Aerobic respiration. Mitochondria are responsible for converting nutrients into the energy-yielding molecule adenosine triphosphate (ATP) to fuel the cell's activities. This function, known as aerobic respiration, is the reason mitochondria are frequently referred to as the powerhouse of the cell. Aerobic respiration. Mitochondria are responsible for converting nutrients into the energy-yielding molecule adenosine triphosphate (ATP) to fuel the cell's activities. This function, known as aerobic respiration, is the reason mitochondria are frequently referred to as the powerhouse of the cell.
Aerobic respiration releases much more energy than anaerobic respiration. Aerobic respiration can result in as many as 38 molecules of ATP from one molecule of glucose, compared to a net gain of 2 molecules of ATP in anaerobic respiration.
36-38 molecules of adenosine triphosphate (ATP) are produced from one molecule of glucose during aerobic respiration. 32-34 molecules of ATP are produced from the electron transport chain. Glycolysis produces 2 molecules of ATP. The Krebs cycle produces 2 molecules of ATP.
The majority of ATP molecules are produced in the mitochondria during aerobic cellular respiration, which can produce about 36 molecules of ATP. In contrast, anaerobic respiration, which occurs in the cytoplasm, produces a net gain of only 2 ATP molecules.
Aerobic respiration typically produces about 36 ATP.
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.
Aerobic respiration releases much more energy than anaerobic respiration. Aerobic respiration can result in as many as 38 molecules of ATP from one molecule of glucose, compared to a net gain of 2 molecules of ATP in anaerobic respiration.
36-38 for aerobic respiration 2 in fermentation sooo.. yes
36-38 molecules of adenosine triphosphate (ATP) are produced from one molecule of glucose during aerobic respiration. 32-34 molecules of ATP are produced from the electron transport chain. Glycolysis produces 2 molecules of ATP. The Krebs cycle produces 2 molecules of ATP.
Cellular RespirationSource: Holt Biology by Johnson Raven* Aerobic cellular respiration. Anaerobic cellular respiration yields a net gain of 2 ATP molecules for each glucose molecule broken down. Aerobic respiration yields a variable number, but always more than ten times as many ATP molecules.
The majority of ATP molecules are produced in the mitochondria during aerobic cellular respiration, which can produce about 36 molecules of ATP. In contrast, anaerobic respiration, which occurs in the cytoplasm, produces a net gain of only 2 ATP molecules.
ATP is the energy-storage product of cellular respiration. Aerobic cellular respiration produces around 36 ATP molecules for every glucose molecule broken down. Anaerobic respiration results in a net gain of 2 ATP molecules.
Aerobic respiration typically produces about 36 ATP.
36 - 38 ATP from aerobic cellular respiration.
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.
If the cell is performing anaerobic respiration, this is called fermentation. Fermentation produces a net gain of two ATP molecules and uses two molecules of glucose (food). Aerobic respiration known as cellular respiration produces a net gain of 38 ATP molecules.
Both start with glycolysis, which is an anaerobic process that produces a net gain of 2 ATP. Glycolysis can be followed by fermentation or aerobic respiration, depending on the organism and available oxygen for aerobic respiration. If glycolysis is followed by fermentation, no more ATP will be produced, so glycolysis and fermentation produce only 2 ATP for every glucose molecule. However, if aerobic respiration occurs, around 34 to 36 more molecules of ATP can be produced from every glucose molecule. So, aerobic respiration is much more efficient at producing ATP.
Fats produce the most ATP per gram. Fats because they are highly reduced compounds. Pats and proteins can be used as fuel in the cell because they can be converted to intermediates of glycolysis or the Krebs cycle.