Health Diagrams II — Curing Autoimmunity and Allergies

---All 200 posts here---

In this second in a series of posts explaining the concepts that I think are central, but misunderstood, about health, I am focusing on how diet and gut flora impact the immune system and cause autoimmunity and allergies.  This cause also suggests a simple cure.

Health in Diagrams I -- Gut Flora and Diet
Health in Diagrams III -- Inflammation from Cell to Tissue

Gut Flora to Tregs to Suppression of Autoimmunity

It is important to understand at the outset that autoimmunity and allergies are caused by a damaged immune system, and repairing the damage cures the diseases.  Damage to the immune system typically represents a break in the continual development of immune cells in the lining of the intestines.  Immune cell development in the gut is dependent on bacteria, the gut flora.  Damage to the gut flora, e.g. by antibiotics, processed foods that lack flora feeding fiber or extreme diets, disrupts development of immune cells.  Typically, loss of the immune cells that keep the aggressiveness of the immune system in check, regulatory T cells or Tregs, results in autoimmunity.  Fix the gut flora and autoimmunity recedes.  

Health Requires Suppression of the Aggressive Immune System

For simplicity, I am focusing on the T cells of the immune system that develop in the intestines and either kill other human cells that are dangerous, e.g. virus-infected or cancer cells, or provide protection by regulating the aggression, Tregs.  Normal functioning of the immune cells permits elimination of damaged or dangerous human cells, while at the same time avoiding rampages of lethally armed T killers.  Examples of untamed T killers in action are degenerative autoimmune diseases, such as arthritis, asthma, prostatitis, celiac, Hashimoto’s thyroiditis, type I diabetes, inflammatory bowel diseases and atherosclerosis. 

Milk Births Baby Immune System

It should not be surprising that the focus of immune system development is the gut.  We start as babies with explicit links between nourishment and immunological protection.  Milk connects the immune systems of mother to baby.  Immune cells from the mother are transferred in milk and colonize the respiratory and digestive system of the baby — the mother’s immune system coats and buffers the baby’s exposure to the world.  Milk hormones close the baby’s gut and milk bacteria are the first probiotics that exploit the milk prebiotics (bifidus factor, human milk oligosaccharides) to produce a gut flora.  [Also note that most commercial probiotics are adapted to grow on cow’s milk and hence these dairy probiotics do not survive in adults.]  The lymphatic system of the breast terminates at the nipple and samples antigens/pathogens from the baby’s mouth, resulting in baby-specific secretory antibodies that return in the milk.  Milk supports a starter set of gut flora, essentially dairy probiotics, that stimulates development of the baby immune system, but inhibits adult gut flora that would digest the protective components of milk.  Formula, on the other hand, is inflammatory to the baby gut, because it supports adult gut flora before the immune system is ready.  Inflammation and stimulation of innate immunity is sufficient, if supported with high levels of sanitation, to permit survival of babies fed formula.  Milk of any type is incompatible with adult gut flora, so breast milk will attack adult gut flora and adult gut flora will digest and inactivate the otherwise beneficial components of the milk.

Milk, Kefir and Gut Flora

Aggressive and Suppressive Cells of Immune System Develop in Intestines

Gut bacteria are required for the development of immune T cells in the lining of the intestines.  Mice grown without gut flora do not have functional immune systems.  In humans, extensive antibiotic treatment produces defective immune systems that are either overly aggressive, i.e. autoimmune, or susceptible to infection and cancer.  They can’t be both.  Aggressive T killers are stimulated to develop by filamentous bacteria and Tregs develop in response to members of the Clostridium family.  In a healthy body, there is a balance between aggression and suppression; there are functional defenses against infection and cancer, while also avoiding autoimmune disease and allergies.

Suppressive Tregs are Deficient in Autoimmunity

Immune cells result from replicative divisions of stem cells.  Antibody producing B cells are produced through a million random rearrangements of antibody genes and those B cells producing antibodies against common self proteins are killed (clonal deletion).  Similarly, T cells are produced by rearrangements of receptors and those that would recognize self are eliminated.  The T cells then migrate to the intestines where they can develop into killer T cells or Tregs, in response to gut flora.  The Tregs act to suppress killer T cells that mistakenly recognize healthy self cells.  Thus, the initial elimination of self-attacking T cells or for B cells that produce antibodies that bind to normal cells, is not perfect and the Tregs are needed to avoid the mistakes.  Tregs are necessary to avoid the immune attack on healthy cells that is the basis of autoimmunity.

Autoimmunity Starts with Inflammation, but Requires Deficient Tregs

Bacterial or viral infections, or physical damage causing inflammation is the first step in autoimmunity.  It is the inflammation that initiates the interactions between proteins, autoantigens, of normal cells and cells of the immune system that bind, internalize, fragment and present the antigen fragments/peptides to activate B or T cells with corresponding receptors.  The activated B cells make antibodies specific for the antigen and the T cells will kill cells displaying the antigen.  It is interesting that most proteins are not autoantigens and are never involved immune reactions.  Only proteins with an unusual triplet of basic amino acids, similar to the quartet of basic amino acids used to transport proteins into the cell nucleus, are candidates to be autoantigens or allergens.  In fact, since nuclear proteins already have a quartet, i.e. the nuclear localization signal, they are common autoantigens.  The last requirement for autoimmunity is a deficiency in Tregs, because if the Tregs are functioning, they will block attack on healthy cells.  Treg deficiency usually results from loss of the type of gut bacteria that stimulate Treg production in the lining of the intestines, i.e. species of Clostridium.

Hospitals are Notorious for Clostridium difficile Infections

Fecal transplants are now recommended as a safe and efficacious treatment for C. diff hospital infections.  That makes sense, because hospitals are where antibiotics are routinely used and C. diff can only infect people missing their healthy species of Clostridium.  Thus, the hospitals wipe out the gut flora with antibiotics and then recolonize them with their own antibiotic resistant C. diff.  More antibiotics can’t fix it, but providing healthy gut flora (transplant) can.

Autoimmune Diseases are Treated/Exacerbated with Antibiotics

Both the aggressive and the suppressive immune cells require gut flora, so after initial antibiotic treatment wipes out bacteria required for suppression and results in autoimmunity, the remaining aggressive half of the immune system can be eliminated by blasting the remaining gut flora with more antibiotics.  Of course this will leave a highly compromised, incompetent immune system that will ultimately yield more extreme symptoms.  This is the typical medical progression for Crohn’s disease, for example.  The alternative is just fixing the gut flora to begin with and curing autoimmunity.

Cure Autoimmunity by Feeding Clostridium Resistant Starch

Autoimmune diseases, by their symptoms, show that sufficient gut flora to stimulate the aggressive half of the immune system is still present.  What is missing are the Clostridium species that convert soluble fiber, such as resistant starch, into short chain fatty acids, e.g. butyrate.  Patients treated with antibiotics usually walk away from the hospital with a suggestion to eat some yogurt to repopulate their missing gut flora.  Unfortunately, dairy probiotics don’t survive in the gut and cannot repair the gut flora and immune system.  The result, after the gut fails to repair and the immune system crashes, is autoimmunity.  There is a more appropriate possibility to avoid or fix autoimmunity.  Some people suffering from autoimmunity (and with remnants of their gut flora intact) have simply fed their gut flora on resistant starch and achieved complete recoveries.  Others fail to respond, because their gut flora is too severely damaged and necessary bacterial species are gone.  Those individuals need to eat the missing species of bacteria and some probiotics (more common in Asia) contain Clostridium species.  Consistent with this use of soluble fiber to feed gut bacteria that produce butyrate and stimulate the suppressive immune system are reports of healing by combining potato starch (RS) and probiotics with Clostridium butyricum (Probiotic-3).  Repair of the suppressive immune system by repair of gut flora (including fecal transplants) and feeding gut flora with appropriate soluble fiber, may be a general approach to the cure of most autoimmune diseases and allergies.

Paleo Gut Flora Repair

Paradoxical Inflammation

Anti-inflammatory Treatments Cause Inflammation in Some Diseases, e.g. Rosacea

I thought that the anti-inflammatory diet and lifestyle I outlined on this blog would be a general purpose starting point for the treatment of all diseases. Inflammation is the foundation for allergies, autoimmune diseases and cancer. Inflammation is a basic defense against infectious diseases and many tissues require signaling components integral to inflammation for their normal function, so it is possible to overdo anti-inflammatory treatment and produce immuno-suppression. But that is unusual. What I am talking about here is inflammation caused by vitamin D, omega-3 oils, potentially low carbs and inhibitors of NFkB, such as tumeric. This is Paradoxical Inflammation.

Rosacean Inflammation Is Paradoxical

The obvious example of a paradoxical inflammatory disease is rosacea. Rosacea seems to be a large group of diseases that manifest in facial inflammation. Excessive flushing of the face can become persistent and form pustules and swelling. The triggers for rosacean inflammation are legion and idiosyncratic. They include mundane social interactions, numerous foods, temperature extremes and, paradoxically, just about everything that I recommend to decrease chronic inflammation.

Bacteria in Tissue and Gut Biofilms Are Candidates

Why do otherwise anti-inflammatory foods and exercise make rosaceans red in the face? Even vagal stimulation that is uniformly calming to inflammation, can make a rosacean flush. This is very inconvenient. I can only invoke the typical players: cryptic bacteria, biofilms, vagus nerve stimulation and response, lymphocytes/macrophages, cytokines and neurotransmitters.

All rosaceans have demonstrated facial inflammation and have had long term exposure to antibiotics and NSAIDs. That combination suggests that bacteria have been transported from a leaky gut (NSAIDs) to the site of inflammation (the face). It is likely that cryptic bacteria inhabit the dermis near the blood vessels and resident lymphocytes/mast cells. This is also the location for axons from vagus nerves. Thus, vagus stimulation may result in the release of neurotransmitter acetylcholine to stimulate lymphocytes/mast cells with subsequent release of cytokines. In this case the cytokines are inflammatory.

Other sources of inflammatory cytokines are lymphocytes/mast cells activated by endotoxin release from cryptic bacteria triggered by immunological attack. In this case, the immunological attack can be initiated by disruption of the stasis invoked by the cryptic bacteria.

Activated Cryptic Bacteria Are Source of Inflammation

It is hypothesized that the cryptic bacteria remain in tissue, because they are able to induce a hibernation-like physiology in the tissue. Disruption of the hibernation would initiate an immunological assault. Disrupting agents typically include vagal stimulators, such as activators of the hot or cold sensors, e.g. capsaicin, castor oil or menthol. Interestingly, the cryptic bacteria require a residual level of inflammation to acquire nutrients from the host. Anti-inflammatories that inhibit NFkB may destabilize the bacterial/host interaction and result in an immunological attack on the bacteria. All of the attacks on the cryptic bacteria release inflammatory endotoxin.

Gut Biofilms Store Bacteria Recruited to Become Cryptic in Inflamed Tissue

During the course of the disease and following numerous antibacterial treatments, bacteria can be continually recruited from safe havens, such as gut biofilms. Antibiotic treatment of biofilms converts the biofilm community to antibiotic resistance through activated horizontal gene transfer. Moreover, harsh treatment of biofilm communities initiates shedding of bacteria that could migrate across the leaky gut adjacent to the gut biofilms and provide new emigrants into the inflamed face tissue. A likely resident would be Chlamydia pneumonia, which has been demonstrated to be carried by macrophages and offloaded at distant sites of inflammation.

How the Vagus Becomes Inflammatory

This brings up the question of why vagal stimulation shifts from anti-inflammatory to inflammatory in rosaceans. I don’t think that the vagus nerves change in either their activation or in the neurotransmitters that are released as a result of stimulation. This means that the cells that respond to the vagal acetylcholine must be changed. I think that the change is a depletion of Treg cells and the result is that acetylcholine receptors on the remaining T cells cause a release of inflammatory cytokines. These cytokines cause the release of NO by endothelial cells and vasodilation. Leaking of endotoxin from the resident cryptic bacteria causes persistent dilation and restructuring of the vasculature.

Helminth and Il-2 Therapy Reestablish Tolerance and Reverse Vagal Inflammation

Since I have been forced to explain paradoxical inflammatory diseases, I might as well speculate on exotic approaches that already suggest potential treatments. Ingesting parasitic worm eggs (helminth therapy) has proven successful in the treatment of inflammatory diseases such as asthma, allergies and IBDs. Interleukin 2 (Il-2), usually used as a complex with an anti-Il2 antibody, is also a productive treatment. In both of these cases, the treatment stimulates the proliferation of Treg cells, which appear to be deficient in many of the inflammatory diseases. These treatments should also lead to a lowering of inflammation in the gut and suppression of inflammation as a result of vagal stimulation. Inhibitors of acetylcholine receptors, e.g. scopolamine patches, might also be interesting to test to see if they inhibit rosacean flushes in response to typical vagal stimulants such as castor oil or menthol.

Addendum:  Another possibility associated with the heavy use of antibiotics by rosaceans is intestinal (biofilm?) candidiasis.  Yeast infections are common after prolonged antibiotic treatment.  Interestingly, Candida produces resolvins from omega-3 fatty acids and the resolvins suppress neutrophil activity that would attack the yeast.  Thus, many of the anti-inflammatory treatments would actually aggravate yeast infections and contribute to rosacea.  Treatment for candidiasis (keeping in mind that yeast may be protected by biofilms) helps many rosaceans.  Stripping biofilms may be useful if pro- and pre-biotics are used to displace Candida.

The Cause of Allegies and Autoimmune Diseases

Keyhole Limpet Hemocyanin (KLH): Internalized Antigen

Scanning the literature for a common protein that can be used as an experimental antigen, it becomes quickly obvious that a favorite is KLH. This would seem to be an odd choice -- why a keyhole limpet protein? But that is the wrong question.

Why is KLH such a good antigen, i.e. why is it readily presented to the host immune system? If you have been reading my posts, you might be thinking about triplets of basic amino acids and that is the answer.

As soon as I remembered the prominent use of KLH as an antigen, I checked the NCBI protein database and immediately found an unusual KKK (triple lysine) near the amino terminus of hemocyanin II ( it comes in two pieces). This triplet explains why KLH is such a good experimental antigen, because it is internalized into antigen presenting cells by its strong heparin-binding domain. Other components, adjuvants, are typically added to the KLH for injection to make sure that a strong local inflammation occurs.

Autoantigens Have Strong Heparin-Binding Triplet

I also learned that Hashimoto’s thyroiditis is an autoimmune disease mediated by the autoantigen thyroid peroxidase. A quick search reveals that thyroid peroxidase is an autoantigen, because it also has a triplet of basic amino acids that can enhance presentation under inflammatory conditions. Grave’s disease of hyperthyroidism is an autoimmune disease in which the thyroid receptor (with a basic triplet) is an autoantigen. The same kind of triplet of basic amino acids was found when I searched today for fire ant antigens and mosquito antigens.

I have also looked for the triplets in protein databases. The triplets are rare in cytoplasmic and extracellular proteins. The proteins that have triplets are usually identified as autoantigens in some disease. The triplets are common in nuclear proteins, since heparin-binding and nucleic acid-binding share the same basic amino acid domains. The nuclear internalization signal also results in rapid cellular internalization, e.g. HIV-TAT, heparanase, IGF-binding proteins. Nuclear proteins are common autoantigens in lupus.

Inflammation Plus Heparin-Binding Internalization: Allergy, Autoimmunity

Chronic inflammation can produce antibodies against proteins (foreign or self) with strong heparin-binding domains (triplets or sometimes neighboring pairs of basic amino acids, lysine or arginine). The generalization explains why particular proteins in pollens, foods, insects, pets, mites, asthma, MS, lupus, celiac, etc. produce antibody responses.

Allergy, Asthma, Autoimmunity Start the Same Way

Inflammation is the current medical buzzword. Name the disease and inflammation is there.

Reproduction Requires Controlled Inflammation
Aspirin blocks many of the steps in triggering inflammation and thus, aspirin administration can be used to reveal a role of inflammation in many unexpected places. Aspirin is effective in blocking some forms of infertility, inhibiting miscarriages and ameliorating postpartum depression. So inflammation is a critical part of reproduction. But, also notice that depression is a symptom of chronic inflammation.

Cancer Requires Inflammation
High dose (IV) aspirin has been successfully used to treat cancer. Inflammation is required for cancer growth, because both use the same transcription factor, NFkB. The aberrant signaling of cancer cells would normally lead to programed cell death, apoptosis, but inflammation blocks apoptosis. Aspirin can in turn block NFkB and in the absence of inflammation, cancer cells die by apoptosis.

Inflammation is Self-Limiting
Aspirin also transforms the COX/lipoxidase system to produce anti-inflammatory prostaglandins/eicosinoids. Inflammation normally progresses into anti-inflammation. Blocking this progression leads to chronic inflammation and a shift from local to systemic inflammation with the rise of inflammatory interleukins in the blood stream.

Immune Response Requires Inflammation
The signal molecules (IL-1, IL-6, TNF) and transcription factor, NFkB, associated with inflammation were all initially identified in the development of lymphocytes. Hence, IL stands for interleukin, a hormone that triggers leukocyte (literally white blood cells or cells associated with the lymphatic immune system, i.e. lymphocytes) development. The nuclear factor, i.e. transcription factor, involved in expression of the large chain, kappa, of immunoglobulins in B cells, was called NFkB.

Genes Expressed by NFkB Cause Symptoms of Inflammation
About five dozen genes are under control of NFkB. Among these are COX-2, the enzyme that converts omega-6 arachidonic acid to inflammatory prostaglandins; iNOS, the enzyme that produces nitric oxide that dilates blood vessels to produce hot, red skin; and the inflammatory interleukins, IL-1, IL-6 and TNF, associated with autoimmune disease, fatigue and cachexia (wasting).

Autoimmunity and Allergy Start with Inflammation
Medical treatments focus on symptom abatement and ignore cause. What causes obesity, allergy or autoimmune disease? The answer appears to be chronic systemic inflammation plus exposure to unusual proteins. The unusual proteins are immunogenic, i.e. interact with the immune system to produce antibodies or reactive T-cell receptors, and are subsequently recognized as autoantigens or allergens, that are the targets for immune attack. Inspection of these autoantigens and allergens shows that they all have one thing in common, they bind to heparin via a strong heparin-binding protein domain that is typically a triplet of adjacent basic amino acids.

Heparin is a Short, Highly Sulfated Fragment of Heparan Sulfate
Commercial heparin is purified from the intestines of hogs and cattle. Heparin is released from mast cells (made fluorescent for microscopy using berberine) along with histamine and is released into the intestines to block pathogens from binding to the heparan sulfate that is part of the intestine surface. The heparin is anti-inflammatory and it contributes to minimizing the inflammatory response of the intestines to food.

Inflammation Reduces Heparan Sulfate Production
Pathogen-generated inflammation of the intestines reduces heparan sulfate production and increases immune response to food antigens. NFkB activation by inflammation turns off the production of some genes needed for heparan sulfate proteoglycan (HSPG) synthesis. Since HSPG is a major component of the basement membrane that holds tissues together, the reduction of HSPG results in protein loss (proteinuria) from kidneys, leaking of intestines, and disruption of the blood/brain barrier.

Reduction of HSPG Results in Immunological Presentation of Autoantigens/Allergens
Proteins are brought into cells by specific binding to protein receptors. In many cases, particularly involving signaling or growth factors, both the signal molecules and the receptors bind to heparin. In addition, there is a robust circulation of HSPG, which is secreted and internalized with a half-life of approximately six hours. The sweep of the HSPGs take heparin-binding proteins with them for internalization, e.g. HIV-TAT, heparanase, tissue transglutaminase. I think that this HSPG sweep under inflammatory conditions also internalizes basic autoantigens and allergens with strong heparin-binding domains. This internalization is the first step toward immunological presentation and the immune response to autoantigens and allergens.

Autoantigen/autoantibody/HSPG Complexes Kill Cells
Antibodies against self-antigens, autoantigens form antigen/antibody complexes that also bind to and cross-link HSPGs, because of the heparin-binding domains of the autoantigens. The large complexes may disrupt HSPG circulation and trigger apoptosis or abnormal physiology. There are many other examples of heparin-based complexes that are toxic, e.g. Alzheimer’s amyloid plaque, diabetic beta cell antibody complexes, celiac gluten/tRG antibody complexes, multiple sclerosis myelin antibody complexes, atherosclerotic plaque.

Anti-Inflammatory Diet and Lifestyle Protects
Dietary and lifestyle adjustments that minimize inflammation, e.g. low starch, no HFCS, low vegetable oil (except olive) and supplements of vitamins D & C, fish oil (omega-3) and glucosamine, reduce the risk of allergies/asthma, degenerative diseases and cancers. Simple, high level supplements with fish oil reduce numerous mental disorders, e.g. depression, ADHD; infertility, pre-eclampsia and postpartum depression; allergies, asthma; arthritis, atherosclerosis; burn recovery, septicemia and head injury.

Reducing Inflammation is a Panacea for Modern Diseases
Most modern diseases have an inflammatory component, because modern diets are rich in inflammatory components, e.g. starch/sugar, corn/soy oil, HFCS, trans fats, and exercise is minimal. The medical industry has not successfully promoted healthy eating and exercise; and in fact has promoted the devastating replacement of saturated fats with inflammatory polyunsaturated vegetable oils. Meat production has moved away from grazing on omega-3-rich plant vegetation to omega-6-rich corn and soy. Replacement of the corn/soy based agricultural economy would have predictably immense beneficial impact in reducing inflammation-based degenerative autoimmune diseases and cancers.

Menstrual Pain is Inflammatory

Inflammation is essential to the menstrual cycle. At key points inflammatory prostaglandins are made from omega-6 arachidonic acid to trigger ovulation and menses, the discharge of the blood-engorged lining of the uterus. Chronic diet-based inflammation can result in disrupted ovulation, infertility due to an inability to suppress an inflammatory response to egg implantation, menstrual pain/cramps and premature birth.

Several studies have shown that reducing diet-based inflammation by eating supplements containing long chain omega-3 oils, e.g. fish oil, decreased menstrual pain and cramps. The reduction in chronic inflammation was associated with decreased production of inflammatory prostaglandins that are the cause of the pain and intense uterine contractions. Normally, the diet would provide a balance of omega-3 and -6 fatty acids, which would yield a mixture of anti-inflammatory and inflammatory prostaglandins, and produce an effective discharge through more moderate uterine contractions.

A more recent evaluation of numerous studies on the impact of omega-3 oils on pain associated with menstruation, arthritis, inflammatory bowel disease, etc., showed a uniform decrease in inflammation and pain. The simple summary is that an inflammatory diet rich in omega-6 vegetable oils leads to pain, suffering and premature aging. A more normal diet with a balance of omega-3 and omega-6 fatty acids leads to health and reduced aging.

Typical symptoms of an inflammatory diet are: menstrual cramps, infertility (gestational problems: preeclampsia, prematurity), joint pain, back pain/sciatica, acne, allergies, asthma, autoimmune diseases. There is increasing evidence that obesity not only produces inflammation, but that an inflammatory diet can lead to obesity. An inflammatory diet, especially if augmented with antibiotics, disrupts the normal gut flora and leads to an inflammatory replacement flora that supports chronic inflammation throughout the body.

Chronic inflammation and much of the damage caused by chronic inflammation is reversible by a shift to an anti-inflammatory diet and lifestyle (described elsewhere on this blog.)

references:
Deutch B. 1995. Menstrual pain in Danish women correlated with low n-3 polyunsaturated fatty acid intake. Eur J Clin Nutr. 49(7):508-16.

Goldberg RJ, Katz J. 2007. A meta-analysis of the analgesic effects of omega-3 polyunsaturated fatty acid supplementation for inflammatory joint pain. Pain 129(1-2):210-23.

Bell RF. 2007. Food and pain: should we be more interested in what our patients eat? Pain. 129(1-2):5-7.

Inflammation Causes Disease

Human diets have changed dramatically over the last few hundred years, and as a consequence so have our diseases. The most recent shift in diet over the last hundred years has resulted in a shift from infectious diseases to degenerative diseases. This trend is summarized in the following Wikipedia entry.

Lifestyle diseases, from Wikipedia:

"Lifestyle diseases (also called diseases of longevity or diseases of civilization) are diseases that appear to increase in frequency as countries become more industrialized and people live longer. They include Alzheimer's disease, atherosclerosis, asthma, cancer, chronic liver disease or cirrhosis, Chronic Obstructive Pulmonary Disease, Type 2 diabetes, heart disease, nephritis or chronic renal failure, osteoporosis, acne, stroke, depression and obesity.

Death statistics in the United States
In 1900, the top three causes of death in the United States were pneumonia/influenza, tuberculosis, and diarrhea/enteritis. Communicable diseases accounted for about 60 percent of all deaths. In 1900, heart disease and cancer were ranked number four and eight respectively. Since the 1940s, the majority of deaths in the United States have resulted from heart disease, cancer, and other degenerative diseases. And, by the late 1990s, degenerative diseases accounted for more than 60 percent of all deaths.
Reference:
National Center for Health Statistics, National Office of Vital Statistics, 1947 for the year 1900 (page 67), for the year 1938 (page 55)."

My point here is that all of the so-called lifestyle diseases are also based on inflammation. I checked the research literature for studies of the response of each of these diseases to diets supplemented with omega-3 fish oils. Studies had been performed in each case. Reduction of inflammation by fish oil treatment was uniformly effective in reducing symptoms of all of the degenerative diseases. Other diseases that can be added to the inflammatory list are spinal disc problems and hypertension. It is interesting that disc dislocations are associated with coeliac, an inflammatory/autoimmune disease. It is also interesting that acne and depression are listed. Acne is indirectly associated with diet, but if sufferers shift to an anti-inflammatory diet, acne symptoms disappear. Depression associated with childbirth is particularly responsive to anti-inflammatory drugs, diet and exercise. Most of the symptoms associated with aging are just due to inflammation and are similarly responsive to anti-inflammatory lifestyle changes

To summarize:

• Modern degenerative diseases are caused by modern inflammatory diets (and insufficient exercise.)
• Anti-inflammatory diet and lifestyle reduce degenerative diseases.
• Aging is predominantly mismanaged inflammation.
  

Asthma Nitric Oxide

Arginine is the source of nitric oxide using the enzyme NOS. Inducible NOS is expressed in response to triggers of inflammation mediated by NFkB. NO in turn activates guanylate cyclase to increase cyclic GMP and cGMP relaxes muscle actin and myosin.

Studies are being made to assess the status of asthma by measuring nitric oxide (NO) in respired air. Since NO is produced as a product of the action of induced nitric oxide synthase (iNOS), and iNOS is synthesized when the inflammatory transcription factor NFkB is activated, then the inflammation that is a characteristic of asthma should be signaled by the production of NO.

If NO is involved in asthma, then one would expect relaxation of muscle to occur. That is the opposite of what is observed; contraction of the muscle cells surrounding airways is responsible for airway constriction is asthmatic episodes. Thus, during asthmatic episodes NO must be reduced.

Since NO is made from the amino acid arginine, then the ability to produce NO can be decreased by reducing available arginine. Arginine can be reduced by the enzyme arginase. The product is ornitine that can in turn be converted into purtrescine, the simplest of the polyamines that are used as counterions in the secretion of heparan and chondroitin sulfates.

Arginase is produced in high levels in asthmatics, but not in normal lungs. Also elevated putrescine is found in asthmatic lungs, indicating that arginine is being converted by arginase into ornithine and on to purtrescine. Ornithine is the precursor for proline that is a key amino acid in collagen production and the increased extracellular matrix that thickens the tissue of asthmatic lungs is rich in collagen.

A major point of this discussion is that NO can only be effectively lowered if there is a limited supply of arginine. Thus arginine supplementation should be helpful to asthmatics. Nitroglycerine patches may also be a means of enhancing sources of NO. Another possible approach would be the use of NO donors conjugated to NSAIDS. These conjugates delivered in an atomized form could provide the lungs with both NO and anti-inflammatory agents. Asthmatics also respond well to rigorous application of the anti-inflamatory diet and lifestyle.

Mast Cell Heparin

Mast cells are sentinels in tissues. They respond to invading pathogens by releasing their stored histamine, enzymes and heparin. The heparin modifies the activity of enzymes and cytokines.

What are mast cells and why are they loaded with heparin (left)? Mast cells start in the bone marrow, like many other components of the immune system. They then move into the blood stream and offload in most of the tissues that typically encounter pathogens and parasites. Thus, the typical commercial source of the mast cell-produced heparin is pig intestines or cow lungs, i.e. since heparin is made and stored in mast cells and mast cells are abundant in lungs and intestines, those are the sources of crude heparin. Proteins bound to the crude heparin are removed as the heparin is cleaned up to be used as an anti-clotting drug.

Mast cells are sentinels near the surface of mucus membranes that line the airways of the lungs and the digestive tract. Diseases of the lungs and intestines, e.g. asthma and inflammatory bowel disease, that have an inflammatory and/or autoimmune component yield high levels of mast cells in the affected tissues. Pathogens or parasites coming in contact with mast cells trigger the sudden release of vesicles full of histamine, enzymes and heparin.

Heparin stored in vesicles in mast cells can also be readily visualized by staining the mast cells in microscope sections using the fluorescent dye berberine (left). Berberine binds quite specifically to heparin and is also used in herbal medicine as a treatment for many inflammatory diseases, such as arthritis. It would be very interesting to know whether berberine has any effect on asthma.

Mast cells display a variety of receptor proteins on their surfaces. Protein receptors work by binding target molecules, ligands, changing their shapes and transmitting a signal through the cytoplasm. A key aspect of the signal transmission is the requirement for the ligand binding to bring together receptors in pairs. The pairing of receptors during ligand binding is facilitated by the binding of heparin to both ligands and receptors. Two ligands, e.g. cytokine peptides, such as TNF, can bind to adjacent sites on a heparin molecule and this pair can then bind to two receptors brought together on the surface of a cell. The receptors bind to the ligand and to the heparin. Some ligands will bind to their receptors without heparin, but the presence of heparin greatly accelerates and intensifies the reactions.

Heparin is synthesized in the vesicles of mast cells and binds to enzymes, e.g. tryptase, also present in the vesicles. The tryptase enzyme proteins form tetramers with heparin wrapped around the edge (left, edge view showing one pair of tryptase proteins with heparin bound diagonally to blue heparin-binding domains; other pair of tryptase proteins is hidden).

Interestingly the active site for each tryptase in the tetramer faces a hole where the four proteins come together. Thus the tetramer can degrade small peptides, but large proteins cannot get access to the blocked active sites. Monomers change shape and are no longer active.

Activated mast cells release their vesicle contents with some enzymes active and their bound heparin is replaced by the heparan sulfate attached to adjacent cells. Other enzymes are initially inactive bound to heparin and are activated by dissociation of the heparin once they are released from the vesicles. In both cases some of the heparin is released from the mast cells into the surrounding tissue. The free heparin can bind to cytokines released from other cells and the combined pairs of cytokines bound to heparin can in turn bind to appropriate receptors on other cells. The abundance of heparan sulfate bound to other cells will determine whether additional heparin is required for receptor responses from particular cytokines. Cells with abundant heparan sulfates will sweep heparin binding ligands toward receptors aggregated in lipid rafts, as the heparan sulfate proteoglycans are internalized for recycling.

Mast cells can be activated by allergens, because of IgE receptors. IgEs are antibodies that trigger allergic responses. The IgEs produced by antibody producing B lymphocytes circulate in the blood serum and bind to mast cell receptor proteins. Allergen molecules bind to the IgE-receptor complexes, trigger the activation of the mast cells and release histamine. The histamine binds to receptors on other cells and produces the symptoms of allergy or asthma.
Heparin can be sprayed into the lungs of asthma sufferers and reduce symptoms. This suggests that the ratio of heparin to cytokines is important and that cytokine signaling required for asthma episodes of airway constriction can bind individually to different heparin molecules and minimize mast cell triggering and histamine release.

Asthma also responds to a general decrease in chronic systemic inflammation. Thus, an anti-inflammatory diet and lifestyle, can reduce episodes and potentially reverse symptoms. Omega-3 oils and glucosamine, for example are both effective.

Tryptase model: Sommerhoff CP, Bode W, Pereira PJ, Stubbs MT, Stürzebecher J, Piechottka GP, Matschiner G, Bergner A. 1999. The structure of the human betaII-tryptase tetramer: fo(u)r better or worse. Proc Natl Acad Sci U S A 96(20):10984-91.


Berberine staining of mast cell heparin: Feyerabend TB, Hausser H, Tietz A, Blum C, Hellman L, Straus AH, Takahashi HK, Morgan ES, Dvorak AM, Fehling HJ, Rodewald HR. 2005. Loss of histochemical identity in mast cells lacking carboxypeptidase A. Mol Cell Biol. 25:6199-210.