It requires energy. ADP is adenosine diphosphate and ATP is adenosone triphosphate. Basically, ATP has three phosphate groups (tri-phosphate) and ADP has two (di-phosphate). When ATP releases energy, a phosphate group is detached, forming energy and ADP. Therefore, to get ATP from ADP, energy is required to add one phosphate group onto the ADP.
adp+p(i)--->atp ADP +P ---> ATP
ATP (adenosine triphosphate) contains the most energy among AMP (adenosine monophosphate), ADP (adenosine diphosphate), ATP, and Pi (inorganic phosphate). This is because ATP has three phosphate groups that are high-energy bonds, making it a primary source of cellular energy. When ATP is hydrolyzed to ADP and Pi, energy is released, which can be used by cells for various processes.
Dehydration reactions typically do not require ATP because they involve the removal of water molecules to form new bonds. However, some dehydration reactions that involve the synthesis of complex molecules may require ATP as an energy source for the process.
ATP has higher potential chemical energy compared to ADP due to the presence of an extra phosphate group in ATP. This extra phosphate group allows ATP to store and release energy more readily during cellular processes. When ATP is hydrolyzed to ADP, energy is released and can be used by the cell for various functions.
ATP, ADP, and AMP are molecules involved in cellular energy metabolism. ATP is the main energy currency in cells, providing energy for various cellular processes. ADP is formed when ATP loses a phosphate group, releasing energy in the process. AMP is formed when ADP loses another phosphate group. In summary, ATP stores energy, ADP releases energy, and AMP is a lower-energy form of ADP.
Yes.
making ATP is endergonic. This is because after ATP hydrolysis to form ADP + P, we now are at a lower energy state and for ATP to be formed again it has to be fueled by catabolic pathways, eg respiration. this energy input allows ATP to be formed and thus we see that phosphorylation of ADP requires energy input (endergonic) to form ATP. Converting ATP into ADP and P itself is EXERGONIC.
ADP has less potential energy than ATP has. In fact, there are 7.3 kc less energy in ADP than in ATP.
adp+p(i)--->atp ADP +P ---> ATP
ATP (adenosine triphosphate) contains the most energy among AMP (adenosine monophosphate), ADP (adenosine diphosphate), ATP, and Pi (inorganic phosphate). This is because ATP has three phosphate groups that are high-energy bonds, making it a primary source of cellular energy. When ATP is hydrolyzed to ADP and Pi, energy is released, which can be used by cells for various processes.
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Dehydration reactions typically do not require ATP because they involve the removal of water molecules to form new bonds. However, some dehydration reactions that involve the synthesis of complex molecules may require ATP as an energy source for the process.
-I'm 98% sure ATP synthase binds ADP and a phosphate group together to produce ATP. But I could be wrong. Its a start!ATP synthase is involved in making energy available to the cell by synthesizing large proteins and converting ADP and inorganic phosphate into high-energy ATP.
-I'm 98% sure ATP synthase binds ADP and a phosphate group together to produce ATP. But I could be wrong. Its a start!ATP synthase is involved in making energy available to the cell by synthesizing large proteins and converting ADP and inorganic phosphate into high-energy ATP.
Usually energy in the body's obtained from converting ATP into ADP. However, glycolysis, the process of converting glucose to pyruvate, releases energy that turns ADP into ATP.
ATP has higher potential chemical energy compared to ADP due to the presence of an extra phosphate group in ATP. This extra phosphate group allows ATP to store and release energy more readily during cellular processes. When ATP is hydrolyzed to ADP, energy is released and can be used by the cell for various functions.
The equation for reforming ATP from ADP and inorganic phosphate is: ADP + Pi + energy → ATP. This process is catalyzed by the enzyme ATP synthase during cellular respiration.