces between H2O molecules and the slight tendency of H2O to ionize are of crucial importance to the structure and function of biomolecules
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10. Water exhibits very strong intermolecular dipole- dipole forces: hydrogen bonding (H-bonding)
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11. Structure of a single water molecule
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12. Water is polar
Summation of individual dipoles determine overall polarity
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13. Water is polar
H2O molecules exhibit cohesive forces known as hydrogen bonds
H-bonding is a special kind of dipole-dipole interaction
H-bonding is possible when H is attached to O, N, or F
Individual H-bonds are weaker than covalent and ionic bonds, but collectively strong
H-bonding gives water its relatively high melting and boiling points (and high heats of fusion and vaporization)
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14. Hydrogen bonding in ice
In ice, each H2O molecule forms the maximum of four H-bonds, creating a crystalline solid
In liquid H2O at room temp. and atmospheric pressure, each H2O molecule H-bonds with an average of 3.4 other H2O molecules
Crystalline lattice of ice results in a structure that is less dense than liquid H2O, thus ice floats on H2O
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15. Putting H-bonds in perspective
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16. Van der Waals forces H-bonding is a special type of (a) 12/26/2018
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17. Water forms H-bonds with polar solutes
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18. Common H-bonds in biological systems
H-bonds are not unique to water
Note that H atoms covalently bound to C do not make H-bonds
C is only slightly more electronegative than H; the C-H bond is only weakly polar
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19. Some biologically important H-bonds
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20. Hydrogen bonds
Strongest when two electronegative atoms are oriented 180o
H-bonds are highly directional
Capable of holding two H-bonded molecules or groups in a specific geometric arrangement
Confers very precise 3-D structures on protein and nucleic acid molecules, which have many intramolecular H-bonds
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21. Water interacts with charged solutes
Disrupts electrostatic solute-solute interactions
Water has a high dielectric constant, a physical property reflecting the number of dipoles in a solvent: ε (H2O) is 78.5; ε (PhH) is 4.6
Ionic interactions are much weaker in more polar environments (solute-solvent interactions strong)
When crystalline NaCl dissolves in H2O, entropy increases
ΔG = ΔH – TΔS: ΔH has a small positive value and TΔS has a large positive value
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22. Nonpolar gases are poorly soluble in water
CO2, O2, and N2 are nonpolar
Dissolution of such gases in not favored by enthalpy or entropy
Poor solubility in water requires other methods of transport
O2 carried by hemoglobin
CO2 carried as HCO3-
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23. Transfer is entropically driven
Entropy (ΔS) increases when hydrocarbons move from water to a nonpolar solvent
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24. Orientation of water around a nonpolar solute
Increased ordering of water reduces entropy of system
Fewer ways for water to form H-bonds (orient) around a nonpolar molecule relative to the number of ways H-bonds can form in bulk water
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25. Aggregation of nonpolar molecules in water
Nonpolar substance is excluded from the aqueous phase
Hydrophobic effect: water’s tendency to minimize its contacts with hydrophobic molecules
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26. Amphipathic compounds in aqueous solution
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31. Model of a micelle Twenty molecules of the detergent octyl glucoside
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34. In summary Individually weak, collectively strong 12/26/2018
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35. Pure water is slightly ionized
Hydration of dissociating protons virtually instantaneous
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36. Pure water has high ionic mobility
Movement of hydronium and hydroxide ions in an electric field is anomalously fast
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37. Draw a molecule with an alcohol (acidic form), a phosphoryl group (basic form), and an ester. Show two of these molecules interacting via a hydrogen bond.
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