Introduction to Metabolism
Metabolic PathwaysLaws of ThermodynamicsFree EnergyEnergy Coupling & ATPEnzymes
Metabolic Pathways All the chemical reactions in an
organism make up its metabolism. There are two types of metabolic
pathways: Anabolic and Catabolic
The Two Types of Pathways Anabolic: Ex. Dehydration
synthesis Photosynthesis Protein synthesis Uses energy Endergonic
reactions
Catabolic: Ex. Hydrolysis Cellular
respiration Releases energy Exergonic
reactions
Energy and Organisms Remember that energy is the
capacity to perform work. Chemical energy is just the potential
energy stored in molecules. Catabolic reactions transform
potential energy into kinetic energy. Anabolic reactions transform kinetic
energy to potential energy.
The Laws of Thermodynamics Living systems are subject to the
laws of thermodynamics just like cars and furnaces.
1st Law of Thermodynamics (Principle of Conservation of Energy)
Energy cannot be created or destroyed.
Laws of Thermodynamics (Continued) 2nd Law of Thermodynamics: Every energy transfer or transformation
increases the entropy (disorder) of the universe.
In living systems, much of the energy involved in transformations is lost as heat. (heat is energy in its most random state)
The quantity of energy in the universe is constant but the quality is not.
Changes in Living Systems Spontaneous: Occur without outside help (energy) Can be harnessed to perform work Only occur when free energy is
available Increase the entropy (disorder) of the
universe and increase the stability of the system.
Free Energy Portion of a system’s energy that
can perform work when the temperature is uniform throughout the system.
We can quantify free energy by using the symbols on the next slide.
Free Energy Equation G= free energy of a system (a
measure of its instability) T=absolute temperature in Kelvins H=total energy of the system S= entropy Relationship is expressed: G=H-TS
Free Energy Changes Expressed as delta G (triangle symbol) Systems that spontaneously change to a
more stable state must give up energy, give up order, or both.
So: Delta G= delta H-T delta S Delta G will have a negative value in
these types of changes.
Equilibrium and Free Energy Equilibrium is a state of maximum
stability. As a reaction proceeds toward
equilibrium its free energy decreases.
For a reaction at equilibrium delta G is 0.(A reaction at equilibrium performs no work)
Exergonic Reactions There is a net release of free energy in an
exergonic reaction. Delta G is negative. Magnitude of delta G is the maximum
amount of work the reaction can perform. Products store less energy than the
reactants. Example Pg.92 Cellular Respiration
Endergonic Reactions Stores free energy in molecules Delta G is positive Magnitude of delta G is the quantity
of energy required to drive the reaction.
Ex. Photosynthesis Products store more energy than the
reactants.
Metabolic Disequilibrium If cells reached equilibrium they would
have no free energy(In other words, they would be dead!)
So one of the defining features of living organisms is that they maintain metabolic disequilibrium.
They can do this because they are open systems and there is a constant flow of materials in and out of the cell.
Energy Coupling and ATP Energy coupling is using exergonic
reactions to drive endergonic reactions. ATP is the “energy coupler” for cellular
work, like: Mechanical Work-muscle contraction Transport Work- Na-K Pump Chemical Work- protein synthesis (or
pushing endergonic reactions)
Adenosine Triphosphate Structure: Nitrogenous base adenine bonded to
ribose with three phosphate groups attached
Reaction: ATP + Water yields ADP + inorganic
phosphate Under cellular conditions(pg 94) this
reaction yields about –13kcal/mol
Characteristics of ATP Bonds between phosphates are unstable
because phophates are negatively charged.
Release of energy is due to instability-in losing a phosphate it becomes more stable.
The terminal phosphate is added (phosphorylation) to another molecule which energizes it.
Most cellular work is done by ATP.
Enzymes It is important to understand that
enzymes are essential to chemical reactions in our bodies.
Normally, chemical reactions occur very slowly and would not allow life as we know it to exist.
Enzymes make everything possible by speeding up reactions as they lower activation energy.
Enzymes (continued) Enzymes are catalytic proteins-they
change the rate of reaction without being used up by the reaction.
Activation energy is the energy needed to get the reaction to proceed. Your text refers to it as the amount of energy needed to push the reactants over an energy barrier so that the downhill part of the reaction can proceed.
Enzymes (continued) Proteins have specific shapes and
enzymes are proteins. Remember that how one molecule recognizes another is related to its shape.
Therefore, sucrase only recognizes and reacts with sucrose. It will not react with maltose.
Enzymes (continued) Enzymes have an active site, a pocket or
groove on the surface of the enzyme where the substrate, or substance the enzyme acts on or changes.
Once the substrate enters the active site, it makes the enzyme slightly change its shape. The aligns molecules so that the ability of the enzyme to catalyze reactions is enhanced. This is called induced fit.
Enzyme Regulation Enzymes are regulated naturally by
temperature and pH. They function most effectively in humans within the range of human body temperature.
Enzymes in humans generally function best between pH 6-8.
An exception would be pepsin which functions best in the stomach at a pH of 2.
Enzyme Helpers Cofactors and coenzymes are substances
that aid enzymes in their catalytic activity.
Some cofactors are minerals like Zinc and Copper. (The minerals in vitamins and mineral supplements)
Coenzymes are organic molecules that help enzymes. (some vitamins are cofactors)
Enzyme Inhibitors Some substances can prevent the
action of enzymes, either totally or temporarily.
These are called inhibitors. If they bond covalently to the enzyme, the effect is permanent. If the bonds are weak then the action can be reversed.
Competitive and Noncompetitive Inhibitors. Competitive
inhibitors mimic the substrate and compete with the substrate for a place in the active site.
They can be overcome with more substrate in the environment.
Noncompetitive inhibitors do not mimic the substrate but change the shape of the enzyme by binding to it somewhere else making the active site essentially inactive.
Metabolic Control The body needs not only speed in
chemical reactions but control so tasks are done in order and efficiently.
It can regulate the activity of enzymes once they are made or turn genes on and off to make enzymes as needed.
Methods of Metabolic Control The allosteric site provides a place for
activator and inhibitor molecules to bind and (you guessed it)activate or inhibit the enzyme.
Allosterically regulated enzymes often have binding sites where polypeptide chains join.
The enzyme becomes stable in its active state if an activator binds to it and stable in its inactive state if an inhibitor binds to it.
Control of ATP by enzymes Some catabolic enzymes have allosteric
sites that bind inhibitors and activators. If there was an excess of ATP, it would bind
to these and act as an inhibitor, slowing catabolism.(catabolism regenerates ATP)
If AMP (product of broken down ATP) accumulates it binds to these sites, acting as an activator and increasing the rate of catabolism so that more ATP is regenerated.
Feedback Inhibition Feedback inhibition is how ATP is
controlled in the example on the last slide.
The end product, in that case ATP, slows down its own production so the cell is not wasting resources making substances that it already has enough of……
The next slide shows another example of this process.
Cooperativity This type of metabolic control relies on
the substrate molecule. It is similar to allosteric regulation and
induced fit. When one substrate molecule binds to an
enzyme’s active site, it “primes” the enzyme to accept more substrate molecules by making all the subunits fit the substrate.
Enzyme Complexes Groups of enzymes involved in a particular
metabolic pathway can form complexes that keep them in a particular place.
This makes metabolism more efficient because it acts like an assembly line, with the product of one enzyme becoming the substrate for the next one.
Some enzyme complexes are bound to particular organelles like those in membranes of the mitochondria that perform cellular respiration.
Prokaryotic vs. Eukaryotic Cells While prokaryotes are very
successful organisms, the complexity of eukaryotes may be partially explained by the compartmentalization of complex reactions on membranes like those present in chloroplasts and mitochondria
Prokaryotes do not have organelles or an endomembrane system like eukaryotes
The presence of organelles is presently explained by the Endosymbiosis Theory
This states that when smaller cells became part of larger cells by predation, some remained functioning in the host cell (pg.516-7)