ADP: Difference between revisions
Jump to navigation
Jump to search
No edit summary |
m I have added a link to the word energy. |
||
| (2 intermediate revisions by 2 users not shown) | |||
| Line 1: | Line 1: | ||
ADP or Adenosine-di- | ADP or Adenosine-di-Phosphate is an organic [[Molecule|molecule]] used in the [[Energy|energy]] maintaining [[Metabolism|metabolism]] in the body. ADP is convertible to [[ATP|ATP]] (Adenosine-Tri-Phosphate) which is more often known as the energy currency of the [[Cell|cell]]. When an inorganic phosphate is removed from [[ATP|ATP]], energy is released which is then used for any function which required energy. Hence it is critically important for maintaining the energy levels in the cell. | ||
ADP has two high energy phosphate bonds. Another phosphate is added to the ADP by an energy consuming process to form [[ATP|ATP]], which then acts as an energy store. Usually the energy released during respiration is used for making of these [[ATP|ATP]] molecules from the ADP. | ADP has only two high energy phosphate bonds. Another [[Phosphate|phosphate]] is added to the ADP by an energy consuming process to form [[ATP|ATP]], which then acts as an energy store. Usually, the energy released during [[Respiration|respiration]] is used for making of these [[ATP|ATP]] molecules from the ADP. | ||
Latest revision as of 20:24, 22 October 2018
ADP or Adenosine-di-Phosphate is an organic molecule used in the energy maintaining metabolism in the body. ADP is convertible to ATP (Adenosine-Tri-Phosphate) which is more often known as the energy currency of the cell. When an inorganic phosphate is removed from ATP, energy is released which is then used for any function which required energy. Hence it is critically important for maintaining the energy levels in the cell.
ADP has only two high energy phosphate bonds. Another phosphate is added to the ADP by an energy consuming process to form ATP, which then acts as an energy store. Usually, the energy released during respiration is used for making of these ATP molecules from the ADP.