Helminths, Oligosaccharides and Immunotolerance

Parasitic worms reverse allergies and autoimmune diseases using oligosaccharides to mimic self and silence immune over-responsiveness.

Helminth therapy, i.e. infection with parasitic intestinal worms to provide remission from allergies, inflammatory bowel and other autoimmune diseases, has been examined as a potential therapeutic model to rehabilitate immunological dysfunction.  The surface oligosaccharides of these worms have been found to mimic human oligosaccharides and alter immune responses by binding to carbohydrate-binding, i.e. lectin, receptors.

Immune Tolerance
The essence of allergic and autoimmune diseases is a defect in distinguishing between pathogen, innocuous and self molecules.  Heightened immune reactions as a result of inflammation move the immune system toward production of antibody and T cell receptors specific for antigens.  Those antigens respond to unique receptors on the surface of each B and T lymphocyte.  The lymphocyte population has been previously depleted of cells that can produce receptors that will bind to most self antigens.  This depletion makes the lymphocyte population generally non-responsive, or tolerant to self antigens.  Thus, the immune system is blind to the body.

Regulatory T Cells and Tolerance
Most of the immune cells of the body are present in the lining of the gut.  It is in the gut that various immune cells continue to develop for their various roles, including controlling immune reactions to self antigens and to common food molecules.  Immune cells in the gut are exposed to some food molecules and bacteria that leak through the cells of the intestinal villi.  Responding to these common antigens by inflammation can lead to inflammatory bowel disease.  This pathological over-responsiveness is normally avoided by development of regulatory T cells, Tregs, that suppress immune responses to common food molecules and to surface antigens of common bacteria.

Treg Development Depends on Gut Flora
Gut bacteria are needed for the normal function of the immune system.  Oddly, Helicobacter pylori, Hp, the cause of stomach ulcers and cancer, also stimulates the development of Tregs.  Thus, the pathology of Hp may result not from its presence, but rather from how it is growing.  Since Hp uses hydrogen gas produced by Klebsiella in the lower bowel and hydrogen production is dependent on dietary starch, then it follows that the pathological behavior of Hp may be dependent on dietary starch.  A low starch diet may actually result in Treg stimulation from Hp and a reduction in allergies and autoimmune diseases.

Tregs Enhanced by Heliminths
Immunological tolerance is also stimulated by parasitic worms, Helminths.  Helminth infestations, therefore, reduce allergies and autoimmune diseases and may contribute to the hygiene hypothesis to explain the prevalence of allergies, autoimmune and other inflammation-based degenerative diseases in modern societies.  Examination of worms to find the molecules responsible for inducing immunological tolerance has identified complex surface and secreted oligosaccharides (small sugar chains) as the active molecules.  Helminth oligosaccharides mimic human cell surface oligosaccharides and bind to carbohydrate-binding, lectin, receptors on immune cells to stimulate Treg development.

Lectin Receptors Control Tolerance
There are many implications of the modulation of the immune system via oligosaccharides.  Note that related oligosaccharides are components of human milk and prepare the gut and develop the immune system.  This explains why formula, which lacks these unique oligosaccharides, results in aberrant gut flora, contributes to neonatal necrotizing colitis and supports the development of allergies and autoimmune diseases.  In contrast, judicious use of self or Helminth oligosaccharides may provide a means of restoring the function of damaged immune systems and therapy for allergies and autoimmune diseases.  Also note that the critical use of lectins, which have oligosaccharide-binding sites rich in aromatic amino acids to bind the hydrophobic faces of the sugars, will also bind and provide entry into immune cells for allergens and autoantigens that have triplets of basic amino acids.  The binding sites of lectins should also bind many aromatic phytochemicals.  Immunomodulation by phytochemicals may result from interference with or mimicking the binding of oligosaccharides to lectin receptors.

reference:
van Die I, Cummings RD.  Glycans modulate immune responses in helminth infections and allergy.  Chem Immunol Allergy. 2006;90:91-112.

Biofilms as Human Gut Mycorrhizals

Are Biofilms Healthy Extensions of Intestinal Villi?

If soil is the stomach of the earth, then plant roots and mycorrizal fungi must be the intestines.

Mycorrhizal fungal hyphae extend from root hairs of plants into surrounding soil and enhance the uptake of phosphate and other nutritents.  Many plants cannot colonize new soil without taking their fungal partners with them.  It would seem obvious that the highly adapted human gut flora would include bacteria and fungi that actively communicate with intestinal epithelial cells.  Perhaps that communication includes both nutrients, e.g. hydrogen, ammonia, etc., vitamins and bacterial wall components, e.g. LPS.

Plants Sit and Mine Soil, Humans Mine Nutrients Passed through Their Gut

I want to try to give a plant’s view of human digestion.  Plants elaborate roots that branch repeatedly and the final extensions sprout hairs from individual epithelial cells.  Mycorrhizal fungal hyphae further extend the reach of the plant into the soil for nutrients. 

I think that a plant would look at us and see us stuffing soil/food into our mouths and watch it come out the other end.  It would then try to figure out where are roots are, i.e. how we absorb the water and minerals from our moving internal stream of soil.  The villi of the small intestines would look like root hairs, but where are the mycorrhizal fungi?  Another problem is that the soil keeps moving past the root hairs and would break off fungal hyphae extending into the soil.  Still another problem is the constant shedding of epithelial cells from the tips of the villi.  The plant would be perplexed, but closer inspection would reveal that biofilms could solve the problems.

Biofilms Coat the Intestinal Villi

Biofilms coating and perhaps spanning the villi of the small intestines may enhance the transport of nutrients into the villi.  This may be controversial and the biofilms may be more commonly limited to the smoother surface of the colon.  The point here is that biofilms may enhance the intestinal uptake of nutrients from food.  Biofilms may, therefore, be essential for health and extend the reach of the intestinal epithelial cells.

Bacterial Community Composition May Be Determined by Diet

A biofilm is composed of some type of linear polymer, such as DNA, heparan sulfate or bacterial acidic polysaccharides, with bacteria that bind to the polymer and to the intestinal epithelium.  Diet determines the bacterial composition of the biofilm.  Thus, the newborn starts without biofilms, gut development is finished by growth hormones in milk and a single species of Bifidobacteria excludes biofilm production, until solid food or formula initiates adult biofilms.  The bacteria in the biofilm depend on diet, so the biofilms can be either beneficial or pathogenic.

Communication within Biofilms and with the Intestines

The bacteria respond to the presence of other bacteria by quorum sensing, which involves release of small molecules that alter the gene expression of other bacteria in the community.  As a consequence, genes, e.g. antibiotic resistance, are exchanged and metabolism is altered.  This is how Klebsiella nitrogenase and hydrogen production is controlled.  The biofilm bacteria also produce compounds, e.g. vitamin D (?), that alter the behavior of the intestinal epithelial cells.  The intestines can respond with inflammation to recognized pathogen components or by triggering development of cells of the immune system.  The intestines are the home of most of the body’s immune cells.

Stimulation of Tregs

Helicobacter pylori adhering to the stomach lining increases the stomach’s quota of regulatory T cells that are involved in immunological tolerance.  Presumably, the supply of Tregs in the intestines is also regulated by biofilms.  Disruption of this system by chronic inflammation can deplete Tregs and lead to unrestrained immune attack that is observed as inflammatory bowel disease.  Thus, Crohn’s disease and ulcerative colitis may be triggered by damaged biofilms.

Biofilm Transformation, Helicobacter, Klebsiella

Helicobacter pylori causes stomach cancer, but it feeds on hydrogen gas produced by Klebsiella pneumoniae in gut biofilms. DNA released by biofilm bacteria not only transfers antibiotic resistance, but it also provides protection against host antibacterial peptides, such a cathelicidins and defensins.

Exploding Labs

When I was working on host/pathogen interactions and plant disease resistance, I also became familiar with research on the formation of the plant equivalent of cancer, crown galls, and symbiotic bacterial nitrogen fixation. I mention this, because this also exposed me to the free-living bacterial nitrogen fixing system in Klebsiella and to the memorable urban legion of exploding labs. As the story goes, as bacteria convert atmospheric nitrogen gas into ammonia, nitrogen fixation, they use high energy electrons, e.g. from ferrodoxin, and lots of ATP, but they also produce hydrogen gas. In labs where they are researching nitrogen fixation, the excess hydrogen gas would accumulate on the ceiling until... boom! Now those labs are properly vented.

Helicobacter Uses Hydrogen as an Energy Source

Helicobacter pylori is considered the most common bacterial pathogen of humans and is the primary cause of ulcers and stomach cancer. H. pylori lives in the stomach by neutralizing stomach acid with ammonia. Another interesting ability of this bacterium is its ability to use hydrogen dissolved in circulating blood as an energy source. The high energy electrons from molecular hydrogen are transported to its electron transport chain, and the energy is used in membrane transport and ATP production. The circulating hydrogen is produced by gut bacteria.

Klebsiella Is not just a Soil Bacterium, Gut Gases

Klebsiella pneumonia is a lung pathogen and it also forms gut biofilms. Presence in the gut and the ability to produce hydrogen gas has some implications for hydrogen utilizing bacteria like H. pylori. Clearly, the stomach of someone with an abundant source of hydrogen fuel in their blood is a better target for H. pylori colonization. This explains why even at age 50, individuals who were exclusively breastfed have a lower incidence of H. pylori and stomach cancer, since even a single bottle of formula can shift an infant to adult, i.e. Klebsiella gut flora.

Klebsiella Needs Carbs to Produce Hydrogen

K. pneumoniae has been associated with Crohn’s Disease and Ankylosing Spondylitis. It grows in gut biofilms and produces pullulanase, an enzyme that can utilize the branched glucosides left over from the action of amylase on plant starch. So K.p. has an untapped food source and it needs lots of ATP to produce hydrogen gas. The nitrogenase needed for nitrogen fixation and hydrogen production is very sensitive to oxygen, so this means that K.p. needs a partially anaerobic environment and must get its energy from fermentation. Fermentation yields much less ATP than respiration using oxygen, which means that K.p. can only produce hydrogen with lots of glucose from starch.

Low Carb Diet Cures Crohn’s Disease

It turns out that the antigen causing Crohn’s disease is the pullulanse (with collagen mimetics.) As you should expect, it has a basic triplet. Eating a low carb diet reduces the flareups of Crohn’s disease, presumably by starving out the K.p.. It is interesting that nitrogenase is the antigen involved in Ankylosing Spondylitis.

Biofilms Promote Transformation and Antibiotic Resistance

Just as a footnote to the benefit of K.p. as a citizen of a biofilm community, H.p. should also live in those biofilms, since that is the source of the hydrogen it uses. Biofilms also stimulate the exchange of DNA, because the quorum sensing chemical signals trigger the release of DNA. The DNA is a component in the matrix that binds bacteria in the biofilm and can work in conjunction with bacterial acidic polysaccharides and host heparan sulfate. These acidic polymers tend to bind the basic antimicrobial peptides, e.g. defensins and cathecidins produced as a major non-adaptive defense against bacteria. Thus, the release of DNA triggered by quorum sensing, builds matrix, facilitates DNA transformation that is the foundation for the spread of antibiotic resistance in gut biofilms and provides resistance against antimicrobial peptides.