ATP
Oxidation in chemistry is when an electron is stripped from an atom or molecule. In this case, an electron is stripped from the phosphate group in ATP so it can be used for energy, hence oxidative phosphorylation. The electron then moves through several processes that generate energy the cell can use. That's why it is most commonly referred to as the electron transport chain.
At the stage of Redox in the Electron transport chain: All of the below are produced 2 ATP from substrate-level phosphorylation 6 NADH yields 18 ATP (assuming 3 ATP per NADH) by oxidative phosphorylation 2 FADH2 yields 4 ATP (assuming 2 ATP per FADH2) by oxidative phosphorylation As you can see from above, NADH is the molecule that conserves most energy.
NADH. In oxidative phosphorylation, for every NADH, around 2.5 ATP molecules are made, and for every FADH2 about 1.5 ATP molecules are made.
yes
The addition of a phosphate group to an organic molecule. Phosphorylation is important for many processes in living cells. ATP is formed during cell respiration from ADP by phosphorylation, as in the mitochondria of eukaryotic cells (oxidative phosphorylation) and the chloroplasts of plant cells (photosynthetic phosphorylation). Phosphorylation also regulates the activity of proteins, such as enzymes, which are often activated by the addition of a phosphate group and deactivated by its removal (called dephosphorylation).simplified for dummies like me : The addition of a phosphate group to a molecule.edited and simplified by Holy122 :P
Total (gross ) ATP production by oxidative process is 36 .
Oxidative phosphorylation is involved as a pathway with ATP.Although the many forms of life on earth use a range of different nutrients, almost all carry out oxidative phosphorylation to produce ATP, the molecule that supplies energy to metabolism. This pathway is probably so pervasive because it is a highly efficient way of releasing energy, compared to alternative fermentation processes such as anaerobic glycolysis.
About 36 to 38 ATP molecules produced by oxidative phosphorylation.
One molecule of Glucose in Oxidative Phosphorylation.
phosphorylation
Oxidation in chemistry is when an electron is stripped from an atom or molecule. In this case, an electron is stripped from the phosphate group in ATP so it can be used for energy, hence oxidative phosphorylation. The electron then moves through several processes that generate energy the cell can use. That's why it is most commonly referred to as the electron transport chain.
the glucose is break down in the cell by 1)glycolysis 2)preparation of pyruvic acid 3) kreb's cycle or citric acid cycle or CAC or tricarboxylic acid cycle 4)oxidative phosphorylation and after that ATP is produced which is the energy currency of our body
After glycolysis you will go through bridging reaction to the Krebs cycle, also known as the citric acid cycle because of the use of citric acid. the reducing power generated indirectly helps to power oxidative phosphorylation that occurs, which yields a total of 34 ATP's from one glucose molecule. Good luck
At the stage of Redox in the Electron transport chain: All of the below are produced 2 ATP from substrate-level phosphorylation 6 NADH yields 18 ATP (assuming 3 ATP per NADH) by oxidative phosphorylation 2 FADH2 yields 4 ATP (assuming 2 ATP per FADH2) by oxidative phosphorylation As you can see from above, NADH is the molecule that conserves most energy.
I wouldn't say that. The main purpose of respiration, that in biochemistry is known as "oxidative phosphorylation" is to produce ATP molecules. A complete chain of an oxidative phosphorylation pathway goes from a molecule of glucose that is degraded into smaller molecules, passing through tricarboxylic acid cycle and a redox loop mechanism (in mitochondria) to produce molecules of water and CO2.
Phosphorylation
yes