(Article referenced below was brought to may attention by Cristian Stremiz - thanks)
Insulin resistance blocks insulin-based transport of glucose into cells that are already overloaded with nutrients. The spilling-over of excess high energy electrons in the mitrochondrial electron transport chain onto oxygen produces superoxide. Superoxide is the trigger to block the import of still more glucose. Thus, insulin resistance is a cellular defense against sudden death by superoxide and other reactive oxygen species (ROS).
High Energy Electrons of Glucose Are Used to Make ATP
Cells are biochemical machines that turn on genes to produce enzymes to convert the high energy electrons on the carbon and hydrogen atoms of glucose into ATP energy and molecular components of the cell. The high energy electrons are systematically depleted of energy, protons are pumped to produce a proton gradient across the inner mitochondrial membrane, ATP is made using the proton gradient and the low energy electron are passed off to oxygen molecules to make water. That is a quick summary of cytoplasmic glycolysis, the tricarboxylic acid cycle (mitochondrial matrix) and the mitochondrial electron transport chain. The final step of transferring the depleted electrons to oxygen to make water is how oxygen is consumed in respiration. Note that if everything works well, the high energy electrons of glucose, which could suddenly release all of their energy directly interacting with oxygen and start a fire, just produce water. Another bad alternative would be for the high energy electrons to bind to molecular oxygen making superoxide.
Cells Adjust their Glucose Individually to Match ATP Use
If the supply of ATP from the mitochondrial electron transport chain of a cell gets low, this triggers the migration of vesicles with glucose transport proteins to the cytoplasmic membrane. Since the number of transport proteins determines the rate of import of glucose, then more transporters means an increase in glucose and more ATP. Type 2 diabetes and insulin resistance represents the others extreme, i.e. what happens when cells get too much glucose, max out their capacity to make ATP and high energy electrons build up in the electron transport chain.
High Blood Sugar Triggers Insulin Production to Import the Glucose into Cells
Superoxide Is a Reactive Oxygen Species (ROS)
Oxidation stress is the reason that plant antioxidants, vitamin C and N-acetyl-cysteine are recommended to avoid inflammation. One of the major sources of oxidation stress is the production of superoxide. Cells produce an enzymes, superoxide dismutase, to convert superoxide into hydrogen peroxide, and catalase to convert hydrogen peroxide into oxygen and water. Superoxide can also interact with nitric oxide to produce the nitric oxide radical. Unfortunately, superoxide can also produce hydroxyl radicals that can react with unsaturated lipids to produce lipid peroxides. Thus, superoxides can contribute to the production of many ROS, cause oxidation damage and trigger inflammation.
Many Different Processes that Produce Insulin Resistance all Produce Superoxide
The trigger for insulin resistance appears to be mitochondrial superoxide accumulation. A recent article used numerous mouse models of insulin resistance that mimic the typical human risk factors for insulin resistance and type 2 diabetes, e.g. excess nutrition, physical inactivity, pregnancy, polycystic ovarian syndrome, metabolic syndrome, inflammation, oxidative stress, anti-inflammatory corticosteroids, etc. and demonstrated that in each case mitochondrial superoxide accumulated. Moreover, mutant mice with lowered superoxide dismutase were more susceptible to insulin resistance and mutants producing an overabundance of superoxide dismutase were resistant to insulin resistance.
Insulin Resistance Is a Natural Defense Against Energy Excess
Superoxide sensing and insulin resistance protect cells against too much energy input and oxidative stress, but without the ability to reduce blood sugar, hyperglycemia leads to the suite of degenerative reactions that provide the symptoms of type 2 diabetes.
reference
Hoehn KL, Salmon AB, Hohnen-Behrens C, Turner N, Hoy AJ, Maghzal GJ, Stocker R, Van Remmen H, Kraegen EW, Cooney GJ, Richardson AR, James DE.Insulin resistance is a cellular antioxidant defense mechanism.Proc Natl Acad Sci U S A. 2009 Oct 20;106(42):17787-92. Epub 2009 Sep 30.
