I don't think that is quite right.
For now, set aside NMN and NR - I think that is a red herring.
What I think is being referred to with TMG and methylation in the mitochondrion is the following series of reactions.
Consider Fig 1 in
this paper. On the right hand side of the mitochondrial compartment, you will see that oxidation of choline, where TMG > DMG is an intermediate step, leads to generation of CH2-THF from THF. Reactions with serine and glycine also feed in to this step. CH2-THF then feeds in to a series of transformations which lead to formate production.
The cytoplasmic and mitochondrial compartments are metabolically connected by transport of serine, glycine and formate across mitochondrial membranes in an almost unidirectional flow - clockwise, according to the figure. The flow is from serine, through glycine and then formate to methionine.
Thus the source of the majority of 1C units for cytoplasmic methylation reactions is mitochondrial formate. Dietary serine is an important ultimate source of this formate, but choline oxidation, and hence TMG>DMG, makes an important contribution.
This paper helps to relate this to energy production, as illustrated in Fig 1.
In other words, the generation of CH2-THF is coupled to NADH production and electron transfer that ultimately leads to ATP production, using the mechanism we are familiar with in the Kreb's cycle.
Carnitine and adoB12 are not directly linked to these reactions, but play a related role in energy generation as follows.
Carnitine is essential to carry fatty acids into the mitochondrion where they are broken down by beta oxidation. Even chain fatty acids end up as acetylCoA and are fed directly into the Kreb's cycle to produce energy.
Odd chain fatty acids end up as acetylCoA and propionylCoA. Some amino acids (methionine, valine, isoleucine and threonine), along with cholesterol side chains also end up as propionylCoA. The latter must be processed further before it can be used for energy and this is where adoB12 comes in.
First propionylCoA carboxylase converts it to methylmalonylCoA, then the enzyme MUT which uses adoB12 as cofactor converts methylmalonylCoA to succinylCoA. This molecule feeds directly into the Kreb's cycle where it is first converted to succinate.
If you look at Fig 1 in the second link you will see where succinate feeds in to the ETC, at complex II, or see the Wikipedia
entry.
In terms of the overall B12 economy of the cell, the MUT reaction is overwhelmingly favoured since most B12 in the cell ends up in the adoB12 form.
I can't make any sense of the introduction of NMN, NR and methylation to the topic and think this is a mistake.
NADH/NAD+ of course is critically important to electron transfer reactions and ATP production but NMR and NR are merely part of the salvage cycle that ensures that these nucleotides are used efficiently.
Methylation here is a terminal reaction which removes excess niacinamide and is done by the enzyme N niacinamide methyltransferase (NNMT).
This paper shows the clearance pathway and the salvage pathways - 1st and 3rd Fgis in the abstract or Fig 1 and Box 2 in the full paper.
