Reaction for G-3-P oxidizing to 1,3-BPG

In summary, when the hydride ion leaves G-3-P it donates two electrons and one proton, which neutralizes the charge on NAD+ and gives NADH.
  • #1
teddy1975
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okay, so here's another question: the reaction for G-3-P oxidizing to 1,3-BPG is:
G-3-P + NAD+ + Pi --> 1,3-BPG + NADH + H+.

I understand that the hydride ion leaves G-3-P and donates two electrons and one proton, which neutralizes the charge on NAD+ and gives NADH. But it is only giving one 'hydrogen', while the product side of the reaction shows another one (the hydrogen proton). Where does this hydronium ion come from? Why is it in the reaction? I read somewhere that it is pulled out of 'solution', but what does that mean?
 
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  • #2
I am no biologist but I think it is Cytochromes in the mitochondrial inner membrane.
 
  • #3
Your question would be the same for any NAD+/NADH or NADP+/NADPH oxidoreductase. (Glcyeraldehyde-3-phosphate dehydrogenase is a bit more complicated than others because you also have a phosphorylation, but your problem is not about that.)

Just think first of a neutral substrate being oxidised to a neutral product, like alcohol -> aldehyde. [tex]H^-[/tex] is transferred to NAD+ giving you the neutral ring NADH as you have explained. What would that leave the alcohol? A positively charged molecule with unpaired electron that can't exist. Write down the structure and you will find yourself predicting that and electron pair folds into make a double bond C=O leaving a free proton so you have accounted for your proton production. In our case, oxidation of an aldehyde, the impossible positively charged subtrate molecule after the H- has left takes on an OH-, so finishes up neutral acid molecule RCOOH. Absorbtion of an OH- is equivalent to production of a H+. Alternatively you can think of the substrate abstracting an OH- from an H2O molecule leaving an H+.

(Then just as a complication the acid molecule which is formally RCOOH, at physiological pH's will be practically totally dissociated into RCOO- + H+.)

Note here we are not too concerned with exactly how it happens, the real steps or 'mechanism', just with the overall results or starting and end products, the 'stoichiometry'. The reaction is equivalent to transfer of H2 to NAD+, or reduction of the NAD, by an H2 molecule; H2 is equivalent to H- + H+.
 
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  • #4
Sorry, just delete the "with unpaired electron" above.
Try and predict with 'bow and arrow' chemistry what happens when the H- leaves.
 

FAQ: Reaction for G-3-P oxidizing to 1,3-BPG

1. What is the overall chemical equation for the reaction of G-3-P oxidizing to 1,3-BPG?

The overall chemical equation for this reaction is: G-3-P + NAD+ + Pi → 1,3-BPG + NADH + H+

2. What is the role of NAD+ in this reaction?

NAD+ acts as an electron acceptor, which is reduced to NADH during the reaction. This reduction of NAD+ allows for the oxidation of G-3-P to 1,3-BPG.

3. How does this reaction contribute to cellular respiration?

This reaction is part of the glycolysis pathway, which is the first stage of cellular respiration. It converts glucose into smaller molecules, such as G-3-P and 1,3-BPG, that can be further broken down to release energy for the cell.

4. What is the significance of 1,3-BPG in this reaction?

1,3-BPG is an important intermediate molecule in the glycolysis pathway. It is used to produce ATP, the main energy currency of the cell, through a series of enzymatic reactions.

5. How does the oxidation of G-3-P to 1,3-BPG help maintain redox balance in the cell?

The oxidation of G-3-P to 1,3-BPG helps maintain redox balance in the cell by balancing the ratio of NAD+ to NADH. This is important because NAD+ is required for many metabolic reactions, and a high concentration of NADH can inhibit these reactions. By producing an equal amount of NADH, the cell can maintain a proper balance of these molecules.

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