a molecule of inorganic phosphate is released, creating ADP
When the chemical bond between the second and third phosphate of an ATP molecule is broken, a high-energy phosphate bond is broken, releasing energy that is used for cellular activities. This process converts ATP (adenosine triphosphate) into ADP (adenosine diphosphate) and inorganic phosphate.
Partially false. Energy is released when phosphate group in ATP is broken apart. This is because there is high energy stored in the bonds as the attached phosphate groups both have a negative charge.
When 2nd phosphate bond is hydrolysed it releases about 7.3 kcal of free energy .Note that this energy is released in standardad laboratory condition in test tube.But inside cell it may release about 13 kcal/mol. biology by campbell@5th ed p90 and 102
False! Because the chemical bond between the adenosine and the phosphate group. When that bond is broken, energy is released, which powers cellular processes.
Phosphate groups in DNA bond to sugar molecules through a phosphodiester bond to form the backbone of the DNA strand.
When ATP is formed from ADP and free phosphate, energy is stored in the bond between the terminal phosphate and the rest of the molecule.When a cell requires energy, it breaks this bond, the terminal phosphate is freed, and a packet of energy is released for the cell to use.
When the bond is broken between the phosphate groups in ATP, energy is released.
The bond between the second and third phosphate groups in ATP must break in order for energy to be released. This releases energy by breaking the high-energy bond and forming ADP (adenosine diphosphate) and inorganic phosphate.
The potential energy in ATP is released when the terminal high-energy bond is broken through a process called hydrolysis. This process involves the addition of water to ATP, leading to the cleavage of the last phosphate group and the release of energy that can be used for cellular processes.
( a phosphate group is removed.) when the chemical bond between the second and third phosphate groups is broken, creating adenosine diphosphate, a phosphate group, and releasing energy.
When the chemical bond between the second and third phosphate of an ATP molecule is broken, a high-energy phosphate bond is broken, releasing energy that is used for cellular activities. This process converts ATP (adenosine triphosphate) into ADP (adenosine diphosphate) and inorganic phosphate.
ATP energy is stored in its 3 phosphate bonds. When the 3rd phosphate bond is broken, the energy is released. Then it only has 2 phosphate bonds.
The bond between the second and third phosphate is broken forming ADP when energy is released from ATP.
The process is called hydrolysis, where water is used to break the terminal high-energy bond in ATP, releasing energy for cellular activities. This reaction converts ATP to ADP (adenosine diphosphate) and inorganic phosphate.
ATP stands for Adenosine Tri-Phosphate. This means there are three phosphate groups stuck together on the tail of the molecule. Packing that many negatively charged groups together takes energy which is stored in the structure. When the bond between the second and third phosphates is broken, energy is released and the molecule becomes ADP or Adenosine Di-Phosphate.
The third one in the chain : A = Adenosine; Amp = Adenosine mono phosphate; Adp = Adenosine di phosphate; and Atp = Adenosine tri phosphate. Already at Adp there are lots of negatively charged oxygen atoms clustered, so to bring in another PO4-- makes it difficult to attach this last Pi and just as much energy is released when the bond is later 'broken'.
ATP is broken into ADP.Adenosine Tri Phosphate into Adenosine Di Phosphate.