What Glutathione (GSH) is and
how it affects your immune health
how it affects your immune health
WHAT IS GLUTATHIONE (GSH)?
Glutathione (or GSH) is the body’s own master antioxidant discovered way back in 1889. However, it was only about 30 years ago that the scientists began to understand its functions and discovered how to raise its levels.
GSH is a small protein molecule composed of 3 amino acids: cysteine, glutamate, and glycine called GSH precursors or building blocks.
GSH is produced out of these three precursors in every cell of the human body and performs many important roles, such as:
Regulation of cell growth and division
For cells to grow and divide they go through several very complex stages. Glutathione reduces the oxides, such as hydrogen peroxide, inside the cell that would otherwise prevent cell division and growth.
DNA synthesis and repair (synthesis - reproduction/creation of a new copy)
Glutathione protects the DNA from oxidative stress during cell division which allows for DNA synthesis (division). When the DNA is mutated by a free radical stealing an electron from the DNA, glutathione repairs the mutated DNA by giving up an electron to the DNA (replacing the DNA’s missing electron).
Protein synthesis
Glutathione maintains our proteins in their proper form. Its sulfur atom reacts with unnatural sulfur-sulfur bonds in proteins, breaking them and allowing the proper pairings to form.
Amino acid transport (transport - movement into, out of, within a cell, or between cells, by means of some agent such as a transporter)
Glutathione is predominately located in the cell, whereas a major fraction of the cellular y-glutamyl transpeptidase (glutathione enzyme) is on the external surface of cell membranes. This means intracellular glutathione is translocated out of many cells – glutathione moves substances, such as amino acids, in and out of the cell.
Enzyme catalysis
Glutathione provides the mechanism by which many enzymes are changed (reduced, transformed or changed from one state to another state). Glutathione is the bridge (catalysis) in the chemical reaction between some enzymes.
Enzyme activation
The highly reactive sulfide bond in glutathione wakes up or activates enzymes so that they carry out their function or are moved from one phase to the next.
Metabolism of toxins (metabolism or biotransformation – breaking down, activating or transforming)
In the liver, the enzyme glutathione S-transferase takes the sulfur from glutathione and attaches it to toxic molecules, this makes the toxin more water soluble (it is diluted in water easily). Once a toxin is water soluble, it is transported to the body's elimination systems and is excreted from the body.
Glutathione (or GSH) is the body’s own master antioxidant discovered way back in 1889. However, it was only about 30 years ago that the scientists began to understand its functions and discovered how to raise its levels.
GSH is a small protein molecule composed of 3 amino acids: cysteine, glutamate, and glycine called GSH precursors or building blocks.
GSH is produced out of these three precursors in every cell of the human body and performs many important roles, such as:
For cells to grow and divide they go through several very complex stages. Glutathione reduces the oxides, such as hydrogen peroxide, inside the cell that would otherwise prevent cell division and growth.
Glutathione protects the DNA from oxidative stress during cell division which allows for DNA synthesis (division). When the DNA is mutated by a free radical stealing an electron from the DNA, glutathione repairs the mutated DNA by giving up an electron to the DNA (replacing the DNA’s missing electron).
Glutathione maintains our proteins in their proper form. Its sulfur atom reacts with unnatural sulfur-sulfur bonds in proteins, breaking them and allowing the proper pairings to form.
Glutathione is predominately located in the cell, whereas a major fraction of the cellular y-glutamyl transpeptidase (glutathione enzyme) is on the external surface of cell membranes. This means intracellular glutathione is translocated out of many cells – glutathione moves substances, such as amino acids, in and out of the cell.
Glutathione provides the mechanism by which many enzymes are changed (reduced, transformed or changed from one state to another state). Glutathione is the bridge (catalysis) in the chemical reaction between some enzymes.
The highly reactive sulfide bond in glutathione wakes up or activates enzymes so that they carry out their function or are moved from one phase to the next.
In the liver, the enzyme glutathione S-transferase takes the sulfur from glutathione and attaches it to toxic molecules, this makes the toxin more water soluble (it is diluted in water easily). Once a toxin is water soluble, it is transported to the body's elimination systems and is excreted from the body.
Glutathione enzymes transform carcinogens, through chemical reaction, to unreactive and non-genotoxic compounds that can be eliminated without causing damage to the cell or DNA.
Glutathione interacts with foreign chemicals (primarily, it is a scavenger of harmful xenobiotics that have been oxidized) compounds to neutralize and break them down, then eliminate them from the body.
Glutathione joins with heavy metals to neutralize them and eliminate them from the body.
In some instances, depending on the state of the xenobiotic, glutathione joins with it instead of metabolizing it.
The immune system works best if the lymphoid cells have properly balanced glutathione. The cloning of T-cells consumes large quantities of cysteine. Macrophages (type of white blood cells), which are only present in sufficient quintiles when there is sufficient glutathione, provide the cysteine for the T-cell cloning. Glutathione regulates the binding, internalization, degradation and T-cell proliferation by increasing, as much as two times, the number of binding cellular receptors. More receptors equates to more T-cells being produced simultaneously (multiple T-cell cloning). Cellular GSH also affects the growth and replication of T-cells through growth stimulating cytokines.
The role of glutathione in the humoral response is that it protects the cells taking part in the humoral response all along this complex process.
A quick synapsis of the humoral immune response: “humoral” means circulating in the bloodstream. This is an immune response (chiefly against bacterial invasion) that is mediated by B cells and involves the transformation of B cells into plasma cells that produce and secrete antibodies to a specific antigen.
The process in a nutshell: macrophages engulf and digest the invading pathogen. The digested pieces activate helper T cells which in turn activate the proliferation of B cells that are programed for the specific invading pathogen.
Glutathione detoxifies reactive oxygen radicals created by radiation which reduces the damage to the cell. Glutathione also interacts covalently and noncovalently (neutralizes the reactivity in several ways) with parts of the cell that keep the cell from triggering apoptosis (cell death).
The action of glutathione in decreasing the damage from radiation is the same as in resistance to UV radiation above.
The crucial cysteine molecule is the key to the protection afforded by glutathione. Its sulfur atom scavenges destructive molecules (peroxides and free radicals) converting them to harmless compounds, such as water.
Glutathione detoxifies reactive oxygen radicals by giving them an electron which effectively neutralizes them, or glutathione joins with the oxyradical which again neutralizes it.
Glutathione biotransforms hydrogen peroxide by turning it into harmless water.
Glutathione recycles oxidized lipoic acid, vitamin C and E by restoring them to an active state, mostly by donating the electrons that they used in metabolizing (neutralizing) free radicals. So, instead of having this army of antioxidants flushed out, they are recycled by glutathione and sent back out to work.
Glutathione is a tripeptide made up of amino acids CYSTEINE, glycine and glutamate. Glutathione provides and determines the amount and availability of neuronal cysteine.
The methionine cycle and the transsulfuration sequence compose the mechanisms for homocysteine metabolism. Transsulfuration sequence requires large quantities of cysteine. It is suspected that the rapid turnover of glutathione in the liver, kidneys, small intestine and pancreas accounts for the metabolism of homocysteine in these organs. Homocysteine metabolism also involves multiple enzymes. Excessive homocysteine is a known contributing factor of hardening of arteries (atherosclerosis).
WHY IS GLUTATHIONE IMPORTANT?
The immune system and detoxification system cannot function without GSH. In his book "Glutathione. Your body's most powerful protector" Dr. Jimmy Gutman says "Glutathione modulation is an essential part of staying young, active and healthy." He also states - "By keeping our intracellular GSH levels up we also keep our immune system on the ball and fully armed".
In the immune system the protective activity of GSH is two-fold – it enhances the activity of immune cells and also functions as an antioxidant within them.
GSH has been clinically researched and proven to optimize your immune system, maximize the function of antioxidants, support your detoxification process at the cellular level, increase your energy levels and increase your strength and endurance.
As of April 2012, Pubmed.gov (the government's depository for research articles in medical and biomedical fields) lists 100,775 medical articles mentioning GSH. This is a tremendous amount of research and energy that the medical profession has put into understanding the role of GSH in our lives. Optimizing your GSH levels benefits everyone, from children to those in their golden years, from the infirm to the elite athlete.
Do not underappreciate the profound meaning of this statement - raising your GSH level is CLINICALLY PROVEN TO BE BENEFICIAL for a very wide array of health concerns.
The research continues at an amazing pace. If you want to know what research has been done for your particular condition go to PubMed and simply type in your condition. It will list the abstracts of related articles. If you want to know what influence GSH plays in your condition, type in "glutathione and your condition", then hit Search. I was amazed at what has been researched and is not common knowledge.
WHAT DOES GLUTATHIONE DO IN OUR BODIES?
Antioxidant - GSH is the body’s master Antioxidant, our bodies depend on GSH for the removal of toxins and GSH is at the heart of all immune functions. Other antioxidants in our body depend on GSH to function properly.
Detoxification - GSH detoxifies a large number of pollutants by binding to carcinogens, heavy metals, herbicides, pesticides and radiation by forming a soluble compound with the toxin that can then be excreted through the urine or bile.
Immune system - Healthy growth and activity of immune cells depends on the availability of GSH. The protective activity of GSH is two-fold – it enhances the activity of immune cells and also functions as an antioxidant within them.
Increased Energy - Our energy levels are a result of many factors - everything from the biochemical reactions taking place within our cells, to muscle function and even your sense of well-being. GSH enables the mitochondria of a cell to remain fully charged, enhancing muscle strength and endurance. Clinical trials have shown that lowering GSH in the mitochondria results in cell death.
Repair - Our body is constantly under attack from free radicals, some from external sources and some generated in our own body. Free radicals attack the nearest stable molecule, "stealing" its electron. A molecule that loses an electron then becomes a free radical itself and attacks the next nearest stable molecule, this begins a chain reaction. Once the reaction is started it can cascade through hundreds of molecules. As this occurs over and over again the cell eventually dies or mutates. GSH performs a vital role in repairing the damaged DNA by replacing the missing electron. Normal to elevated GSH keeps the repair of our cells at a maximum and reduces the number of cell mutations that would occur otherwise.
Glutathione exists in reduced (GSH) and oxidized (GSSG) states. In healthy cells and tissue, more than 90% of the total Glutathione is in the reduced form (GSH) and less than 10% exists in the oxidized form (GSSG). An increased GSSG-to-GSH ratio is considered indicative of oxidative stress. The ratio of reduced Glutathione to oxidized Glutathione within cells is often used scientifically as a measure of cellular toxicity.
in immune health:
To know more: http://www.immunehealthscience.com/glutathione.html