It usually changes the shape of a protein molecule. This is the way life works.
The energy released from ATP is used for the process of metabolism in in the cells. When ATP is released, it is converted to ADP energy.
The wavy lines are the high-energy bonds. when, broken each bond releases energy for the use of the cell By Aquila a. Bernas Deparonians
ATP is a molecule with 3 phosphorus groups. The 3rd phosphorus group has a high energy bond connecting it to the 1st 2. When energy is needed by the cell to do work this 3rd bond is broken.
I can't believe that someone answered "amino acids"......The actual answer is the bond between the second and third phosphate group.Because of the substantial amount of energy liberated when it is broken, the bond between the second and third phosphates is commonly described as a "high-energy" bond and is depicted in the figure by a wavy red line. (The bond between the first and second phosphates is also "high-energy".) (But please note that the term is not being used in the same sense as the term "bond energy". In fact, these bonds are actually weak bonds with low bond energies.)phosphate bond
because...it is very unstable, thus allowing the third phosphate bond in ATP to be easily broken to release energy for anabolic reactions and to produce ADP.
The energy molecules cells use are usually ATP (adenosine triphosphate) or GTP (guanosine triphosphate). The bond between the two last phophates of the nucleotide is a high-energy one, due to the amount of energy required to overcome the repulsion between the two negatively-charged phosphates. When this bond is hydrolyzed (ATP/GTP is broken down into ADP/GDP and inorganic phosphate), the energy is released and can be coupled to power other cellular processes.
Hydrolysis
Hydrolysis
The high energy phosphate bond. This bond is broken by the enzyme ATPase.
The wavy lines are the high-energy bonds. when, broken each bond releases energy for the use of the cell By Aquila a. Bernas Deparonians
ATP is a molecule with 3 phosphorus groups. The 3rd phosphorus group has a high energy bond connecting it to the 1st 2. When energy is needed by the cell to do work this 3rd bond is broken.
I can't believe that someone answered "amino acids"......The actual answer is the bond between the second and third phosphate group.Because of the substantial amount of energy liberated when it is broken, the bond between the second and third phosphates is commonly described as a "high-energy" bond and is depicted in the figure by a wavy red line. (The bond between the first and second phosphates is also "high-energy".) (But please note that the term is not being used in the same sense as the term "bond energy". In fact, these bonds are actually weak bonds with low bond energies.)phosphate bond
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.
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.
If the bond dissociation energy for reactants is high then activation energy required for the reaction also will be high.
ATP is formed when one of the three energy systems creates the lost high energy bond (that was lost in the production of energy in the muscle contraction) between the 2nd and 3rd inorganic phosphate molecule. when the bond is broken to create a contraction, adenosine triphosphate turns into adenosine diphosphate. and the cycle starts over again.hope that helped
Bond forming releases energy. Atoms will begin with a high potential energy, and will bond with other atoms to form compounds which have a lower potential energy, and are therefore more stable. Bond breaking takes in energy i.e. energy is required to break bonds.
Forming bonds always releases energy. Breaking bonds always requires energy.