FADS and NADS Pick up, temporarily store and safely eat out while the mitochondria energy does electronsconnect to onlit the electron transport chain.
I didn't want to change someone's answer, but according to biology-online.org,
Both are enzymes; NAD acts as an electron and hydrogen carriers in some oxidation-reduction reactions. FAD is a hydrogen acceptor molecule in the Krebs Cycle.
See below:
Nicotinamide adenine dinucleotide --> nad
(Science: enzyme) coenzymes that act as electron and hydrogen carriers in some oxidation-reduction reactions.
Fad
(Science: biochemistry) a riboflavin-containing hydrogen Acceptor molecule in the Krebs Cycle of plant respiration and a coenzyme of some oxidation-reduction enzymes.
The availability of the reactants needed for respiration (CO2, ADP, NAD+, FAD, H+, etc). The reactants are formed by photosynthesis.
Flavin Adenine Dinucleotide
NADP if photosynthesis. NAD or FAD if cellular respiration.
Acetyl-CoA: CoA=Co-enzyme A; Coenzyme I, coenzyme II, coenzyme A and B-12 and coenzyme Q.
NAD and FAD are reduced in the Krebs cycle and oxidised in the electron transport chain.
The two most important hydrogen carries are NAD and FAD.NAD and FAD are part of the Krebs cycle and they are molecules that are found in cell respiration.
Nad, nadp, fad
The nucleotide Adenosine tri-phosphate, primarily. Also involved are FAD-H and NADP-H.
Loss of electrons causes NADH to become NAD+. This cycle of oxidation reduction helps generate ATP in cell respiration.
The availability of the reactants needed for respiration (CO2, ADP, NAD+, FAD, H+, etc). The reactants are formed by photosynthesis.
NADP if photosynthesis. NAD or FAD if cellular respiration.
Flavin Adenine Dinucleotide
NAD and FAD are the two hydrogen carriers involved in respiration. NAD is reduced in glycolysis, the Link Reaction and the Krebs Cycle to NADH + H+; whilst FAD is reduced to FADH2 solely in the Krebs Cycle. The role of the hydrogen carriers is to transport the hydrogen atoms to the Electron Transport Chain, where their energy is used to join ADP and Pi to give a molecule of ATP.
Acetyl-CoA: CoA=Co-enzyme A; Coenzyme I, coenzyme II, coenzyme A and B-12 and coenzyme Q.
The process of cellular respiration has three main stages. The first is glycolysis, in which glucose is split into two molecules. ATP, pyruvic acid, and NADH are all produced during this process. The second stage is the citric acid cycle. This occurs after the two molecules of glucose (resulting after the split) are converted into a compound called acetyl CoA. Through a series of steps, NAD and FAD compounds as well as ATP molecules are produced, and the NAD and FAD are reduced. These reduced forms carry high energy electrons to the next stage. This third and final stage is known as electron transport. An electron transport chain is made up of electron carriers in the membrane of the mitochondria of eukaryotic cells. Through multiple reactions, the high energy electrons are passed to oxygen, and ATP is produced.
NAD and FAD are reduced in the Krebs cycle and oxidised in the electron transport chain.
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