Lecture 3 Free Energy of Hydrolysis - BIOC*4520 PDF

Summary

This PDF document is a lecture on free energy of hydrolysis, part of a larger course on metabolic processes. It discusses the Gibbs equation, and how organisms perform energy transductions. It introduces concepts of cellular organization, with different energy and carbon sources.

Full Transcript

BIOC*4520:
Metabolic Processes
Energy, metabolic processes
and thermodynamics

Gibbs equation
ΔG = ΔH - TΔS.
Organisms Perform Energy Transductions
to Accomplish Work to Stay Alive
 Six Kingdoms of Life Defined by
Organism, Cellular, and Molecular Differences

Six kingdoms Cellular organization
Archaea Unicellular prokaryote
Bacteria Unicellular prokaryote
Protista Unicellular eukaryote
Fungi Uni- or Multicellular eukaryote
Plantae Multicellular eukaryote
Animalia Multicellular eukaryote
Organisms Can Also Be Classified by
Different Energy and Carbon Sources
Metabolism Is the Sum of All Chemical
Reactions in the Cell
Life on earth - constant temperature and pressure (1
atm.), so we can confine our bioenergetics analysis to
consideration of Gibbs free energy ΔGo.
A reaction is favorable if the change in Gibbs free
energy (ΔGo) is negative, i.e. if the free energy of the
products is less than the free energy of reactants.
A favorable, spontaneous reaction
A+B ⇄ C+D
occurs if:
GC + GD < GA + GB
 Equilibrium and ΔG°
Measure Spontaneity of a Reaction

In biological
systems R = gas cst. =
ΔG’o or ΔGo’ used 0.00831
for ΔGo kJoule/mole/K
Under standard conditions,
e.g. start with 1 M of A & B
Free Energy, or the Equilibrium Constant,
Determines the Spontaneity of Processes

TABLE 13-3 Relationships among K'eq, G˚, and the Direction of
Chemical Reactions
Starting with all components at
When K'eq is... G˚ is... 1 M, the reaction...
>1.0 negative proceeds forward
1.0 zero is at equilibrium