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Electrons. ( plus that proton )
NADH is generated by the electrons transferred to the NAD+. It is used in oxidative phosphorylation of for ATP synthesis later on.
NADH+ provides electrons for the é transport chain.
As they both accept electrons and are reduced, but NAD carries stripped electrons from glucose ( becoming NADH ) to the electron transfer chain while oxygen is the final electron acceptor.
NAD plus
NAD+ accept electrons.
Electrons. ( plus that proton )
NAD+ is reduced. It becomes NADH.
NADH
to accept high energy electrons
like NADP+ in photosynythesis, each NAD+ accepts a pair of high-energy electrons. This molecule, known as NADH, holds the electrons until they can be transferred to other molecules. By doing this, NAD+ helps to pass energy from glucose to other pathways in the cell.
NAD+ is an electron carrier molecule that helps pass energy from glucose to other pathways in a cell by taking high-energy electrons and holding on to them until they can be transferred to other molecules.
the free energy liberated when electrons are removed from the organic molecules must be greater than the energy required to give the electrons to NAD+
They form FADH2 and NADH
NADH is generated by the electrons transferred to the NAD+. It is used in oxidative phosphorylation of for ATP synthesis later on.
They build up.
NADH+ provides electrons for the é transport chain.