Adenosine Triphosphate

Adenosine triphosphate (ATP) is considered by biologists to be the energy currency of life. It is the high-energy molecule that stores the energy we need to do just about everything we do. It is present in the cytoplasm and nucleoplasm of every cell, and essentially all the physiological mechanisms that require energy for operation obtain it directly from the stored ATP. (Guyton) As food in the cells is gradually oxidized, the released energy is used to re-form the ATP so that the cell always maintains a supply of this essential molecule. Karp quotes an estimate that more than 2 x 1026 molecules or >160kg of ATP is formed in the human body daily! ATP is remarkable for its ability to enter into many coupled reactions, both those to food to extract energy and with the reactions in other physiological processes to provide energy to them. In animal systems, the ATP can be synthesized in the process of glycolysis in which there is a net production of two ATP molecules in a cycle. This glycolysis is a major step in anaerobic respiration. For aerobic respiration the glycolysis is also a source of ATP but the more productive process in the tiny energy factories called mitochondria plays a major role in the production of ATP.

The structure of ATP has an ordered carbon compound as a backbone, but the part that is really critical is the phosphorous part - the triphosphate. Three phosphorous groups are connected by oxygens to each other, and there are also side oxygens connected to the phosphorous atoms. Under the normal conditions in the body, each of these oxygens has a negative charge, and therefore repel each other. These bunched up negative charges want to escape - to get away from each other, so there is a lot of potential energy here.

If you remove just one of these phosphate groups from the end, so that there are just two phosphate groups, the molecule is much happier. This conversion from ATP to ADP is an extremely crucial reaction for the supplying of energy for life processes. Just the cutting of one bond with the accompanying rearrangement is sufficient to liberate about 7.3 kilocalories per mole = 30.6 kJ/mol. This is about the same as the energy in a single peanut.

Living things can use ATP like a battery. The ATP can power needed reactions by losing one of its phosphorous groups to form ADP, but you can use food energy in the mitochondria to convert the ADP back to ATP so that the energy is again available to do needed work. In plants, sunlight energy can be used to convert the less active compound back to the highly energetic form. For animals, you use the energy from your high energy storage molecules to do what you need to do to keep yourself alive, and then you "recharge" them to put them back in the high energy state. The oxidation of glucose operates in a cycle called the TCA cycle or Krebs cycle in eukaryotic cells to provide energy for the conversion of ADP to ATP.

Order and disorder in biological systems.
Energy cycle in living things
Index

Second law concepts

Reference
Guyton
Ch 45

Karp
Ch 5
 
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Conversion from ATP to ADP

Adenosine triphosphate (ATP) is the energy currency of life and it provides that energy for most biological processes by being converted to ADP (adenosine diphosphate). Since the basic reaction involves a water molecule,

ATP + H2O → ADP + Pi

this reaction is commonly referred to as the hydrolysis of ATP.

The structure of ATP has an ordered carbon compound as a backbone, but the part that is really critical is the phosphorous part - the triphosphate. Three phosphorous groups are connected by oxygens to each other, and there are also side oxygens connected to the phosphorous atoms. Under the normal conditions in the body, each of these oxygens has a negative charge, and as you know, electrons want to be with protons - the negative charges repel each other. These bunched up negative charges want to escape - to get away from each other, so there is a lot of potential energy here.

If you remove just one of these phosphate groups from the end, so that there are just two phosphate groups, the molecule is much happier. If you cut this bond, the energy is sufficient to liberate about 7000 calories per mole, about the same as the energy in a single peanut.

Living things can use ATP like a battery. The ATP can power needed reactions by losing one of its phosphorous groups to form ADP, but you can use food energy in the mitochondria to convert the ADP back to ATP so that the energy is again available to do needed work. In plants, sunlight energy can be used to convert the less active compound back to the highly energetic form. For animals, you use the energy from your high energy storage molecules to do what you need to do to keep yourself alive, and then you "recharge" them to put them back in the high energy state.

Examples of free energy change ΔG from this reaction.
Order and disorder in biological systems.
Energy cycle in living things
Index

Second law concepts
 
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Free Energy from Hydrolysis of ATP

Adenosine triphosphate (ATP) is the energy currency of life and it provides that energy for most biological processes by being converted to ADP (adenosine diphosphate). Since the basic reaction involves a water molecule,

ATP + H2O → ADP + Pi

this reaction is commonly referred to as the hydrolysis of ATP. The change in Gibbs free energy in the reaction is used to assess the energy yield of such reactions, and as a general indicator of the spontaneity of reactions. Under standard conditions this change ΔG0' is

.

But inside a living cell, typical concentrations of the reactants might be [ATP]=10mM, [ADP]=1mM and [Pi]=10mM. Under those conditions the free energy change is

.

Because of the concentrations of ATP and ADP in the cell, the conditions are very favorable for the use of the hydrolysis of ATP as an energy source. In fact, many processes with positive ΔG values can take place when coupled with the hydrolysis of ATP.

Order and disorder in biological systems.
Energy cycle in living things
Index

Reference
Karp
Ch 3
 
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Magnesium in Association with ATP

The metal magnesium is found in association with many enzymes in living organisms. In particular, it associates strongly with ATP. The most important effect is attributable to the MgATP2 complex, which is a cofactor for these enzymes.

Index

Reference
Karp
Ch 3

Crichton
Ch 10
 
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