In more artistic style, from Figure 1 in Schurr's paper, it looks like this:
If we look at the more traditional view of glycolysis to pyruvate with a deficit of NAD+ which must be made up by the mtG3Pdh enzyme we have something which looks quite like this:
The concept here is that mtG3Pdh is being used to regenerate the NAD+ which is essential for glycolysis to proceed to pyruvate. Of course, this concept becomes obsolete as soon as we adopt the lactate hypothesis. I tend to view reality as a combination of two pathways like this:
Normal function is via lactate with NAD+ and NADH in perfect balance. The generation of NAD+ from NADH by mtG3Pdh reduces the redox potential of the cytoplasm so the drive to generate lactate, while NADH is in short supply, becomes unhelpful or frankly impossible. For each NADH utilised by mtG3Pdh it is necessary to abort glycolysis at pyruvate, saving the one equivalent NADH by terminating it here rather than at lactate.
It's not that mtG3Pdh replenishes essential NAD+, it's that its consumption of NADH obliges termination of glycolysis at pyruvate. So is mtG3Pdh doing, if the traditional view is a load of bollocks?
Insulin signalling:
Under conditions of high glucose throughput, with insulin signalling, glycolysis will terminate at pyruvate in proportion to the activation of the glycerophosphate shuttle. Notice the two blue arrows signifying two actions of insulin. If we go back to Veech once more, with his isolated heart preparations, we have these two very specific actions of insulin:
One is an increase in glycogen synthesis. Flooding cardiac myocytes with insulin puts every GLUT4 possible on to the cell surface and intracellular glucose approaches that of the perfusing buffer, in this case 10mmol/l. The cells have absolutely no use for this much suddenly available glucose and the simple solution is to divert it to glycogen. The use of intensive insulin therapy in humans with T2D always improves non-oxidative glucose disposal. It goes to glycogen. They get fat too of course. I guess we could quote Veech's abstract:
"The administration of saturating doses of insulin to the glucose perfused, working rat heart acutely increased activity of the glucose transporter 4, GLUT 4, in the plasma membrane (equilibrating extracellular glucose and intracellular [glucose]), activated glycogen synthase (stimulating the rate of glycogen synthesis), and increased mitochondrial acetyl CoA production by the pyruvate
dehydrogenase multienzyme complex. Unexpectedly, insulin increased cardiac hydraulic work but decreased net glycolytic flux and O2 consumption, improving net cardiac efficiency by 28%".
The second arrow points to the mitochondria. Insulin acts to produce a covalent change in the ETC proteins which improves ATP generation per unit oxygen consumed.
In Veech's isolated rat heart preparation insulin REDUCES glycolysis, increases glycogen synthesis and increases mitochondrial ETC efficiency. It's all in the paper on the link above and in assorted related papers, many of which are free full texts and cover the basics. And not so basics.
Veech was looking at combinations of glucose, insulin and ketone bodies. Unlike myself, he is no lover of fatty acids. Ah well. So the buffer used had no fatty acids at all. Now, what do we think insulin will do to fatty acids? It has already maximised the efficiency of the ETC and shunted excess glucose to (harmless) glycogen.
Does insulin facilitate or inhibit the oxidation of fatty acids? The process is just like the diversion of glucose to glycogen:
Once upon a time, before insulin kicked in, CPT1 was used to supply fatty acids to the mitochondria for beta oxidation. Given the increased efficiency of ox phos under insulin, the fate of a significant proportion of fatty acids presenting for beta oxidation is to meet a blockade at CPT1 and to be diverted towards re esterification to triglycerides in the cytoplasm.
I wouldn't suggest that intramuscular triglycerides cause insulin resistance per se. But derivatives there-of do appear to do so and there is certainly an association between intramyocyte triglyceride accumulation and insulin resistance, particularly in non athletes.
This all well and good. Things become more interesting when we take a mtG3Pdh knockout mouse, which cannot signal through mtG3Pdh, and make it run. And run. And run. Until exhaustion, whenever that might be. Of course we also have a rather popular drug to inhibit mtG3Pdh which might mimic the knockout situation. Perhaps for the next post.
Peter
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